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Sample records for radiation emergency response

  1. Medical response to radiation emergencies in Argentina

    International Nuclear Information System (INIS)

    Gisone, Pablo A.; Perez, Maria del R.; Dubner, Diana L.; Michelin, Severino C.; Vazquez, M.; Demayo, O.

    2006-01-01

    Although radiation accidents are not frequent, the increasing use of radioisotopes in medicine and industry increases the likelihood of such accidental situations. Additionally, risks posed by the malevolent use of radiation sources have been highlighted during the last few years. In this context, the enhancement of national capabilities for medical assistance of victims in radiation emergencies becomes relevant. This communication describes the organization of medical response to radiation emergencies existing in Argentina. A three-level system for medical response has been developed: pre-hospital response given on-site by local emergency services, assistance provided by emergency departments of local general hospitals and central reference hospitals for treatment of acute radiation syndrome, cutaneous radiation syndrome and internal contamination. An education and training program is regularly executed at the three levels, including theoretical background as well as practical training. Guidelines and protocols for medical handling of victims have been elaborated and implemented. Research and development of new strategies for diagnosis and treatment of radiation injuries are promoted by ARN in close collaboration with physicians belonging to reference hospitals. (author)

  2. Medical Response in Radiation Emergency in Argentina

    International Nuclear Information System (INIS)

    Vazquez, M.A.; Tadic, M.M.

    2011-01-01

    According to the Nuclear Federal Law No. 24804, the Nuclear Regulatory Authority (ARN) is empowered to regulate and control the nuclear activity with regard to radiological and nuclear safety, physical protection and nuclear non-proliferation issues. ARN has a system for intervention in radiological -and nuclear emergencies with a primary intervention group, which is on duty in weekly shifts all year round. This paper aims at describing the system as implemented at present. The Emergency Medical System has been developed into three levels: Level I: local emergency services. This level includes triage (conventional and radiological), first-aid care, and first management of contaminated victims Level II: emergency departments of local general hospitals that are in charge of performing a second triage by a biomedical approach, the treatment of conventional and/or radiocombined injuries and completing decontamination as necessary. In this way the initial triage is completed by a physical examination, timing and severity of prodromal signs and symptoms, sequential blood counts and serum enzymatic levels that allow a first-stage dosimetric approach at this level. Victims requiring higher complexity assistance shall be transferred to third-level hospitals. Level III: three central reference hospitals (Hospital Naval 'Pedro Mallo', Hospital de Quemados from Gobierno Autonomo de la Ciudad de Buenos Aires and Hospital Britanico de Ciudad de Buenos Aires) capable of providing healthcare for diagnosis and treatment of acute radiation syndrome, cutaneous radiation syndrome and internal contamination constitute this level. An educational program for medical and paramedical responders is regularly carried out at the three levels, including theoretical background as well as practical training. Guidelines and protocols for medical handling of victims have been drawn up. Research and development of new strategies for first medical response, diagnosis and treatment of radiation

  3. Medical response in radiation emergency in Argentina

    International Nuclear Information System (INIS)

    Vazquez, Marina A.; Tadic, Maria M.

    2008-01-01

    According to the Nuclear Federal Law Nr. 24804, the Nuclear Regulatory Authority (ARN) is empowered to regulate and control the nuclear activity with regard to radiological and nuclear safety, physical protection and nuclear non-proliferation issues. ARN has a system for intervention in radiological -and nuclear emergencies with a primary intervention group, which is on duty in weekly shifts all year round. This paper aims at describing the system as implemented at present. The Emergency Medical System has been developed into three levels: Level I: local emergency services. This level includes triage (conventional and radiological), first-aid care, and first management of contaminated victims. Level II: Emergency departments of local general hospitals that are in charge of performing a second triage by a biomedical approach, the treatment of conventional and/or radio-combined injuries and completing decontamination as necessary. In this way the initial triage is completed by a physical examination, timing and severity of prodromal signs and symptoms, sequential blood counts and serum enzymatic levels that allow a first-stage dosimetric approach at this level. Victims requiring higher complexity assistance shall be transferred to third-level hospitals. Level III: three central reference hospitals (Hospital Naval 'Pedro Mallo', Hospital de Quemados from Gobierno Autonomo de la Ciudad de Buenos Aires and Hospital Britanico de Ciudad de Buenos Aires) capable of providing health care for diagnosis and treatment of acute radiation syndrome, cutaneous radiation syndrome and internal contamination constitute this level. An educational program for medical and paramedical responders is regularly carried out at the three levels, including theoretical background as well as practical training. Guidelines and protocols for medical handling of victims have been drawn up. Research and development of new strategies for first medical response, diagnosis and treatment of radiation

  4. Radiation emergency response in Illinois, Alabama, and Texas

    International Nuclear Information System (INIS)

    Larsen, D.K.; Chester, R.O.

    1978-03-01

    The objective of this study was to examine state radiation emergency response and to locate any areas of emergency planning in need of improvement. This report briefly presents a summary of laws and defining documents governing radiation emergency response, describes the existing and projected need for such response, and presents the authors' analyses of the evolution of state response plans and their application to radiation incidents. Three states' programs are discussed in detail: Illinois, Alabama, and Texas. These states were selected because they have quite different emergency-response programs. Therefore, these state programs provide a wide variety of approaches to state radiation emergency response

  5. Chinese experience on medical response to radiation emergencies

    International Nuclear Information System (INIS)

    Liu, Ying; Qin, Bin; Lei, Cuiping; Chen, Huifang; Han, Yuhong

    2008-01-01

    Full text: Chinese Center for Medical Response to Radiation Emergency (CCMRRE) was established in 1992, based on the National Institute for Radiological Protection, China CDC (NIRP, China CDC). CCMRRE is a liaison of WHO/REMPAN and functions as a national and professional institute for medical preparedness and response to emergencies involving radioactive material. CCMRRE participates in drafting National Medical Assistant Program for Radiation Emergency and relevant technical documents, develops preventive measures and technique means of medical preparedness and response to radiation emergency. CCMRRE is responsible for medical response to radiological or nuclear accident on national level. CCMRRE holds training courses, organizes drills and provides technical support to local medical organizations in practicing medical preparedness and response to radiation emergency. CCMRRE collects, analyzes and exchanges information on medical response to radiological and nuclear emergency and establishes relevant database. CCMRRE also guides and participates in radiation pollution monitoring on accident sites. In the past ten years, we accumulate much knowledge and experience on medical response to radiation emergencies. In this context, we will discuss Xinzhou Accident, which took place in 1992 and involved in three deaths, and Ha'erbin Accident that took place in 2005 and involved one death. A father and two brothers in Xinzhou Accident died of over-exposed to 60 Co source and misdiagnosis and improper treatment, which indicates that most general practitioners are uncertain about the health consequences of exposure to ionizing radiation and the medical management of exposed patients. When Ha'erbin Accident happened in 2005, the local hospital gave the right diagnosis and treatment based on the clinic symptoms and signs, which prevent more people suffering from over-expose to 192 Ir source. The distinct changes comes from the education and training to primary doctors related

  6. Emergency response and radiation monitoring systems in Russian regions

    International Nuclear Information System (INIS)

    Arutyunyan, R.; Osipiyants, I.; Kiselev, V.; Ogar, K; Gavrilov, S.

    2008-01-01

    Full text: Preparedness of the emergency response system to elimination of radiation incidents and accidents is one of the most important elements of ensuring safe operation of nuclear power facilities. Routine activities on prevention of emergency situations along with adequate, efficient and opportune response actions are the key factors reducing the risks of adverse effects on population and environment. Both high engineering level and multiformity of the nuclear branch facilities make special demands on establishment of response system activities to eventual emergency situations. First and foremost, while resolving sophisticated engineering and scientific problems emerging during the emergency response process, one needs a powerful scientific and technical support system.The emergency response system established in the past decade in Russian nuclear branch provides a high efficiency of response activities due to the use of scientific and engineering potential and experience of the involved institutions. In Russia the responsibility for population protection is imposed on regional authority. So regional emergence response system should include up-to-date tools of radiation monitoring and infrastructure. That's why new activities on development of radiation monitoring and emergency response system were started in the regions of Russia. The main directions of these activities are: 1) Modernization of the existing and setting-up new facility and territorial automatic radiation monitoring systems, including mobile radiation surveillance kits; 2) Establishment of the Regional Crisis Centres and Crisis Centres of nuclear and radiation hazardous facilities; 3) Setting up communication systems for transfer, acquisition, processing, storage and presentation of data for participants of emergency response at the facility, regional and federal levels; 4) Development of software and hardware systems for expert support of decision-making on protection of personnel, population

  7. Current trends in gamma radiation detection for radiological emergency response

    Science.gov (United States)

    Mukhopadhyay, Sanjoy; Guss, Paul; Maurer, Richard

    2011-09-01

    Passive and active detection of gamma rays from shielded radioactive materials, including special nuclear materials, is an important task for any radiological emergency response organization. This article reports on the current trends and status of gamma radiation detection objectives and measurement techniques as applied to nonproliferation and radiological emergencies. In recent years, since the establishment of the Domestic Nuclear Detection Office by the Department of Homeland Security, a tremendous amount of progress has been made in detection materials (scintillators, semiconductors), imaging techniques (Compton imaging, use of active masking and hybrid imaging), data acquisition systems with digital signal processing, field programmable gate arrays and embedded isotopic analysis software (viz. gamma detector response and analysis software [GADRAS]1), fast template matching, and data fusion (merging radiological data with geo-referenced maps, digital imagery to provide better situational awareness). In this stride to progress, a significant amount of inter-disciplinary research and development has taken place-techniques and spin-offs from medical science (such as x-ray radiography and tomography), materials engineering (systematic planned studies on scintillators to optimize several qualities of a good scintillator, nanoparticle applications, quantum dots, and photonic crystals, just to name a few). No trend analysis of radiation detection systems would be complete without mentioning the unprecedented strategic position taken by the National Nuclear Security Administration (NNSA) to deter, detect, and interdict illicit trafficking in nuclear and other radioactive materials across international borders and through the global maritime transportation-the so-called second line of defense.

  8. Integration of radiation monitoring for nuclear emergency response teams

    Energy Technology Data Exchange (ETDEWEB)

    Olsen, J T; Thompson, N Y [Royal Military Coll. of Canada, Kingston, ON (Canada)

    1994-12-31

    The Canadian Forces have established Nuclear Emergency Response Teams to cope with potential radiation accidents. Previously, only gamma and high-energy beta radiation could be detected. Recently, new radiation sampling, detecting, and analytical equipment has been bought, including air samplers, beta counters, high-purity germanium gamma detectors, and multi-channel analyzers together with Gamma Vision Software to analyze gamma spectra. The purpose of the present study is to propose a way to use the new equipment, to analyze the results from the gamma and beta detectors, and to integrate the results into a format for decision making. Integration is achieved through the creation of a computer program, Radiation Integration Program (RIP). This program analyzes gross beta counts, and uses them to estimate danger to the thyroid. As well the results from Gamma Vision are converted from Bq to dose rate for several parts of the body. Overall gamma results affecting the thyroid are compared to the beta results to verify the initial estimations.

  9. System of medical response to radiation emergency after a terror attack in China

    International Nuclear Information System (INIS)

    Liu, Y.; Wang, Z.

    2005-01-01

    Full text: Nuclear or radiological accident is an unintended or unexpected event occurring with a radiation source or during a practice involving ionizing radiation, which may result in significant human exposure and/or material damage. Recent events involving terrorist activities have focused attention on the radiological threats. The full spectrum of radiological threats from terrorist spans the deliberate dispersal of radioactive material to the detonation of a nuclear weapon. While the most likely threat is the dispersal of radioactive materials, the use of a crude nuclear weapon against a major city cannot be dismissed. Radiological incident response requires functions similar to non-radiological incident response. Radiation emergency system in China has been established for radiological emergency preparedness and response. National coordination committee of radiation emergency has been setup in 1994, which consist of 17 ministries. The ministry is responsible for the medical assistance for radiation emergency. Chinese Center for Medical Response to Radiation Emergency (CCMRRE) was established in 1992, based on the National Institute for Radiological Protection, China CDC (NIRP, China CDC). The CCMRRE has been as one liaison institutes of WHO/REMPAN and functions as a national and professional institute for medical assistance in radiation accidents and terrorist events involving radioactive material. Under Provincial Committee of Radiation Emergency, there are local organizations of medical assistance in radiation emergency. The organizations carry out the first aid, regional clinic treatment, radiation protection and radiation monitory in nuclear accidents and radiological accidents. (author)

  10. A knowledge based system for training radiation emergency response personnel

    International Nuclear Information System (INIS)

    Kuriakose, K.K.; Peter, T.U.; Natarajan, A.

    1992-01-01

    One of the important aspects of radiation emergency preparedness is to impart training to emergency handling staff. Mock exercises are generally used for this purpose. But practical considerations limit the frequency of such exercises. A suitably designed computer software can be effectively used to impart training. With the advent of low cost personal computers, the frequency with which the training programme can be conducted is unlimited. A computer software with monotonic behaviour is inadequate for such training. It is necessary to provide human like tutoring capabilities. With the advances in knowledge based computer systems, it is possible to develop such a system. These systems have the capability of providing individualized training. This paper describes the development of such a system for training and evaluation of agencies associated with the management of radiation emergency. It also discusses the utility of the software as a general purpose tutor. The details required for the preparation of data files and knowledge base files are included. It uses a student model based on performance measures. The software is developed in C under MS-DOS. It uses a rule based expert system shell developed in C. The features of this shell are briefly described. (author). 5 refs

  11. Problems of medical personnel deontology during radiation emergency response

    International Nuclear Information System (INIS)

    Poplavskij, K.K.; Popov, A.O.

    1990-01-01

    Problems of deontology in the process of liquidation of radiation accident consequences are considered in the article. It is noted, that shortages of ethical nature in the activities of physicians are related to insufficient qualification of medical personnel in the area of radiation medicine. Problems of medical personnel participation in the large scale propaganda activities among various groups of population are considered. 5 refs

  12. Public health response to radiation emergencies and the role of the Helsinki Project Office

    International Nuclear Information System (INIS)

    Baverstock, Keith F.

    1997-01-01

    This paper focuses on the public health element of nuclear emergency preparedness, defined as the mitigation of the long-term effects of radiation on exposed populations, as opposed to dealing with the health consequences of an exposure in an individual (termed medical aspects). The paper also approaches to the role of the Helsinki Project Office which is concerned with the protection of public health through effective response to nuclear emergencies, and falling into two categories, namely contingency planning or preparedness, and response

  13. Modernisation of Radiation Monitoring Room as a Part of Slovenian Emergency Response Centre

    International Nuclear Information System (INIS)

    Sarvari, A.; Mitic, D.

    2003-01-01

    In the year 2002 the Slovenian Nuclear Safety Administration (SNSA) moved to the new premises therefore it had to rearrange some of its rooms for the emergency situation. SNSA does not operate with a dedicated Emergency Response Centre (ERC), instead of it the SNSA has to rearrange the existing rooms in case of an emergency. Modernisation of the equipment, with the help of government of the United Kingdom of Great Britain and Northern Ireland, for the emergency situation was carried out, especially in the monitoring room. The radiation monitoring system, which is placed in the monitoring room, continuously collects, processes and archives the incoming data of exposure to radiation and meteorological parameters on the Slovenian territory (A model national emergency response plan for radiological accidents, IAEA, Vienna, 1993. IAEA-TECDOC-718). In the emergency situation the monitoring room transforms into the room for the Dose Assessment Group (DAG), which is part of ERC (IAEA emergency response network, IAEA, Vienna, 2000, EPR-ERNET (2000)). The modernisation of monitoring room and within the DAG room with new equipment and its purpose is described in this article. Modernisation of the monitoring room and the room for DAG showed to be inevitably needed. Modernisation of the monitoring room has brought the SNSA a sophisticated and reliable system of controlling the external exposure to radiation on the Slovenian territory. The equipment, especially the equipment for the use in the emergency situation, brought novelties for the Dose Assessment Group. The group has now better and easier control of radiation situation in case of an accident. In overall this modernisation has put the Slovenian Nuclear Safety Administration a step forward in having a dedicated Emergency Response Centre, since it does not need to rearrange the room for the Dose Assessment Group. (author)

  14. Lessons Learned from the Response to Radiation Emergencies (1945-2010) (French Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  15. Lessons Learned from the Response to Radiation Emergencies (1945-2010) (Spanish Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the … application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  16. Lessons Learned from the Response to Radiation Emergencies (1945-2010) (Arabic Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  17. Lessons Learned from the Response to Radiation Emergencies (1945-2010)

    International Nuclear Information System (INIS)

    2012-01-01

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  18. Lessons Learned from the Response to Radiation Emergencies (1945-2010)

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2012-08-15

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  19. Lessons Learned from the Response to Radiation Emergencies (1945-2010) (Russian Edition)

    International Nuclear Information System (INIS)

    2013-01-01

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  20. Optimization of in-vivo monitoring program for radiation emergency response

    Energy Technology Data Exchange (ETDEWEB)

    Ha, Wi Ho; Kim, Jong Kyung [Dept. of Nuclear Engineering, Hanyang University, Seoul (Korea, Republic of)

    2016-12-15

    In case of radiation emergencies, internal exposure monitoring for the members of public will be required to confirm internal contamination of each individual. In-vivo monitoring technique using portable gamma spectrometer can be easily applied for internal exposure monitoring in the vicinity of the on-site area. In this study, minimum detectable doses (MDDs) for '1'3'4Cs, {sup 137}Cs, and {sup 131}I were calculated adjusting minimum detectable activities (MDAs) from 50 to 1,000 Bq to find out the optimal in-vivo counting condition. DCAL software was used to derive retention fraction of Cs and I isotopes in the whole body and thyroid, respectively. A minimum detectable level was determined to set committed effective dose of 0.1 mSv for emergency response. We found that MDDs at each MDA increased along with the elapsed time. 1,000 Bq for {sup 134}Cs and {sup 137}Cs, and 100 Bq for {sup 131}I were suggested as optimal MDAs to provide in-vivo monitoring service in case of radiation emergencies. In-vivo monitoring program for emergency response should be designed to achieve the optimal MDA suggested from the present work. We expect that a reduction of counting time compared with routine monitoring program can achieve the high throughput system in case of radiation emergencies.

  1. Joint radiation emergency management plan of the international organizations. Emergency preparedness and response. Date effective: 1 December 2002

    International Nuclear Information System (INIS)

    2002-11-01

    directives and regulations that bear on emergency response arrangements among some States. There are also bilateral agreements between some international organizations that also have relevance to preparedness and response arrangements. In March 2002, the IAEA Board of Governors approved a Safety Requirements document to be issued according to the IAEA's statutory function 'to establish ... standards of safety for protection of health and minimization of danger to life and property'. These Safety Requirements, entitled 'Preparedness and Response for a Nuclear or Radiological Emergency' (GS-R-2), are being jointly sponsored by the FAO, IAEA, the International Labour Organisation (ILO), the OECD Nuclear Energy Agency (NEA/OECD), the United Nations Office for the Co-ordination of Humanitarian Affairs (OCHA), the Pan American Health Organization (PAHO) and WHO. These safety standards imply additional expectations with regard to operational emergency response arrangements. It has been recognized by the organizations responsible for emergency response, and reflected in the above requirements, that good planning in advance of an emergency can substantially improve the response. Moreover, one of the most important features of emergency response plans is to have clear lines of responsibility and authority. With this in mind, the IAEA, the organizations party to the Conventions, and some other international organizations that participate in the activities of the IACRNA develop and maintain this 'Joint Radiation Emergency Management Plan of the International Organizations' (the Joint Plan), which describes: the objectives of response; the organizations involved in response, their roles and responsibilities, and the interfaces among them and between them and States; operational concepts; and preparedness arrangements. These practical arrangements are reflected in the various organizations own emergency plans. The IAEA is the main co-ordinating body for development and maintenance of the

  2. Preparation and response to radiation and nuclear emergencies in case of natural disasters

    International Nuclear Information System (INIS)

    Vegueria, Pablo Jerez; Lafortune, J.F.

    2013-01-01

    The impact of natural disasters in cities and communities has grown by different causes in different parts of the world. There are several examples of the impact that have caused extreme natural events in facilities and activities in which ionizing radiation are used. The recent example of the accident at the nuclear power plant of Fukushima Daichi with release of radioactive substances to the environment caused by an earthquake and a tsunami show the need of the increasing improvement in the safety of facilities and activities that use ionizing radiation and radioactive materials in general. Planning and response to events of this nature is another aspect that is important and needs attention. The IAEA documents offer a comprehensive and effective guide to achieve an appropriate degree of readiness to respond to nuclear and radiological emergencies in any situation. However, there are specific challenges for planning and response posed a radiological emergency caused by an extreme natural event or occurring simultaneously with this. The present work deals with essential aspects to take into account by the authorities who coordinate the planning and response to radiological emergencies to deal with extreme natural events

  3. Joint radiation emergency management plan of the international organizations. Emergency preparedness and response. Date effective: 1 January 2007

    International Nuclear Information System (INIS)

    2007-01-01

    binding treaties and have directives and regulations that bear on emergency response arrangements among some States. There are also bilateral agreements between some international organizations that also have relevance to preparedness and response arrangements. In March 2002, the IAEA issued Safety Requirements, entitled 'Preparedness and Response for a Nuclear or Radiological Emergency' (GS-R-2), jointly sponsored by the FAO, IAEA, the International Labour Organization (ILO), the OECD Nuclear Energy Agency (OECD/NEA), the United Nations Office for the Coordination of Humanitarian Affairs (OCHA), the Pan American Health Organization (PAHO) and WHO. These safety standards imply additional expectations with regard to operational emergency response arrangements. It is recognized by the participating organizations, and reflected in the above requirements, that good planning in advance of an emergency can substantially improve the response. With this in mind, the IAEA, the organizations party to the Conventions, and some other international organizations that participate in the activities of the IACRNA develop and maintain this 'Joint Radiation Emergency Management Plan of the International Organizations' (the Joint Plan), which describes: the objectives of response; the organizations involved in response, their roles and responsibilities, and the interfaces among them and between them and States; operational concepts; and preparedness arrangements. The various organizations reflect these arrangements in their own emergency plans. The IAEA is the main co-ordinating body for development and maintenance of the Joint Plan. All States irrespective whether they are party to one or other of the two Conventions are invited to adopt arrangements that are compatible with those described here when providing relevant information about nuclear or radiological emergencies to relevant international organizations, in order to minimize the radiological consequences and to facilitate the

  4. Emergency response workers workshop

    International Nuclear Information System (INIS)

    Agapeev, S.A.; Glukhikh, E.N.; Tyurin, R.L.

    2012-01-01

    A training workshop entitled Current issues and potential improvements in Rosatom Corporation emergency prevention and response system was held in May-June, 2012. The workshop combined theoretical training with full-scale practical exercise that demonstrated the existing innovative capabilities for radiation reconnaissance, diving equipment and robotics, aircraft, emergency response and rescue hardware and machinery. This paper describes the activities carried out during the workshop [ru

  5. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies - Training Materials

    International Nuclear Information System (INIS)

    2013-01-01

    These materials are designed for use at a four day training course on the application of cytogenetic dosimetry in preparedness for and response to radiation emergencies. They contain information on: (1) Basics of biological effects of ionizing radiation: Parts 1+2; (2) Basics of dosimetry; (3) dicentric assay; (4) Retrospective dosimetry by translocation analysis; (5) Premature chromosome condensation analysis; (6) Cytokinesis block micronucleus assay; (7) Applied statistics for biodosimetry; (8) Automatic analysis of chromosomal assays; (9) Biodosimetry in mass casualty events; (10) Safety of laboratory staff and quality programmes; (11) Examples of accident investigations; (12) Cytogenetic dose estimation in the criticality accident in Tokaimura; (13) Radiological accidents in Latin America; (14) Radiological accidents in Georgia. Additionally, the CD contains two working sessions with the reference materials for use and a standard training programme. This training course consists of lectures and work sessions that can easily be utilized by a State to build a basic capability in biodosimetry application in a nuclear or radiological emergency

  6. Uncertainty of fast biological radiation dose assessment for emergency response scenarios.

    Science.gov (United States)

    Ainsbury, Elizabeth A; Higueras, Manuel; Puig, Pedro; Einbeck, Jochen; Samaga, Daniel; Barquinero, Joan Francesc; Barrios, Lleonard; Brzozowska, Beata; Fattibene, Paola; Gregoire, Eric; Jaworska, Alicja; Lloyd, David; Oestreicher, Ursula; Romm, Horst; Rothkamm, Kai; Roy, Laurence; Sommer, Sylwester; Terzoudi, Georgia; Thierens, Hubert; Trompier, Francois; Vral, Anne; Woda, Clemens

    2017-01-01

    Reliable dose estimation is an important factor in appropriate dosimetric triage categorization of exposed individuals to support radiation emergency response. Following work done under the EU FP7 MULTIBIODOSE and RENEB projects, formal methods for defining uncertainties on biological dose estimates are compared using simulated and real data from recent exercises. The results demonstrate that a Bayesian method of uncertainty assessment is the most appropriate, even in the absence of detailed prior information. The relative accuracy and relevance of techniques for calculating uncertainty and combining assay results to produce single dose and uncertainty estimates is further discussed. Finally, it is demonstrated that whatever uncertainty estimation method is employed, ignoring the uncertainty on fast dose assessments can have an important impact on rapid biodosimetric categorization.

  7. A mobile radiological laboratory for rapid response to off-site radiation emergencies

    Energy Technology Data Exchange (ETDEWEB)

    Katoch, D. S.; Sharma, R. C.; Mehta, D. J.; Raj, V. Venkat [Bhabha Atomic Research Centre, Mumbai (India)

    2002-07-01

    A mobile radiological laboratory (MRL) has been designed and developed primarily for providing a rapid response to radiation emergencies arising as a consequence of nuclear and/or radiological accidents. It is equipped specifically to monitor the environment and provide quick assessment of radiological hazards to the population living within a radius of 30 km around a nuclear facility. In this paper, various design features of an Indian MRL together with the details of installed equipment are presented. The MRL has been designed for a continuous outdoor operation of about two weeks. It is built on a 10.70 m long air suspension Bus Chassis and has four sections : Driver's Cabin, Main Counting Laboratory, Whole Body Monitor and Rear section housing general utilities. The electric power is provided by two diesel generators during field operation and by 230 V AC mains supply at headquarters and wherever possible. The equipment installed in the MRL includes : Alpha, beta and gamma counting systems and low and high volume air samplers for the assessment of radioactive contents in the samples of air, water, soil and vegetation; environment dose rate meters and a variety of survey meters for evaluating any potential increase in radiation levels; personal dosimeters to control external radiation exposure; personal protective equipment for avoiding skin and clothing contamination; a chair type of whole body monitor for the assessment of internal radioactive contamination of the human body, in particular, thyroidal uptake of radioiodine; an automatic weather station for recording continuously the meteorological parameters and a satellite based global positioning system to continuously track and display the geographical location of the MRL. The calibrations of the installed equipment are presently in progress. Preliminary results obtained for the methods needed for rapid detection of gamma emitters in the environment and human body, namely, in situ gamma spectrometry and

  8. Emergency response activities and collecting damaged radiation devices from a war affected area in Croatia

    International Nuclear Information System (INIS)

    Subasic, Damir; Schaller, Antum

    1997-01-01

    A number of various devices containing ionizing radiation sources were in use in the area affected by the recent war in Croatia. In destruction caused by the war operations, a number of these devices were damaged, destroyed or even missed/lost. The actions undertaken to (re)collect these radiation sources, experience gained and lessons learned are reviewed. The importance of a well-organized national regulatory system is highlighted as a precondition for the efficient identification and safe collection of radiation sources which were under ruins. Experience from this event could be well applicable to similar situations caused by disasters and particularly for regulatory authorities who design emergency preparedness plans. (author)

  9. Emergency preparedness incident response and radiation monitoring in Finland. Annual report 1999

    International Nuclear Information System (INIS)

    Ristonmaa, S.

    2000-04-01

    The Radiation and Nuclear Safety Authority (STUK) publishes annually a report about STUK's preparedness measures. The report describes notifications received by STUK's on duty system and further measures carried out after receiving a message. In addition, the emergence exercises STUK participated in during the year are described. The radiation situation in Finland is continuously monitored. STUK is the authority who carries out a wide range of environmental measurements, sampling and sensitive laboratory analyses. The measurement results are presented in the form of tables and graphically. (editor)

  10. Emergency preparedness incident response and radiation monitoring in Finland. Annual report 1998

    International Nuclear Information System (INIS)

    Ristonmaa, S.

    1999-03-01

    The Radiation and Nuclear Safety Authority (STUK) publishes annually a report about STUK's preparedness measures. The report describes notifications received by STUK's on duty system and further measures carried out after receiving a message. In addition, the emergence exercises STUK participated in during the year are described. The radiation situation in Finland is continuously monitored. STUK is the authority who carries out a wide range of environmental measurements, sampling and sensitive laboratory analyses. The measurement results are presented in the form of tables and graphically. (editor)

  11. Joint radiation emergency management plan of the international organizations. Emergency preparedness and response. Date effective: 1 December 2004

    International Nuclear Information System (INIS)

    2004-11-01

    The Convention on Early Notification of a Nuclear Accident (the 'Early Notification Convention') and the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the 'Assistance Convention') are the prime legal instruments that establish an international framework to facilitate the exchange of information and the prompt provision of assistance in the event of a nuclear accident or radiological emergency, with the aim of minimizing the consequences. The International Atomic Energy Agency (IAEA) has specific functions assigned to it under these Conventions, to which, in addition to a number of States, the World Health Organization (WHO), the World Meteorological Organization (WMO) and the Food and Agriculture Organization of the United Nations (FAO) are full Parties. Since 1989, the arrangements between these organizations for facilitating the practical implementation of those articles of the two Conventions that are operational in nature have been documented by the IAEA in the Emergency Notification and Assistance Technical Operations Manual (ENATOM). The manual is intended for use primarily by contact points as identified in the Conventions. Pursuant to the obligations placed on it by the Conventions, the IAEA regularly convenes the Inter-Agency Committee on Response to Nuclear Accidents (IACRNA)2, whose purpose is to co-ordinate the arrangements of the relevant international intergovernmental organizations ('international organizations') for preparing for and responding to nuclear or radiological emergencies. Although the Conventions assign specific response functions and responsibilities to the IAEA and the Parties, various international organizations have - by virtue of their statutory functions or of related legal instruments - general functions and responsibilities that encompass aspects of preparedness and response. Moreover, some regional organizations (e.g. the European Union) are party to legally binding treaties and have

  12. Emergency response activities and collecting damaged radiation devices from a war affected area in Croatia

    Energy Technology Data Exchange (ETDEWEB)

    Subasic, Damir; Schaller, Antum [APO-Hazardous Waste Management Agency, Zagreb (Croatia)

    1997-12-31

    A number of various devices containing ionizing radiation sources were in use in the area affected by the recent war in Croatia. In destruction caused by the war operations, a number of these devices were damaged, destroyed or even missed/lost. The actions undertaken to (re)collect these radiation sources, experience gained and lessons learned are reviewed. The importance of a well-organized national regulatory system is highlighted as a precondition for the efficient identification and safe collection of radiation sources which were under ruins. Experience from this event could be well applicable to similar situations caused by disasters and particularly for regulatory authorities who design emergency preparedness plans. (author) 4 refs., 1 tab.

  13. Radiation-induced damage analysed by luminescence methods in retrospective dosimetry and emergency response.

    Science.gov (United States)

    Woda, Clemens; Bassinet, Céline; Trompier, François; Bortolin, Emanuela; Della Monaca, Sara; Fattibene, Paola

    2009-01-01

    The increasing risk of a mass casualty scenario following a large scale radiological accident or attack necessitates the development of appropriate dosimetric tools for emergency response. Luminescence dosimetry has been reliably applied for dose reconstruction in contaminated settlements for several decades and recent research into new materials carried close to the human body opens the possibility of estimating individual doses for accident and emergency dosimetry using the same technique. This paper reviews the luminescence research into materials useful for accident dosimetry and applications in retrospective dosimetry. The properties of the materials are critically discussed with regard to the requirements for population triage. It is concluded that electronic components found within portable electronic devices, such as e.g. mobile phones, are at present the most promising material to function as a fortuitous dosimeter in an emergency response.

  14. Emerging radiation protection

    International Nuclear Information System (INIS)

    Allard, D.J.

    1993-01-01

    In recent years, a number of radiation protection issues have emerged into the public forum. The perceived high risks associated with radiation exposure, and disproportionate media attention to such issues, have contributed to heightened concerns by the public and the individual occupationally exposed worker. This paper examines the new and controversial radiation risk estimates of the National Research Council's BEIR V committee, which are based on the most current atomic-bomb survivor data and a revised dosimetry model. These risk estimates are somewhat higher than past values, and may eventually impact the legal framework in the United States through the regulations of the EPA, NRC, DOE, OSHA, and other agencies that set radiation exposure standards. Additionally, present regulations and standards are often based upon differing levels of acceptable risk, which have led to conflicting exposure and effluent release criteria. Further, due to inherent boundaries in legal authority, many potentially significant sources of radiation exposure to the public remain unregulated Radiation exposure scenarios such as medical x-ray, radon, and other technology enhanced sources have no legal limits. These issues and others are examined and analyzed with respect to regulatory policy

  15. Radiological emergencies the first response

    International Nuclear Information System (INIS)

    2011-11-01

    This national training course about radiological emergencies first answer include: Targets and preparation for emergency response in case of a nuclear or radiological accident. Operations center, action guide for fire fighting, medical coverage, forensic test, first aid, basic instrumentation for radiation, safety equipment, monitoring radiation, gamma rays, personnel exposed protection , radiation exposure rate, injury and illness for radiation, cancer risk, contamination, decontamination and treatment, markers, personnel dosimetry, training, medical and equipment transportation, shielded and tools. Psychological, physical (health and illness), economical (agriculture and industry) and environment impacts. Terrorist attacks, security belts. Support and international agreements (IAEA)

  16. A web based on-line radiation early warning system for emergency preparedness and response centre

    International Nuclear Information System (INIS)

    Bhujbal, Vaibhav; Saindane, Shashank S.; Narasaiah, M.V.R.; Murali, S.

    2018-01-01

    The topography of the Bhabha Atomic Research Centre, Trombay site, where all major components of nuclear fuel cycle activities are located is very complex in nature. The assessment of the radiological impact, if any, due to atmospheric releases from these facilities within BARC site is being carried out by using a Local Area Network (LAN) based Radiation Early Warning System and meteorological parameters. The upgraded system is aimed at providing data during normal operation of the various facilities at site and for providing early warning to decision makers in case of any onset of an emergency. It is carried out by acquiring both on-line and off-line data on releases from the plants, the environmental radiation dose rate at selected locations and other related parameters. The monitors placed at these selected locations including strategic point around the BARC site can also help in detecting any attempt of unauthorized trafficking of the radioactive sources. This paper explains different aspects of the system operating at BARC

  17. Development of a high speed three-dimensional radiation detecting system for the emergency response robot

    Energy Technology Data Exchange (ETDEWEB)

    Lee, Nam Ho; Lee, Yong Duk; Choi, Chang Whan; Jung, Kyung Min; Moon, Myung Kook; Kim, Hee Moon

    2007-02-15

    Technologies for managing the emergency leak accident of radioactive materials have been developed actively in USA, Japan, and Russia, since the Chernobyl nuclear disaster in Russia and nuclear fuel accident in Japan Nuclear fuel Conversion cooperation had occurred. A robot (Pioneer) for managing radioactive materials have been developed in co-operation of USA(CMU), Japan, and Russia. The pioneer is recently examined its performance through exploring test in the Chernobyl nuclear reactor. The exploring function of these system is quite different with a dosimeter for a worker in operation, installation, and radiation measurement. So, it is inevitable to develop a new system. The developed system from now is so expensive and slow in operation. So this problem is pending and must be improved. In this research, instead of an existing expensive system, a CCD(or CMOS) sensor, which has high resolution (640 X 480) and high signal process (30 frame/sec), is used for exploring radioactive materials as economical view and image consideration. The connection with image processing, 3D imaging technology, and radioactive exploring can visualize imaginary radiation source and can improve exploring and managing radioactive materials.

  18. Emergency response activities and the collection of damaged radiation devices in the war areas of Croatia

    International Nuclear Information System (INIS)

    Subasic, D.; Schaller, A.

    1998-01-01

    Several kinds of devices containing sources of ionizing radiation had been in use in the areas of Croatia which were affected by the recent war, principally in industrial and medical applications. The greater share of these devices was constituted by 151 radioactive lightning conductors with a maximum individual activity of 19.5 GBq and some 8300 smoke detectors. In the destruction caused by the war, some of these devices were damaged, destroyed or lost. The actions undertaken to retrieve them and their sources are described, as well as the experience gained and lessons learned. The importance of a well organized national regulatory system is underscored as a precondition for the efficient identification and safe recovery of radiation sources lying amidst the ruins in the area affected by the war. The experience gained in these actions may be applicable to similar situations caused by natural disasters such as earthquakes, floods, hurricanes, etc. and of particular interest to regulatory authorities for the drawing up of emergency preparedness plans. (author)

  19. Emergency preparedness and response

    International Nuclear Information System (INIS)

    Griffiths, M.

    1996-01-01

    After the Chernobyl accident, it became painfully obvious to the international community that there was an urgent need to establish a system for the coordination of international disaster assistance. It became the task of the United Nations Office for Disaster Relief (UNDRO) to develop such a system. The former UNDRO was subsumed into the Department of Humanitarian Affairs (DHA), established in January 1992 on the basis of UN General Assembly Resolution 46/182 adopted in December 1991, and the disaster relief system presently found in DHA is a further evolution of the system established by UNDRO. One particular importance in relation to nuclear accidents is the fact that UNDRO and the International Atomic Energy Agency (IAEA) signed a Memorandum of Understanding defining their respective responsibilities and the need for cooperation in case of accidents involving the unintentional release of nuclear radiation. In essence, the MOU makes it clear that the responsibilities of the IAEA, in connection with accidents at Nuclear Power Plants, related to the technical and radiological aspects, in particular to accident prevention, to the on-site preparedness, and to remedial measures within the 30-km zone outside the NPP. DHA's responsibilities, on the other hand, relate to the general preparedness and the rescue efforts outside the 30 km zone. In this respect, the preparedness and emergency response system is no different from the system employed in any other type of sudden-onset emergency

  20. Radiation Emergency Planning in Petroleum Industry

    International Nuclear Information System (INIS)

    El-Shinawy, R.M.K.; El-Naggar, M.A.; Abdel-Fattah, A.T.; Gomaa, A.M.

    2001-01-01

    Similar to all industrial activities utilizing radiation sources, or dealing with radioactive materials in its operations, petroleum industry requires the organization of a Radiation Emergency Plan. This plan should be based on a comprehensive and subtle understanding of the extensive multidisciplinary operations involved in petroleum processing and the dangers that threaten human health, environment and property; both from ordinary emergency situations common to petroleum industry activities and also from radiation emergency events. Radiation emergencies include radiological source accidents involving occurrence of high dose exposures. Radioactive contamination or spill are also major problems that may cause low dose exposures and environmental radioactive contamination. The simultaneous occurrence of other industrial emergency events such as fires or structural collapses will add to the seriousness of the emergency situation. The essential aspects of Radiation Emergency Planning include notification, assessment of situation, foresight, definition of roles and responsibilities including health safety and environmental concepts. An important contribution to the Emergency Planning is the proper intelligent medical response. Another essential parameter is the training of personnel that will undertake the responsibility of executing the emergency procedures according to the various emergency situations. The main features of the radiation Emergency Plan in Petroleum industry is presented in the text

  1. Emergency Medical Rescue in a Radiation Environment

    International Nuclear Information System (INIS)

    Briesmeister, L.; Ellington, Y.; Hollis, R.; Kunzman, J.; McNaughton, M.; Ramsey, G.; Somers, B.; Turner, A.; Finn, J.

    1999-01-01

    Previous experience with emergency medical rescues in the presence of radiation or contamination indicates that the training provided to emergency responders is not always appropriate. A new course developed at Los Alamos includes specific procedures for emergency response in a variety of radiological conditions

  2. Joint radiation emergency management plan of the International Organizations. Emergency preparedness and response. Date effective: 1 December 2000

    International Nuclear Information System (INIS)

    2000-12-01

    The Convention on Early Notification of a Nuclear Accident (the 'Early Notification Convention') and the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the 'Assistance Convention') are the prime legal instruments that establish an international framework to facilitate the exchange of information and the prompt provision of assistance in the event of a nuclear accident or radiological emergency, with the aim of minimizing the consequences. The International Atomic Energy Agency (IAEA) has specific functions allocated to it under these Conventions, to which the World Health Organization (WHO), the World Meteorological Organization (WMO) and the Food and Agriculture Organization of the United Nations (FAO) are full Parties. Since 1989, the arrangements between these organizations for facilitating the practical implementation of those articles of the two Conventions which are operational in nature have been documented by the IAEA in the Emergency Notification and Assistance Technical Operations Manual (ENATOM). This manual describes the conceptual link between the IAEA, all other relevant international intergovernmental organizations, States which are IAEA Member States and/or Parties to one or both Conventions, and other States under the terms of the two Conventions. The ENATOM is intended for use primarily by Contact Points as defined in the Convention

  3. Radiological Emergency Response Data

    Data.gov (United States)

    U.S. Environmental Protection Agency — Quality Data Asset includes all current and historical emergency radiological response event and incident of national significance data and surveillance, monitoring,...

  4. Radiation emergency preparedness in nuclear power plants

    International Nuclear Information System (INIS)

    Geetha, P.V.; Ramamirtham, B.; Khot, P.

    2008-01-01

    The purpose of planning for radiation emergency response is to ensure adequate preparedness for protection of the plant personnel and members of the public from significant radiation exposures in the unlikely event of an accident. With a number of safety features in the reactor design and sound operating procedures, the probability of a major accident resulting in the releases of large quantities of radioactivity is extremely small. However, as an abundant cautious approach a comprehensive radiation emergency response preparedness is in place in all the nuclear power plants (NPPs). Radiation Emergency in NPPs is broadly categorized into three types; plant emergency, site emergency and off-site emergency. During off site emergency conditions, based on levels of radiation in the environment, Civil Authorities may impose several counter measures such as sheltering, administering prophylaxis (stable iodine for thyroid blocking) and evacuation of people from the affected area. Environmental Survey Laboratory (ESL) carries out environmental survey extensively in the affected sector identified by the meteorological survey laboratory. To handle emergency situations, Emergency Control Centre with all communication facility and Emergency Equipment Centre having radiation measuring instruments and protective equipment are functional at all NPPs. AERB stipulates certain periodicity for conducting the exercises on plant, site and off site emergency. These exercises are conducted and deficiencies corrected for strengthening the emergency preparedness system. In the case of off site emergency exercise, observers are invited from AERB and Crisis Management Group of Department of Atomic Energy (DAE). The emergency exercises conducted by Nuclear Power Plant Sites have been very satisfactory. (author)

  5. Radiation Emergency Preparedness Tools: Psychological First Aid

    Centers for Disease Control (CDC) Podcasts

    2010-12-30

    This podcast is an overview of the Clinician Outreach and Communication Activity (COCA) Call: Practical Tools for Radiation Emergency Preparedness. A specialist working with CDC's Radiation Studies Branch describes Psychological First Aid and a newly developed multimedia training program, entitled "Psychological First Aid in Radiation Disasters.".  Created: 12/30/2010 by National Center for Environmental Health (NCEH) Radiation Studies Branch and Emergency Risk Communication Branch (ERCB)/Joint Information Center (JIC); Office of Public Health Preparedness and Response (OPHPR).   Date Released: 1/13/2011.

  6. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies (Arabic Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual's working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade

  7. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies

    International Nuclear Information System (INIS)

    2011-01-01

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual's working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade.

  8. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies (Spanish Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual’s working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade

  9. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies (Russian Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual's working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade

  10. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies (Chinese Edition)

    International Nuclear Information System (INIS)

    2015-01-01

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual's working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade

  11. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies (French Edition)

    International Nuclear Information System (INIS)

    2013-01-01

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual's working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade

  12. OEM Emergency Response Information

    Data.gov (United States)

    U.S. Environmental Protection Agency — The Office of Emergency Management retains records of all incident responses in which it participates. This data asset includes three major sources of information:...

  13. Radiation protection guidelines for radiation emergencies

    International Nuclear Information System (INIS)

    Lessard, E.T.; Meinhold, C.B.

    1986-01-01

    The system of dose limitation and present guidance for emergency workers and guidance for intervention on behalf of the public are discussed. There are three elements for the system of dose limitation: justification, optimization and dose limits. The first element is basically a political process in this country. Justification is based on a risk-benefit analysis, and justification of the use of radioactive materials or radiation is generally not within the authority of radiation protection managers. Radiation protection managers typically assess detriments or harm caused by radiation exposure and have very little expertise in assessing the benefits of a particular practice involving nuclear material

  14. Radiation emergency planning in Poland

    Energy Technology Data Exchange (ETDEWEB)

    Niewodniczanski, J [National Atomic Energy Agency, Warsaw (Poland)

    1996-08-01

    The paper presents a schematic outline of the radiation emergency policy in Poland, rather from the point of view of logistics of the problem than discussing details of existing or proposed procedures. (author). 5 refs, 1 fig.

  15. Radiation emergency planning for medical organizations

    International Nuclear Information System (INIS)

    Jerez Vergueria, Sergio F.; Jerez Vergueria, Pablo F.

    1997-01-01

    The possible occurrence of accidents involving sources of ionizing radiation demands response plans to mitigate the consequences of radiological accidents. This paper offers orientations in order to elaborate emergency planning for institutions with medical applications of ionizing radiation. Taking into account that the prevention of accidents is of prime importance in dealing with radioactive materials and others sources of ionizing radiation, such as X-rays, it is recommended that one include in emergency instructions and procedures several aspects relative to causes which originate these radiological events. Topics such as identification of radiological events in these practices and their consequences, protective measures, planning for and emergency response and maintenance of emergency capacity, are considered in this article. (author)

  16. Countermeasures in radiation emergencies

    International Nuclear Information System (INIS)

    Narayanan, K.K.

    1998-01-01

    ICRP Publication 60 (1990) contains recommendations on two radiological situations: (i) Human activities that add radiation exposure to that which people normally incur due to background radiation, or that increases the likelihood of their incurring exposure are termed PRACTICES. Here the occurrences of the exposure are foreseen and can be limited by control of source and by application of the ICRP system of dose limitation and (ii) The human activities that seek to reduce the existing radiation exposure, or the existing likelihood of incurring exposure which is not part of a controlled practice are termed INTERVENTIONS. Here the source of exposure is not subject to control, for example, in accident situations so that any subsequent exposure can be limited only by some form of INTERVENTION. The relevant general recommendations on intervention are that the countermeasures forming a program of intervention, which always have some disadvantage, should be justified in the sense that they should do more good than harm. Their form, scale and duration should be then optimised so as to maximise the net benefit

  17. Emergency preparedness incident response and radiation monitoring in Finland. Annual report 1998; Valmiustapahtumat ja valtakunnallinen saeteilyvalvonta. Vuosiraportti 1998

    Energy Technology Data Exchange (ETDEWEB)

    Ristonmaa, S. [ed.

    1999-03-01

    The Radiation and Nuclear Safety Authority (STUK) publishes annually a report about STUK's preparedness measures. The report describes notifications received by STUK's on duty system and further measures carried out after receiving a message. In addition, the emergence exercises STUK participated in during the year are described. The radiation situation in Finland is continuously monitored. STUK is the authority who carries out a wide range of environmental measurements, sampling and sensitive laboratory analyses. The measurement results are presented in the form of tables and graphically. (editor)

  18. Emergency preparedness incident response and radiation monitoring in Finland. Annual report 1999; Valmiustapahtumat ja saeteilyvalvonta. Vuosiraportti 1999

    Energy Technology Data Exchange (ETDEWEB)

    Ristonmaa, S. [ed.

    2000-04-01

    The Radiation and Nuclear Safety Authority (STUK) publishes annually a report about STUK's preparedness measures. The report describes notifications received by STUK's on duty system and further measures carried out after receiving a message. In addition, the emergence exercises STUK participated in during the year are described. The radiation situation in Finland is continuously monitored. STUK is the authority who carries out a wide range of environmental measurements, sampling and sensitive laboratory analyses. The measurement results are presented in the form of tables and graphically. (editor)

  19. Emergency response strategies

    International Nuclear Information System (INIS)

    Carrilo, D.; Dias de la Cruz, F.

    1984-01-01

    In the present study is estimated, on the basis of a release category (PWR4) and several accident scenarios previously set up, the emergency response efficacy obtained in the application of different response strategies on each of the above mentioned scenarios. The studied strategies contemplate the following protective measures: evacuation, shelter and relocation. The radiological response has been obtained by means of CRAC2 (Calculation of Reactor Accident Consequences) code, and calculated in terms of absorbed dose equivalent (Whole body and thyroid), as well as early and latent biological effects. (author)

  20. Hanford Emergency Response Plan

    International Nuclear Information System (INIS)

    Wagoner, J.D.

    1994-04-01

    The Hanford Emergency Response Plan for the US Department of Energy (DOE), Richland Operations Office (RL), incorporates into one document an overview of the emergency management program for the Hanford Site. The program has been developed in accordance with DOE orders, and state and federal regulations to protect worker and public health and safety and the environment in the event of an emergency at or affecting the Hanford Site. This plan provides a description of how the Hanford Site will implement the provisions of DOE 5500 series and other applicable Orders in terms of overall policies and concept of operations. It should be used as the basis, along with DOE Orders, for the development of specific contractor and RL implementing procedures

  1. Hanford Emergency Response Plan

    Energy Technology Data Exchange (ETDEWEB)

    Wagoner, J.D.

    1994-04-01

    The Hanford Emergency Response Plan for the US Department of Energy (DOE), Richland Operations Office (RL), incorporates into one document an overview of the emergency management program for the Hanford Site. The program has been developed in accordance with DOE orders, and state and federal regulations to protect worker and public health and safety and the environment in the event of an emergency at or affecting the Hanford Site. This plan provides a description of how the Hanford Site will implement the provisions of DOE 5500 series and other applicable Orders in terms of overall policies and concept of operations. It should be used as the basis, along with DOE Orders, for the development of specific contractor and RL implementing procedures.

  2. Survey of Canadian hospitals radiation emergency plans

    Energy Technology Data Exchange (ETDEWEB)

    Davis, C [Social Data Research Ltd./The Flett Consulting Group, Inc., Ottawa, ON (Canada)

    1996-02-01

    This report documents the findings of a survey of Canadian hospitals conducted by Social Data Research Ltd. during the Spring and Summer, 1995. The main objective of the survey was to determine the state of readiness of Canadian hospitals in respect of radiation emergency planning. In addition, the AECB was interested in knowing the extent to which a report by the Group of Medical Advisors, `GMA-3: Guidelines on Hospital Emergency Plans for the Management of Minor Radiation Accidents`, which was sponsored and distributed in 1993, was received and was useful to hospital administrators and emergency personnel. A self-administered questionnaire was distributed to 598 acute care hospitals, and 274 responses were received. The main conclusion of this study is that, with the exception of a few large institutions, hospitals generally do not have specific action plans to handle minor radiation accidents. (author).

  3. Survey of Canadian hospitals radiation emergency plans

    International Nuclear Information System (INIS)

    Davis, C.

    1996-02-01

    This report documents the findings of a survey of Canadian hospitals conducted by Social Data Research Ltd. during the Spring and Summer, 1995. The main objective of the survey was to determine the state of readiness of Canadian hospitals in respect of radiation emergency planning. In addition, the AECB was interested in knowing the extent to which a report by the Group of Medical Advisors, 'GMA-3: Guidelines on Hospital Emergency Plans for the Management of Minor Radiation Accidents', which was sponsored and distributed in 1993, was received and was useful to hospital administrators and emergency personnel. A self-administered questionnaire was distributed to 598 acute care hospitals, and 274 responses were received. The main conclusion of this study is that, with the exception of a few large institutions, hospitals generally do not have specific action plans to handle minor radiation accidents. (author)

  4. Wind emergency response system

    International Nuclear Information System (INIS)

    Garrett, A.J.; Buckner, M.R.; Mueller, R.A.

    1981-01-01

    The WIND system is an automated emergency response system for real-time predictions of the consequences of liquid and airborne releases from SRP. The system consists of a minicomputer and associated peripherals necessary for acquisition and handling of large amounts of meteorological data from a local tower network and the National Weather Service. The minicomputer uses these data and several predictive models to assess the impact of accidental releases. The system is fast and easy to use, and output is displayed both in tabular form and as trajectory map plots for quick interpretation. The rapid response capabilities of the WIND system have been demonstrated in support of SRP operations

  5. Operational guidance for radiation emergency response organisations in Europe for using biodosimetric tools developed in EU MULTIBIODOSE project.

    Science.gov (United States)

    Jaworska, Alicja; Ainsbury, Elizabeth A; Fattibene, Paola; Lindholm, Carita; Oestreicher, Ursula; Rothkamm, Kai; Romm, Horst; Thierens, Hubert; Trompier, Francois; Voisin, Philippe; Vral, Anne; Woda, Clemens; Wojcik, Andrzej

    2015-04-01

    In the event of a large-scale radiological emergency, the triage of individuals according to their degree of exposure forms an important initial step of the accident management. Although clinical signs and symptoms of a serious exposure may be used for radiological triage, they are not necessarily radiation specific and can lead to a false diagnosis. Biodosimetry is a method based on the analysis of radiation-induced changes in cells of the human body or in portable electronic devices and enables the unequivocal identification of exposed people who should receive medical treatment. The MULTIBIODOSE (MBD) consortium developed and validated several biodosimetric assays and adapted and tested them as tools for biological dose assessment in a mass-casualty event. Different biodosimetric assays were validated against the 'gold standard' of biological dosimetry-the dicentric assay. The assays were harmonised in such a way that, in an emergency situation, they can be run in parallel in a network of European laboratories. The aim of this guidance is to give a concise overview of the developed biodosimetric tools as well as how and when they can be used in an emergency situation. © The Author 2014. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.

  6. Operational guidance for radiation emergency response organisations in Europe for using bio-dosimetric tools developed in EU MULTIBIODOSE project

    International Nuclear Information System (INIS)

    Jaworska, Alicja; Ainsbury, Elizabeth A.; Rothkamm, Kai; Fattibene, Paola; Lindholm, Carita; Oestreicher, Ursula; Romm, Horst; Thierens, Hubert; Vral, Anne; Trompier, Francois; Voisin, Philippe; Woda, Clemens; Wojcik, Andrzej

    2015-01-01

    In the event of a large-scale radiological emergency, the triage of individuals according to their degree of exposure forms an important initial step of the accident management. Although clinical signs and symptoms of a serious exposure may be used for radiological triage, they are not necessarily radiation specific and can lead to a false diagnosis. Biodosimetry is a method based on the analysis of radiation-induced changes in cells of the human body or in portable electronic devices and enables the unequivocal identification of exposed people who should receive medical treatment. The MULTIBIODOSE (MBD) consortium developed and validated several bio-dosimetric assays and adapted and tested them as tools for biological dose assessment in a mass-casualty event. Different bio-dosimetric assays were validated against the 'gold standard' of biological dosimetry-the dicentric assay. The assays were harmonised in such a way that, in an emergency situation, they can be run in parallel in a network of European laboratories. The aim of this guidance is to give a concise overview of the developed bio-dosimetric tools as well as how and when they can be used in an emergency situation. (authors)

  7. Radiation protection programme for emergency exposure situations

    International Nuclear Information System (INIS)

    Amoah, Peter Atta

    2016-04-01

    An assessment of the Radiation Protection of Emergency Exposure Situations in Ghana was carried out in relation to documents provided by the International Atomic Energy Agency (IAEA). As realized in the document of the “Method for Developing Arrangements for Response to a Nuclear or Radiological Emergency” of the IAEA, the National Nuclear and Radiological Emergency Response Plan (NNRERP) of Ghana also discusses the Infrastructural and Functional Requirements necessary for the intervention of a nuclear or radiological emergency. The NNRERP describes the concept of operations for a response designed to facilitate the delivery of coordinated assistance to government authorities such as the National Disaster Management Organisation (NADMO), the Radiation Protection Board (RPB) and other participating organizations. From the NNRERP, practices in Ghana, fall into emergency planning category III and IV. As part of the planning measures, one of Ghana Atomic Energy Commission’s primary functions is to provide technical support with a mechanism for timely, interagency coordination of advice and recommendations to NADMO concerning protective actions, environmental concerns, health matters and other related matters. It has been realized from this assessment that there is an urgent need to upgrade infrastructure with logistics for training, exercises and drills to achieve its optimum expectations which will eventually lead to high level of confidence in meeting the standard of a Radiation Protection Programme in Emergency Exposure Situations. (au)

  8. Laboratory operation during radiation emergency

    International Nuclear Information System (INIS)

    Bunata, M.; Prouza, Z.; Tecl, J.

    2009-01-01

    During radiation emergency, a special operation mode of laboratories of the Radiation Monitoring Network (hereinafter RMN) is expected. The principal factors differing the emergency mode from the normal one are the following: - significantly higher amount of analyzed samples; - high activities of the majority of the samples; - higher risk of personal and equipment contamination; - higher working and psychological demands on laboratory staff. The assuring of the radiation protection requirements of laboratory staff has to be the primary objective, nevertheless the risk of equipment contamination and of samples cross- contamination of course have to be as well taken into consideration. The presentation describes the experience of the RMN Central Laboratory of the National Radiation Protection Institute in Prague (SURO) which was obtained during realization of field tests, in which a radioactive matter was released. These tests allow us to evaluate the source term or radioactivity dispersal balance based on various detection methods with the aim to estimate exposure of the afflicted persons. Tests provided to simulate emergency working conditions in Central Laboratory - high number of contaminated samples, which have to be analyzed in a short time (short half-time of used radionuclide 99m Tc) using sophisticated laboratory techniques (gamma spectrometers, aerosols collectors, etc.). The testing shows the availability of the SURO laboratory to work during the radiation emergency and to participate on its determination. The suitable settings and the ideal number of staff have been found. The average analysis time was approximately 1 minute per sample and the sample results were available just a few minutes after the counting. Moreover, the settings avoided any danger and kept both the crew and the samples safe and secure from contamination. (authors)

  9. Laboratory operation during radiation emergency

    International Nuclear Information System (INIS)

    Bunata, M.; Tecl, J.; Prouza, Z.

    2008-01-01

    During radiation emergency, a special operation mode of laboratories of the Radiation Monitoring Network (hereinafter RMN) is expected. The principal factors differing the emergency mode from the normal one are the following: - significantly higher amount of analyzed samples; - high activities of the majority of the samples; - higher risk of personal and equipment contamination; - higher working and psychological demands on laboratory staff. The assuring of the radiation protection requirements of laboratory staff has to be the primary objective, nevertheless the risk of equipment contamination and of samples cross- contamination of course have to be as well taken into consideration. The presentation describes the experience of the RMN Central Laboratory of the National Radiation Protection Institute in Prague (SURO) which was obtained during realization of field tests, in which a radioactive matter was released. These tests allow us to evaluate the source term or radioactivity dispersal balance based on various detection methods with the aim to estimate exposure of the afflicted persons. Tests provided to simulate emergency working conditions in Central Laboratory -high number of contaminated samples, which have to be analyzed in a short time (short half-time of used radionuclide 99m Tc) using sophisticated laboratory techniques (gamma spectrometers, aerosols collectors, etc.). The testing shows the availability of the SURO laboratory to work during the radiation emergency and to participate on its determination. The suitable settings and the ideal number of staff have been found. The average analysis time was approximately 1 minute per sample and the sample results were available just a few minutes after the counting. Moreover, the settings avoided any danger and kept both the crew and the samples safe and secure from contamination. (authors)

  10. Dangerous goods emergency response

    International Nuclear Information System (INIS)

    Price, K.

    1991-01-01

    This paper reports on a general overview of the State of Western Australia including: the legal framework of the Dangerous Goods and Emergency response management scenarios (which consist mainly of fuel products such as LP gas); particular problems unique to the Western Australian environment; what has been done to overcome those problems. Western Australia has an area of about two and a half million square kilometers. The demography of the State is such that the population is concentrated in the south-west corner of the State with isolated pockets, mainly associated with mineral development but also associated with agriculture, scattered throughout the State

  11. Emergency Response Guideline Development

    International Nuclear Information System (INIS)

    Gary D Storrick

    2007-01-01

    Task 5 of the collaborative effort between ORNL, Brazil, and Westinghouse for the International Nuclear Energy Research Initiative entitled 'Development of Advanced Instrumentation and Control for an Integrated Primary System Reactor' focuses on operator control and protection system interaction, with particular emphasis on developing emergency response guidelines (ERGs). As in the earlier tasks, we will use the IRIS plant as a specific example of an integrated primary system reactor (IPSR) design. The present state of the IRIS plant design--specifically, the lack of a detailed secondary system design--precludes establishing detailed emergency procedures at this time. However, we can create a structure for their eventual development. This report summarizes our progress to date. Section 1.2 describes the scope of this effort. Section 2 compares IPSR ERG development to the recent AP1000 effort, and identifies three key plant differences that affect the ERGs and control room designs. The next three sections investigate these differences in more detail. Section 3 reviews the IRIS Safety-by-Design philosophy and its impact on the ERGs. Section 4 looks at differences between the IRIS and traditional loop PWR I and C Systems, and considers their implications for both control room design and ERG development. Section 5 examines the implications of having one operating staff control multiple reactor units. Section 6 provides sample IRIS emergency operating procedures (EOPs). Section 7 summarizes our conclusions

  12. Frequently Asked Questions about Radiation Emergencies

    Science.gov (United States)

    ... Frequently Asked Questions (FAQ) about Radiation Emergencies Language: English (US) Español (Spanish) Recommend on Facebook Tweet Share Compartir For more information on radiation, go to the Radiation Dictionary . Get Inside: Why should I get inside during ...

  13. Preparation and response to radiation and nuclear emergencies in case of natural disasters; Preparacion y respuesta a emergencias nucleares y radiologicas en caso de desastres naturales

    Energy Technology Data Exchange (ETDEWEB)

    Vegueria, Pablo Jerez, E-mail: pablo@orasen.co.cu [Centro Nacional de Seguridad Nuclear (CNSN), La Habana (Cuba); Lafortune, J.F., E-mail: padijeff@gmail.com [VP International Affairs, International Safety Research (Canada)

    2013-07-01

    The impact of natural disasters in cities and communities has grown by different causes in different parts of the world. There are several examples of the impact that have caused extreme natural events in facilities and activities in which ionizing radiation are used. The recent example of the accident at the nuclear power plant of Fukushima Daichi with release of radioactive substances to the environment caused by an earthquake and a tsunami show the need of the increasing improvement in the safety of facilities and activities that use ionizing radiation and radioactive materials in general. Planning and response to events of this nature is another aspect that is important and needs attention. The IAEA documents offer a comprehensive and effective guide to achieve an appropriate degree of readiness to respond to nuclear and radiological emergencies in any situation. However, there are specific challenges for planning and response posed a radiological emergency caused by an extreme natural event or occurring simultaneously with this. The present work deals with essential aspects to take into account by the authorities who coordinate the planning and response to radiological emergencies to deal with extreme natural events.

  14. Medical management of radiation emergencies

    International Nuclear Information System (INIS)

    Bongirwar, P.R.

    2002-01-01

    This review deals specifically with the medical management of victims, such as, the triage of exposed individuals on the basis of preliminary observations and investigations, planning priority of treatment to different groups, emergency care, and definitive care. The infrastructure for appropriate management involves first aid posts, decontamination centre, Site Hospital and Specialized Central Hospital. Medical management of life threatening radiation doses involve haematological examinations, blood component therapy, treatment with growth factors and if necessary, bone marrow transplantation as the last option. Most of the radiation accidents involving partial body and localized exposures are associated with industrial radiography sources. Such exposures are generally not life threatening but may involve serious skin injury, such as, ulceration, necrosis and gangrene. Methods have been developed to carry out decontamination of skin and decorporation of internally deposited radio nuclides. This article also provides information on the Radiation Emergency Medical Preparedness and Assistance Network and also outlines the role of media in reducing the human suffering in the event of an accident

  15. Nuclear emergency preparedness and response in Germany

    International Nuclear Information System (INIS)

    Miska, H.

    2009-01-01

    Off-site nuclear emergency response in Germany is divided into disaster response under the responsibility of the Laender and measures for precautionary radiation protection pursuant to the Precautionary Radiation Protection Act under the lead of federal authorities. Early countermeasures at the regional level require a different management than long-term and comprehensive actions of precautionary radiation protection. As situations may arise in which measures of both approaches overlap with regard to place and time, it is essential to make thorough preparations in order to avoid problems with implementation. (orig.)

  16. Emergency Response to Radioactive Material Transport Accidents

    International Nuclear Information System (INIS)

    EL-shinawy, R.M.K.

    2009-01-01

    Although transport regulations issued by IAEA is providing a high degree of safety during transport opertions,transport accidents involving packages containing radioactive material have occurred and will occur at any time. Whenever a transport accident involving radioactive material accurs, and many will pose no radiation safety problems, emergency respnose actioms are meeded to ensure that radiation safety is maintained. In case of transport accident that result in a significant relesae of radioactive material , loss of shielding or loss of criticality control , that consequences should be controlled or mitigated by proper emergency response actions safety guide, Emergency Response Plamming and Prepardness for transport accidents involving radioactive material, was published by IAEA. This guide reflected all requirememts of IAEA, regulations for safe transport of radioactive material this guide provide guidance to the publicauthorites and other interested organziation who are responsible for establishing such emergency arrangements

  17. Transport accident emergency response plan

    International Nuclear Information System (INIS)

    Vallette-Fontaine, M.; Frantz, P.

    1998-01-01

    To comply with the IAEA recommendations for the implementation of an Emergency Response Plan as described in Safety Series 87, Transnucleaire, a company deeply involved in the road and rail transports of the fuel cycle, masters means of Emergency Response in the event of a transport accident. This paper aims at analyzing the solutions adopted for the implementation of an Emergency Response Plan and the development of a technical support and adapted means for the recovery of heavy packagings. (authors)

  18. A system for radiation monitoring at the site for emergency planning and response in a nuclear station potentialities and prospects

    International Nuclear Information System (INIS)

    Novakov, V.; Moskovska, N.; Madzharov, M.; Angelov, V.

    1993-01-01

    The paper describes the existing system for radiation monitoring of the NPP region. The location of the devices puts a number of problems as maintenance of the radiometric equipment and urgent collecting and processing of the measuring data. Undeniably, to get an effective and timely decision, it is necessary to have on hand information as complete and prompt as possible, about the radiological situation in the regions, towns, villages and sites. As a result of daily observation and registration, an amount of enough in volume data could be accumulated. This data may be used as a base in case of a sudden change of the radiological situation and/or in case of arising of some local contaminations as a result of a volley type of emission, accidents at the nuclear power stations and releases fractions of radioactive and rare gases. The data obtained for a comparatively large region (about 700 square kilometers) with a high degree of gamma detectors distribution density are discussed. In the conditions of a progressively complicating radiological situation, they allow to determine the possible directions of the emission and also to undertake some response actions for protection of the population in time. (author)

  19. L-007: Objectives preparation and Emergency response

    International Nuclear Information System (INIS)

    2011-01-01

    This lecture explains the preparation and response in a nuclear and radiological emergency. Must be taken into consideration a program of preparedness, the public health and environment protection, propagation of contamination limit, first aid and treatment radiation damage, the stochastic, psychological and physical effects reduction

  20. The Brazilian emergency response system

    International Nuclear Information System (INIS)

    Santos, Raul dos

    1997-01-01

    With the objective of improving the response actions to potential or real emergency situations generated by radiological or nuclear accidents, the Brazilian National Nuclear Energy Commission (CNEN) installed an integrated response system on a 24 hours basis. All the natiowide notifications on events that may start an emergency situation are converged to this system. Established since July 1990, this system has received around 300 notifications in which 5% were classified as potential emergency situation. (author)

  1. Fire Department Emergency Response

    International Nuclear Information System (INIS)

    Blanchard, A.; Bell, K.; Kelly, J.; Hudson, J.

    1997-09-01

    In 1995 the SRS Fire Department published the initial Operations Basis Document (OBD). This document was one of the first of its kind in the DOE complex and was widely distributed and reviewed. This plan described a multi-mission Fire Department which provided fire, emergency medical, hazardous material spill, and technical rescue services

  2. Medical preparedness for radiation emergency in Japan

    International Nuclear Information System (INIS)

    Akashi, Makoto

    1997-01-01

    Medical preparedness for radiation emergency in Japan is primary for off-site public protection. Many things remains to be discussed about on-site emergency medical problems. On the other hand, each nuclear facility should have a countermeasure plan of radiation emergency including medical measures for the emergency. Disaster countermeasure act and a guideline from NSC entitled 'Off-site emergency planning and preparedness for nuclear power plants' establish the system for countermeasures in radiation emergencies. The guideline also establishes medical plans in radiation emergencies, including care system for the severely contaminated or injured. NIRS is designated by the guideline as the definite care hospital for radiation injuries and is prepared to dispatch medical specialists and to receive the injured. NIRS conducts clinical follow-up studies of the injured, researches of diagnosis and treatments for radiation injuries, and education and training for medical personnel. NIRS has the plans to serve as the reference center for emergency in Japan and also in Asia, if necessary. NIRS would like to serve as a member of WHO Collaborating Center for Radiation Emergency Medical Preparedness and Assistance (REMPAN). Now NIRS is making preparation for providing 24-hours direct or consultative assistance with medical problems associated with radiation accidents in local, national, and hopefully international incidents. (author)

  3. Evidence of children's vulnerability to radiation in the context of radiological/nuclear events and considerations for emergency response.

    Science.gov (United States)

    Lane, Rachel; Reinhardt, Pascale; Thompson, Patsy

    2010-11-01

    International organisations, such as International Atomic Energy Agency, United Nations Scientific Committee on the Effects of Atomic Radiation and World Health Organisation, together with committees of experts such as Biological Effects of Ionising Radiation and Committee on Medical Aspects of Radiation in the Environment, have assessed the effects of radiation on large exposed populations (Chernobyl accident, and Hiroshima/Nagasaki atomic bombings) and on nuclear energy workers and people living near nuclear facilities. Childhood and in utero exposure to moderate and high levels of ionizing radiation, such as those experienced during the atomic bombings of Japan, or from radiotherapy, is an established cause of leukaemia and solid cancer. There is no evidence of increase in solid cancers (excluding thyroid cancer) or leukaemia in the children from Chernobyl, and no evident link between worker's exposure to radiation and leukaemia in their offspring or with the presence of leukaemia clusters around nuclear power plants. It has also not been possible to demonstrate the evidence of radiation hereditary effects in human populations. In accordance with international guidance, Canadian Nuclear Safety Commission recommends optimisation of protection strategies to reduce doses to children. The development of credible radiological/nuclear event scenarios would assist in identifying probable sources of radioactivity and pathways of exposure for children. Such scenarios should then be used to identify protection strategies appropriate for children.

  4. Improvement Methods in NPP's Radiation Emergency Plan: An Administrative Approach

    International Nuclear Information System (INIS)

    Lee, Yoon Wook; Yang, He Sun

    2009-01-01

    The Radiation Emergency Plan (REP) can be divided into a technical and an administrative responses. The domestic NPP's REPs are reviewed from the viewpoint of the administrative response and improvement methods are also suggested in this treatise. The fields of the reviews are the composition of the emergency response organizations, the activation criteria of the organizations, the selection of the staffings and the reasonableness of the REP's volume. In addition, the limitations of the current radiation exercises are reviewed and the improvement method of the exercise is presented. It is expected that the suggested recommendations will be helpful in establishing useful REPs and making practical radiation exercises in Korea

  5. Southern states radiological emergency response laws and regulations

    International Nuclear Information System (INIS)

    1989-07-01

    The purpose of this report is to provide a summary of the emergency response laws and regulations in place in the various states within the southern region for use by legislators, emergency response planners, the general public and all persons concerned about the existing legal framework for emergency response. SSEB expects to periodically update the report as necessary. Radiation protection regulations without emergency response provisions are not included in the summary

  6. Radiation response of tumours

    International Nuclear Information System (INIS)

    Twentyman, P.R.

    1988-01-01

    In this chapter knowledge regarding cellular radiation response and the factors which modify it is related to the volume changes and probability of control of irradiated solid tumors. After a discussion of the different cell populations present within solid tumors the cell population kinetics of the neoplastic cells are considered in more detail. The influence of factors related to the three-dimensional geometry of the tumor, particularly hypoxia, are considered, and also the role of the tumor vasculature in radiation response. Repair of sublethal damage (SLD) and potentially lethal damage (PLD) is dealt with and finally the relationship between the various end-points of tumor radioresponsiveness is discussed

  7. NOAA Emergency Response Imagery

    Data.gov (United States)

    National Oceanic and Atmospheric Administration, Department of Commerce — The imagery posted on this site is in response to natural disasters. The aerial photography missions were conducted by the NOAA Remote Sensing Division. The majority...

  8. Radiation Emergency Preparedness Tools: Psychological First Aid

    Centers for Disease Control (CDC) Podcasts

    This podcast is an overview of the Clinician Outreach and Communication Activity (COCA) Call: Practical Tools for Radiation Emergency Preparedness. A specialist working with CDC's Radiation Studies Branch describes Psychological First Aid and a newly developed multimedia training program, entitled "Psychological First Aid in Radiation Disasters."

  9. SICOEM: emergency response data system

    International Nuclear Information System (INIS)

    Martin, A.; Villota, C.; Francia, L.

    1993-01-01

    The main characteristics of the SICOEM emergency response system are: -direct electronic redundant transmission of certain operational parameters and plant status informations from the plant process computer to a computer at the Regulatory Body site, - the system will be used in emergency situations, -SICOEM is not considered as a safety class system. 1 fig

  10. SICOEM: emergency response data system

    Energy Technology Data Exchange (ETDEWEB)

    Martin, A.; Villota, C.; Francia, L. (UNESA, Madrid (Spain))

    1993-01-01

    The main characteristics of the SICOEM emergency response system are: -direct electronic redundant transmission of certain operational parameters and plant status informations from the plant process computer to a computer at the Regulatory Body site, - the system will be used in emergency situations, -SICOEM is not considered as a safety class system. 1 fig.

  11. First Response to Medical Emergency

    International Nuclear Information System (INIS)

    Manisah Saedon; Sarimah Mahat; Muhamad Nurfalah Karoji; Hasnul Nizam Osman

    2015-01-01

    Accident or medical emergencies, both minor and critical, occurs each day and can happen in any workplace. In any medical emergencies, time is a critical factor because the first person to arrive at the scene of an accident has a key role in the rescue of a victim. With the knowledge of some common medical procedures and emergency actions, this first responder can make a positive contribution to the welfare of the accident victim. In some cases, this contribution can make difference between life and death. Improper response to medical emergencies by an untrained person can result in worsen injuries or death. Therefore, first aids training are necessary to provide the information. (author)

  12. Mobile emergency response unit

    International Nuclear Information System (INIS)

    Kadi, W.J.; Trolan, R.T.; Becker, J.F.

    1979-01-01

    The Hotspot quick-response unit was the solution to a requirement to find, identify, and control areas of radioactive contamination at the scene of a nuclear weapons accident. The unit consists of two trucks and two trailers, and is designed to be transported by one U.S. Air Force C-141. One truck (generator truck) carries a 40 kW generator-heater-air conditioner combination, spare tires, and accessories. The other (water truck) carries supplies and a 250-gal water tank. One trailer (counting trailer) contains detecting, counting, and recording equipment. The other (decontaminating trailer) contains a shower, sink, 30-gal hot water tank, and supplies

  13. Medical management and planning for radiation emergencies

    International Nuclear Information System (INIS)

    Bongirwar, P.R.

    2001-01-01

    Radiation Emergencies which result as a consequence of nuclear or radiological accidents can produce a spectrum of different types of radiation injuries which could include cases of whole body irradiation causing Acute Radiation Syndrome, partial body irradiation, radiation burns (localized irradiation), radioactive contamination and combined injuries having component of conventional injuries. General principles of managing these cases entail doing triage, offering immediate emergency care and instituting definitive treatment. Infra-structural facilities which are required to facilitate their management include first aid post at plant site, personnel decontamination centre, site clinic and specialized hospital which can offer comprehensive investigational and treatment modalities. Training of medical and paramedical personnel is crucial as part of emergency preparedness programme and if needed, help can be sought from WHO's Radiation Emergency Medical Preparedness and Assistance Network Centres. (author)

  14. Emergency Preparedness and Response: A Safety Net

    Energy Technology Data Exchange (ETDEWEB)

    Aaltonen, H., E-mail: hannele.aaltonen@stuk.fi [Radiation and Nuclear Safety Authority (STUK), Helsinki (Finland)

    2014-10-15

    Full text: The objective of nuclear regulatory work is to prevent accidents. Nevertheless, possibility of a severe accident cannot be totally excluded, which makes a safety net, efficient emergency preparedness and response, necessary. Should the possibility of accidents be rejected, the result would be in the worst case inadequate protection of population, functions of society, and environment from harmful effects of radiation. Adequate resources for maintenance and development of emergency arrangement are crucial. However, they need to be balanced taking into account risks assessments, justified expectations of society, and international requirements. To successfully respond to an emergency, effective emergency preparedness, such as up-to-date plans and procedures, robust arrangements and knowledgeable and regularly trained staff are required. These, however, are not enough without willingness and proactive attitude to • communicate in a timely manner; • co-operate and coordinate actions; • provide and receive assistance; and • evaluate and improve emergency arrangements. In the establishment and development of emergency arrangements, redundant and diverse means or tools used are needed in, for example, communication and assessment of hazard. Any severe nuclear emergency would affect all countries either directly or indirectly. Thus, national emergency arrangements have to be compatible to the extent practicable with international emergency arrangements. It is important to all countries that the safety nets of emergency arrangements are reliable - and operate efficiently in a coordinated manner when needed - on national, regional and international level. (author)

  15. Advising the public about radiation emergences. NCRP Commentary No. 10

    International Nuclear Information System (INIS)

    1994-01-01

    Technologies that use or produce radiation or radioactive materials, like many other complex technologies, have the inherent potential to cause emergency situations in which public safety may be jeopardized. Professionals engaged with such technologies are trained to minimize risk and potential harm, even in emergencies, but there can be no question that emergencies are public events and that, as such, the public must be informed. The degree of the public's involvement in an emergency will, of course, depend on the type and scale of the event but the need for information is present in all cases. This Commentary reviews salient features involved in the provision of information to the public relating to radiation emergencies. Section 2 outlines sources of information available to the public for a broad understanding of technology and science in general, and radiation matters in particular. Section 3 addresses the vital matter of credibility. In Section 4, matters of perception and their influence on the usability of information are assessed. Section 5 directs attention to the role of information sources during the emergency itself. Section 6 presents a survey of the types of information that can prove helpful to the public in connection with a radiation emergency and exhibits a proposed index for helping people comprehend the magnitude of radiation levels and their impacts. Means for improving the dissemination of information and the public's capacity to use it are outlined in Section 7. Finally, appendices provide information about emergency response organizations and additional information about the proposed radiation index

  16. Radiation emergency medical preparedness and assistance network in China

    International Nuclear Information System (INIS)

    Su, Xu

    2008-01-01

    Full text: Rapid economic growth in demand has given rise to power shortage in China. The installed capacity of nuclear power has been scheduled to reach 36-40 GW in preliminary plans, which is about 4% of China's energy supply by 2020. On the other hand, the number of radiation facilities rises 7% annually, while this figure for medical accelerators and CT is 15%. With the application of radiation sources increasing, the possibility of accidents exposure is growing. The radiation emergency medical preparedness is increasingly practically challenging. CCMRRE (Chinese Center for Medical Response to Radiation Emergency), which functions as a national and professional institute with departments for clinic, monitoring and evaluating and technical supporting, was established in 1992. Clinic departments of haematological and surgical centres, and specialists in the radiation diagnosis and therapy, is responsible for the medical assistance in radiation accidents. The monitoring and evaluating department with bio-dosimetry, physical dosimetry and radiation monitoring laboratory, concentrates in radiation monitoring, dose estimating of accident exposure. Technical support department with advisors and experts in exposure dose estimating, radiation protecting and injury treating, provides technical instruction in case of nuclear and radiological accidents. In addition, around whole country, local organization providing first assistance, regional clinic treatment and radiation protection in nuclear accidents has been established. To strengthen the capability of radiation emergency medical response and to improve the cooperation with local organization, the managers and involved staffs were trained in skill frequently. The medical preparedness exercise, which mimics the nuclear accidents condition, was organized by CCMRRE and performed in 2007. The performances demonstrated that the radiation emergency medical preparedness and assistance system is prompt, functional and

  17. Institutional planning for radiation emergencies

    International Nuclear Information System (INIS)

    Keil, E.R.

    1986-01-01

    Persons providing health care pride themselves on their ability to handle emergencies. This pride is born of the daily experience of caring for the sick and injured. Emergencies include traumatic injuries, sudden changes in health status, and various minor disturbances in the physical environment inside the hospital. The effectiveness of this ability is unquestioned in limited-scale problems. However, survey experience of the Joint Commission on the Accreditation of Hospitals (JCAH) reveals weaknesses when health care organizations are faced with larger scale problems such as earthquakes and plane crashes. One may speculate that a massive emergency such as occurred at Chernobyl would overwhelm this ability. Based on the same survey experience, JCAH believes that health care organizations can plan and train to prepare for large-scale emergencies in a careful and systematic manner. Through such study and practice, their existing confidence and ability to deal with limited emergencies can be explained

  18. System for radiation emergency medicine. Activities of tertiary radiation emergency hospitals

    International Nuclear Information System (INIS)

    Kamiya, Kenji; Tanigawa, Koichi; Hosoi, Yoshio

    2011-01-01

    Japanese system for radiation emergency medicine is primarily built up by Cabinet Nuclear Safety Commission in 2001 based on previous Tokai JCO Accident (1999) and is composed from the primary, secondary and tertiary medical organizations. This paper describes mainly about roles and actions of the tertiary facilities at Fukushima Nuclear Power Plant Accident and tasks to be improved in future. The primary and secondary organizations in the system above are set up in the prefectures with or neighboring the nuclear facility, and tertiary ones, in two parts of western and eastern Japan. The western organization is in Hiroshima University having its cooperating 7 hospitals, and is responsible for such patients as exposed to high dose external radiation, having serious complication, and difficult to treat in the primary/secondary hospitals. The eastern is in National Institute of Radiological Sciences (NIRS) with 6 cooperating hospitals and responsible for patients with internal radiation exposure difficult to treat, with contaminated body surface with difficulty in decontamination and/or with causable of secondary contamination, and difficult to treat in the secondary hospitals. The tertiary organizations have made efforts for the education and training of medical staff, for network construction among the primary, secondary and other medicare facilities, for establishment of transferring system of patients, and for participation to the international network by global organizations like Response Assistance Network (RANET) in International Atomic Energy Agency (IAEA), and Radiation Emergency Preparedness and Network (REMPAN) in World Health Organization (WHO). At the Fukushima Accident, staffs of the two tertiary hospitals began to conduct medicare on site (Mar. 12-) and learned following tasks to be improved in future: the early definition of medicare and its network system, and Emergency Planning Zone (EPZ); urgent evacuation of residents weak to disaster like elderly

  19. Lessons Learned from the Response to Radiation Emergencies (1945-2010) (Spanish Edition); Enseñanzas extraídas de la respuesta a emergencias radiológicas

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2014-07-15

    An underlying concept in the safety standards of the International Atomic Energy Agency (IAEA) is that prevention is better than cure. This is achieved through the … application of appropriate standards in design and operation. Nevertheless, radiation incidents and emergencies do occur and safety standards are necessary that define the approaches to be used in mitigating the consequences. The IAEA Safety Requirements publication, Preparedness and Response for a Nuclear or Radiological Emergency, GS-R-2, establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. They take account of several other Safety Standards at the Safety Requirements level, namely: the International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources (BSS); Governmental, Legal and Regulatory Framework for Safety, GSR Part 1; Safety of Nuclear Power Plants: Design, NS-R-1; and Safety of Nuclear Power Plants: Operation, NS-R-2. Implementation of the requirements is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. Although developed before the publication of the Fundamental Safety Principles, they define the requirements that must be satisfied in order to achieve the overall objective and apply the principles that are presented in publications relating to emergencies. An emergency is defined in the Agency's glossary as 'a non-routine situation or event that necessitates prompt action, primarily to mitigate a hazard or adverse consequences for human health and safety, quality of life, property or the environment. This includes nuclear and radiological emergencies and conventional emergencies such as fires, release of hazardous chemicals, storms or earthquakes. It includes situations for which prompt action is warranted to mitigate the effects of a perceived hazard'. Several nuclear emergencies have

  20. Emergency handling of radiation accident cases: firemen

    International Nuclear Information System (INIS)

    Procedures for the emergency handling of persons exposed to radiation or radioactive contamination are presented, with emphasis on information needed by firemen. The types of radiation accident patients that may be encountered are described and procedures for first aid, for preventing the spread of radioactive contamination, and for reporting the accident are outlined

  1. Mutual emergency assistance for radiation accidents

    International Nuclear Information System (INIS)

    1971-01-01

    This document presents the result of a questionnaire survey conducted in order to assess what type of emergency assistance IAEA member states could provide in the event of radiation accidents. The survey covers resources like skilled personnel in collection, analysis and interpretation of data, surveying and radiation protection equipment, radiochemical analysis facilities, and medical assistance capacities

  2. Emerging frontiers in radiation biology

    International Nuclear Information System (INIS)

    Singh, B.B.

    1996-01-01

    Radiation biology owes its origin to the spectacular success in the treatment of human diseases by x-rays and radium, just after their respective discoveries in 1895-96. From the very inception it has attracted researchers from all disciplines of science. The target and hit theory developed by physicists, dominated the scene till the advent of radiation chemistry concepts which offered an entirely different perspective to the mechanisms involved in biological effects of radiations and their modification by endogenous and exogenous agents like radioprotectors and radiosensitisers including hyperthermia. The applied aspect of radiation biology mainly relates to radiation therapy of cancer which, in spite of its long existence, is still to achieve scientific perfection. Nevertheless, it did not wait -and fortunately so-, for its radiobiological rationality but continued its development to be the main modality for cancer treatment today. Several approaches are now being attempted to improve its efficacy by selectively damaging the cancerous cells while sparing the normal tissues and also by devising suitable predictive assays for radioresponse of different tumours to enable individualisation of treatment schedules. (author). 99 refs., 1 fig., 2 tabs

  3. Hazardous Materials Management and Emergency Response (HAMMER)

    Data.gov (United States)

    Federal Laboratory Consortium — The Volpentest Hazardous Materials Management and Emergency Response (HAMMER) Federal Training Center is a safety and emergency response training center that offers...

  4. Radiation Emergency Preparedness Tools: Virtual Community Reception Center

    Centers for Disease Control (CDC) Podcasts

    2011-02-28

    This podcast is an overview of resources from the Clinician Outreach and Communication Activity (COCA) Call: Practical Tools for Radiation Emergency Preparedness. A specialist working with CDC's Radiation Studies Branch describes a web-based training tool known as a Virtual Community Reception Center (vCRC).  Created: 2/28/2011 by National Center for Environmental Health (NCEH) Radiation Studies Branch and Emergency Risk Communication Branch (ERCB)/Joint Information Center (JIC); Office of Public Health Preparedness and Response (OPHPR).   Date Released: 2/28/2011.

  5. Emergency response planning in Saskatchewan

    International Nuclear Information System (INIS)

    Irwin, R.W.

    1998-01-01

    Release reporting and spill clean-up requirements by Saskatchewan Energy and Mines were reviewed. Wascana's experience in response planning was discussed. It was suggested that the key to prevention was up-front due diligence, including facility and oil well analysis. Details of Wascana's emergency plan, and details of Saskatchewan Energy and Mines release reporting procedures were also provided

  6. Generic procedures for medical response during a nuclear or radiological emergency. Emergency preparedness and response

    International Nuclear Information System (INIS)

    2005-04-01

    The aim of this publication is to serve as a practical resource for planning the medical response to a nuclear or radiological emergency. It fulfils in part functions assigned to the IAEA under Article 5.a(ii) of the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), namely, to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and available results of research relating to such emergencies. Effective medical response is a necessary component of the overall response to nuclear or radiological (radiation) emergencies. In general, the medical response may represent a difficult challenge for the authorities due to the complexity of the situation, often requiring specialized expertise, and special organizational arrangements and materials. To be effective, adequate planning and preparedness are needed. This manual, if implemented, should help to contribute to coherent international response. The manual provides the practical tools and generic procedures for use by emergency medical personnel during an emergency situation. It also provides guidance to be used at the stage of preparedness for development of medical response capabilities. The manual also addresses mass casualty emergencies resulting from malicious acts involving radioactive material. This part was supported by the Nuclear Security Fund. The manual was developed based on a number of assumptions about national and local capabilities. Therefore, it must be reviewed and revised as part of the planning process to match the potential accidents, threats, local conditions and other unique characteristics of the facility where it may be used

  7. International conference on non-military radiation emergencies: [Final technical report

    International Nuclear Information System (INIS)

    1986-01-01

    The subject of this report was limited to non-military radiation emergencies because such events needed to be addressed and the topic was considered to be manageable. The Conference theme developed around the lessons learned from the radiation emergencies at Chernobyl, Three Mile Island, and Windscale. Specific topics to be considered included acute and long-term effects of radiation exposure; frequency and nature of radiation emergencies; national standards for exposures to ionizing radiation; plans and procedures for responding to emergencies at the hospital, community, and national levels; and responsibilities of physicians and other health professionals regarding radiation exposures and emergencies

  8. Emergency response planning in Pennsylvania

    International Nuclear Information System (INIS)

    Reilly, M.A.

    1988-01-01

    In the decade since the accident at Three Mile Island, emergency planning for response to these events has undergone a significant change in Pennsylvania, as elsewhere. Changes respond to federal guidance and to state agency initiatives. The most singular change is the practice of implementing a protective action throughout the entire emergency planning zone (EPZ). Due to Pennsylvania agency experiences during the accident, the decision was made soon after to develop a staff of nuclear engineers, each giving special day-to-day attention to a specific nuclear power station in the state. Changes in communications capabilities are significant, these being dedicated phone lines between the Commonwealth and each power station, and the reorientation of the Department of Environmental Resources radio network to accommodate direction of field monitoring teams from Harrisburg. Changes that are being or will be implemented in the near future include assessing the emergency response data system for electronic delivery of plant parameter data form facilities during accidents, increased participation in exercises, emergency medical planning, and training, the inclusion of all 67 counties in Pennsylvania in an ingestion EPZ, and the gradual severance of dependence on land-line emergency communication systems

  9. Towards accurate emergency response behavior

    International Nuclear Information System (INIS)

    Sargent, T.O.

    1981-01-01

    Nuclear reactor operator emergency response behavior has persisted as a training problem through lack of information. The industry needs an accurate definition of operator behavior in adverse stress conditions, and training methods which will produce the desired behavior. Newly assembled information from fifty years of research into human behavior in both high and low stress provides a more accurate definition of appropriate operator response, and supports training methods which will produce the needed control room behavior. The research indicates that operator response in emergencies is divided into two modes, conditioned behavior and knowledge based behavior. Methods which assure accurate conditioned behavior, and provide for the recovery of knowledge based behavior, are described in detail

  10. Southern states radiological emergency response laws and regulations

    International Nuclear Information System (INIS)

    1990-06-01

    The purpose of this report is to provide a summary of the emergency response laws and regulations in place in the various states within the southern region for use by legislators, emergency response planners, the general public and all persons concerned about the existing legal framework for emergency response. SSEB expects to periodically update the report as necessary. Radiation protection regulations without emergency response provisions are not included in the summary. The radiological emergency response laws and regulations of the Southern States Energy Compact member states are in some cases disparate. Several states have very specific laws on radiological emergency response while in others, the statutory law mentions only emergency response to ''natural disasters.'' Some states have adopted extensive regulations on the topic, others have none. For this reason, any general overview must necessarily discuss laws and regulations in general terms. State-by-state breakdowns are given for specific states

  11. Multidisciplinary collaboration for meeting radiation emergencies

    International Nuclear Information System (INIS)

    Jankowski, C.B.

    1986-01-01

    Radiation emergencies preparedness depend on the participation of many kinds of professionals in a concerted effort to meet whatever unforeseen situation may arise. This is true even for an injury involving only a single individual, the most common kind of radiation emergency. Each local hospital supporting a nuclear power facility performs at least one medical drill annually to review its ability to manage radiation casualties. Admitting even one injured and contaminated plant employee to the emergency room requires the involvement of many hospital departments, including the nursing, medical, security, housekeeping, radiology, clinical laboratories, and administration groups. The triage of several injured victims to regional hospitals would demand even more personnel and coordination of their efforts. In an extreme situation, the need for health care personnel could be enormous. Planning for large-scale radiation emergencies should involve physicians, but there must also be advice from and coordination with nurses, health physicists, emergency management specialists, emergency medical technicians, and state and local police and fire officials

  12. Mutual emergency assistance for radiation accidents

    International Nuclear Information System (INIS)

    1983-03-01

    A revised document on ''Mutual Emergency Assistance for Radiation Accidents'' jointly prepared by the Agency with the participation of the World Health Organization (WHO), the Food and Agricultural Organization of the United Nations (FAO), the International Labour Organisation (ILO) and the Office of the United Nations Disaster Relief Co-ordinator (UNDRO) was issued in 1980 as TECDOC-237. The present document lists the additional information received after publication of the 1980 edition and is issued as a Supplement to TECDOC-237 (1980 Edition). Some useful information contained in TECDOC-237 such as the IAEA arrangement and the WHO Collaborating Centres for Radiation Emergency Assistance are reprinted for ready reference

  13. Manual on public health action in radiation emergencies

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    1994-12-31

    Over the years, the World Health Organization (WHO) has issued a series of reports and publications providing guidance on the public health aspects of nuclear power production, in line with target 11 of the European policy for health for all, which calls for the reduction of injury, disability and death from accidents. Immediately after the nuclear accident at Chernobyl in April 1986, the WHO Regional Office for Europe established an emergency operation to provide technical cooperation and communication links with Member States. A special project on the public health dimensions of radiation emergencies was subsequently established, which included a series of activities related both directly to the Chernobyl accident and to emergency planning for future accidents. This manual brings together the experience gained in the special project to improve the planning for and response to emergencies. It has been prepared to meet public health needs arising from all types of major radiation emergency in the European Region. The manual describes the guiding principles and advises on the practical application of measures to protect and inform the public in a radiation emergency. It is hoped that the manual will promote close interaction between the WHO Member States in this field. The advice given in earlier WHO publications on radiation emergencies has been examined and revised in the light of recent experience 12 refs, 4 figs, 4 tabs

  14. Manual on public health action in radiation emergencies

    International Nuclear Information System (INIS)

    1994-01-01

    Over the years, the World Health Organization (WHO) has issued a series of reports and publications providing guidance on the public health aspects of nuclear power production, in line with target 11 of the European policy for health for all, which calls for the reduction of injury, disability and death from accidents. Immediately after the nuclear accident at Chernobyl in April 1986, the WHO Regional Office for Europe established an emergency operation to provide technical cooperation and communication links with Member States. A special project on the public health dimensions of radiation emergencies was subsequently established, which included a series of activities related both directly to the Chernobyl accident and to emergency planning for future accidents. This manual brings together the experience gained in the special project to improve the planning for and response to emergencies. It has been prepared to meet public health needs arising from all types of major radiation emergency in the European Region. The manual describes the guiding principles and advises on the practical application of measures to protect and inform the public in a radiation emergency. It is hoped that the manual will promote close interaction between the WHO Member States in this field. The advice given in earlier WHO publications on radiation emergencies has been examined and revised in the light of recent experience

  15. EMERGENCY RADIATION SURVEY DEVICE ONBOARD THE UAV

    Directory of Open Access Journals (Sweden)

    S. Bogatov

    2013-08-01

    Full Text Available Radiation survey device (RSD on the base of unmanned aerial vehicle (UAV was developed as an equipment of rescue forces for radiation situation reconnaissance in case of emergency. RSD is multi range radiometer with spectrometer functions capable to work within gamma ray fields of dose rate 10–7 – 10–1 Sievert per hour. UAV md4-1000 (Microdrones GmbH, Germany was selected as the RSD carrier as a reliable vehicle with appropriate properties. Short description of RSD, UAV and developed software features as well as sensitivity assessments for different radiation sources are presented.

  16. Effective nuclear and radiation emergency planning

    International Nuclear Information System (INIS)

    Grlicarev, I.

    2000-01-01

    The paper describes how to develop a balanced emergency plan, which realistically reflect the interfaces with various emergency organizations. The use of resources should be optimized with focusing on the most likely accidents. The pitfalls of writing an emergency plan without ''big picture'' in mind should be avoided. It is absolutely essential to have a clear definition of responsibilities and to have proper understanding of the tasks in between all counterparts in the emergency preparedness. Special attention should be paid to off-site part of the nuclear emergency preparedness, because the people involved in it usually receive less training than the on-site personnel and they are not specialized for nuclear emergencies but deal with all sorts of emergencies. (author)

  17. Local emergency arrangements for radiation accidents

    International Nuclear Information System (INIS)

    Jones, A.

    1989-01-01

    This paper describes the local and national framework for public protection during peacetime emergencies with particular reference to major accidents or events with radiological consequences. The basis for the development of emergency plans will be described together with the inter-relationship between the responsibilities of individual organisations. (author)

  18. Radiological emergency: road map for radiation accident victim transport

    International Nuclear Information System (INIS)

    Costa, V.S.G.; Alcantara, Y.P.; Lima, C.M.A.; Silva, F. C. A. da

    2017-01-01

    During a radiological or nuclear emergency, a number of necessary actions are taken, both within the radiation protection of individuals and the environment, involving many institutions and highly specialized personnel. Among them it is possible to emphasize the air transportation of radiation accident victims.The procedures and measures for the safe transport of these radiation accident victims are generally the responsibility of the armed forces, specifically the Aeronautics, with the action denominated 'Aeromedical Military Evacuation of Radiation Accident Victims'. The experience with the Radiological Accident of Goiânia demonstrated the importance of adequate preparation and response during a radiological emergency and the need for procedures and measures with regard to the transport of radiation victims are clearly defined and clearly presented for the effectiveness of the actions. This work presents the necessary actions for the transport of radiation accident victim during a radiological emergency, through the road map technique, which has been widely used in scientific technical area to facilitate understanding and show the way to be followed to reach the proposed objectives

  19. Responses to emergencies in Mexico and Central America

    International Nuclear Information System (INIS)

    Diaz, E.F.

    1986-01-01

    Radiation emergencies have two main aspects: radiation safety, which concerns control of the radiation source, and, more importantly, health effects, which entail diagnoses, treatment, and rehabilitation. The physician participates directly in a radiation emergency because he or she is the professional who knows best the human body and the methodology to re-establish health. However, because these types of incidents are infrequent, many physicians are poorly prepared to deal with such emergencies. Two main aspects of emergency response plans are: (1) prevention, including public education for behavior and planning for appropriate response; and (2) application, including prophylactic measures, assessing the extent of exposure and contamination, controlling public anxiety, and managing and treating the victims

  20. Automated emergency meteorological response system

    International Nuclear Information System (INIS)

    Pepper, D.W.

    1980-01-01

    A sophisticated emergency response system was developed to aid in the evaluation of accidental releases of hazardous materials from the Savannah River Plant to the environment. A minicomputer system collects and archives data from both onsite meteorological towers and the National Weather Service. In the event of an accidental release, the computer rapidly calculates the trajectory and dispersion of pollutants in the atmosphere. Computer codes have been developed which provide a graphic display of predicted concentration profiles downwind from the source, as functions of time and distance

  1. Radiation technology in emerging industrial applications. Proceedings

    International Nuclear Information System (INIS)

    2003-01-01

    In many industrial applications radiation processing has proven to be a technology of choice either because of its economic competitiveness or its technical superiority. Although the chemical effects of ionizing radiation have been known for more than a century, its industrial applications became possible only after the availability of reliable gamma sources and powerful electron accelerators during the last couple of decades.The programmes of the International Atomic Energy Agency (IAEA) in radiation processing are implemented through the Department of Nuclear Sciences and Applications and the Department of Technical Co-operation. The IAEA has been active in this field for many years, contributing to new developments, training, promotion and transfer of technology. In September 1997, the IAEA held an international symposium in Zakopane, Poland on the 'Use of radiation technology for the conservation of environment' where the status of current developments and of applications of radiation processing in the control of environmental pollution was reviewed (IAEA-TECDOC-1023, 1998). Recent developments and achievements in various aspects of radiation processing have been assessed continuously through the organization of consultants meetings, advisory group meetings and research co-ordination meetings. Worldwide growing interest in the use of radiation technology in various new industrial applications, as exemplified by the reports and presentations made at these meetings, has led the IAEA to organize a symposium to cover every aspect of radiation processing and, exclusively, the emerging industrial applications of radiation technology. The International Symposium on Radiation Technology in Emerging Industrial Applications was convened in November 2000 in Beijing, China. Its main purpose was to bring scientists,technologists, industrialists and regulatory authorities together with a view of exchanging information and reviewing the status of current developments and

  2. Radiation technology in emerging industrial applications. Proceedings

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2003-09-01

    In many industrial applications radiation processing has proven to be a technology of choice either because of its economic competitiveness or its technical superiority. Although the chemical effects of ionizing radiation have been known for more than a century, its industrial applications became possible only after the availability of reliable gamma sources and powerful electron accelerators during the last couple of decades.The programmes of the International Atomic Energy Agency (IAEA) in radiation processing are implemented through the Department of Nuclear Sciences and Applications and the Department of Technical Co-operation. The IAEA has been active in this field for many years, contributing to new developments, training, promotion and transfer of technology. In September 1997, the IAEA held an international symposium in Zakopane, Poland on the 'Use of radiation technology for the conservation of environment' where the status of current developments and of applications of radiation processing in the control of environmental pollution was reviewed (IAEA-TECDOC-1023, 1998). Recent developments and achievements in various aspects of radiation processing have been assessed continuously through the organization of consultants meetings, advisory group meetings and research co-ordination meetings. Worldwide growing interest in the use of radiation technology in various new industrial applications, as exemplified by the reports and presentations made at these meetings, has led the IAEA to organize a symposium to cover every aspect of radiation processing and, exclusively, the emerging industrial applications of radiation technology. The International Symposium on Radiation Technology in Emerging Industrial Applications was convened in November 2000 in Beijing, China. Its main purpose was to bring scientists,technologists, industrialists and regulatory authorities together with a view of exchanging information and reviewing the status of current developments and

  3. Human Response to Emergency Warning

    Science.gov (United States)

    Sorensen, J.

    2009-12-01

    Almost every day people evacuate from their homes, businesses or other sites, even ships, in response to actual or predicted threats or hazards. Evacuation is the primary protective action utilized in large-scale emergencies such as hurricanes, floods, tornados, tsunamis, volcanic eruptions, or wildfires. Although often precautionary, protecting human lives by temporally relocating populations before or during times of threat remains a major emergency management strategy. One of the most formidable challenges facing emergency officials is evacuating residents for a fast-moving and largely unpredictable event such as a wildfire or a local tsunami. How to issue effective warnings to those at risk in time for residents to take appropriate action is an on-going problem. To do so, some communities have instituted advanced communications systems that include reverse telephone call-down systems or other alerting systems to notify at-risk residents of imminent threats. This presentation examines the effectiveness of using reverse telephone call-down systems for warning San Diego residents of wildfires in the October of 2007. This is the first systematic study conducted on this topic and is based on interviews with 1200 households in the evacuation areas.

  4. A Tactical Emergency Response Management System (Terms ...

    African Journals Online (AJOL)

    2013-03-01

    Mar 1, 2013 ... information is a result of collaboration between accident response personnel. ... Tactical Emergency Response Management System (TERMS) which unifies all these different ... purpose of handling crisis and emergency.

  5. Emergency room management of radiation accidents

    International Nuclear Information System (INIS)

    Rosenberg, R.; Mettler, F.A. Jr.

    1990-01-01

    Emergency room management of radioactively contaminated patients who have an associated medical injury requiring immediate attention must be handled with care. Radioactive contamination of the skin of a worker is not a medical emergency and is usually dealt with at the plant. Effective preplanning and on-the-scene triage will allow the seriously injured and contaminated patients to get the medical care they need with a minimum of confusion and interference. Immediate medical and surgical priorities always take precedence over radiation injuries and radioactive contamination. Probably the most difficult aspect of emergency management is the rarity of such accidents and hence the unfamiliarity of the medical staff with the appropriate procedures. The authors discuss how the answer to these problems is preplanning, having a simple and workable procedure and finally having 24-h access to experts

  6. Coordinating International Response to Emergencies

    International Nuclear Information System (INIS)

    Bice, S. D.

    2007-01-01

    Pandemic disease, natural disasters and terrorism can affect thousands of people in a relatively short period of time anywhere in the world. Our recent international experience with hurricanes, earthquakes, tsunamis and infectious diseases (AIDS, TB and highly pathogenic avian influenza) show us that we must respond with a coordinated approach or we will fail the very people we intend to help. Nations from around the world are often eager to send assistance to the site of a disaster, but coordinating the incoming aid is more often flawed and imprecise than it must be in order to save lives and mitigate suffering. How can any one country, suffering from a horrendous calamity coordinate the incoming aid from around the world? Can any one agency hope to coordinate the myriad nation's response let alone that of the hundreds of non-governmental organizations? Currently, the answer is sadly, no. The purpose of this presentation is not to recommend one over the many international bodies which claim to oversee humanitarian assistance; the purpose of this presentation is to discuss the elements of only one aspect of the overall response effort: public health and medical response coordination. Public health response is of course different than a purely medical response. Traditionally, in a natural disaster, immediate public health concerns center around water, sewerage/waste disposal, potential for disease outbreaks, etc, whereas medical response concentrates on triage, saving those who can be saved, patching up the injured, and to a lesser extent, primary care to the survivors. In order to avoid political controversy, this presentation will use the example of Hurricane Iniki in Hawaii, September 1992, to illustrate key concepts. The State of Hawaii is no stranger to natural disasters. Their emergency response mechanisms are well honed, exercised and quite capable. However, the local community leaders on Kauai Island went thru each of the following phases before they

  7. Mutual emergency assistance for radiation accidents

    International Nuclear Information System (INIS)

    1980-11-01

    In 1963 the International Atomic Energy Agency (IAEA) issued a document, WP.35, dated 23 November 1963, based on information provided by a number of its Member States on the type of radiological assistance that they might be able to make available in the event of a radiation emergency in another country at the request of that country. The document was subsequently revised in 1968 and 1971 with the participation of the World Health Organization (WHO), the Food and Agriculture Organization of the United Nations (FAO) and the International Labour Organisation (ILO). In 1979, an expanded questionnaire to ascertain what could be required by the State in the event of a major radiation accident, was sent jointly by these organizations with the participation of the Office of the United Nations Disaster Relief Co-ordinator (UNDRO), to all their Member States. The text of the expanded questionnaire is reproduced. The present document lists all the information, received up to mid 1980, that contains offers of assistance made by a State. It also lists information on the assistance that might be required by the State. In general, the replies have been reproduced in the form in which they were received, although a few changes in presentation have been introduced in the interest of brevity and clarity. Some countries have pointed out that their replies are necessarily of a general character and that the full extent of the assistance they would be capable of providing could be determined only after a specific request had been received. The information given in this document should therefore be regarded only as a guide to the type of radiological assistance that might be available and/or needed. Other available international assistance includes that provided by the Agency through the IAEA Radiation (Emergency) Assistance Procedures, by WHO through its system of Collaborating Centres on human radiation pathology, and by various States via regional or inter-countries' agreements on

  8. The Student Volunteer Army: a 'repeat emergent' emergency response organisation.

    Science.gov (United States)

    Carlton, Sally; Mills, Colleen E

    2017-10-01

    This paper seeks to contribute to understanding of the factors associated with an effective emergent emergency response organisation and to provide new insights into this understudied area. It examines, through an analysis of a range of textual resources, the emergence and re-emergence of the Student Volunteer Army (SVA) during the devastating earthquakes in Canterbury, New Zealand, in 2010-11. This evaluation is conducted in relation to the four key features of an effective emergency response organisation: adaptability; direction; leadership; and communication. In addition, the paper aims to further understanding of 'emergency entrepreneurship' and thus of the values and strategies that underpin social entrepreneur organisations in times of normalcy. The paper concludes that the unique position of the SVA as a 'repeat emergent' emergency response organisation enabled it to innovate continually and to improve repeatedly its systems, relationships, and image, such that it exhibited features common to emergent and established emergency response organisations. © 2017 The Author(s). Disasters © Overseas Development Institute, 2017.

  9. Emergency planning and response preparedness in Slovenia

    International Nuclear Information System (INIS)

    Martincic, R.; Frlin-Lubi, A.; Usenicnik, B.

    2000-01-01

    Disasters do occur and so do nuclear or radiological accidents. Experience has shown that advance emergency response preparedness is essential in order to mitigate the consequences of an accident. In Slovenia, the Civil Protection Organization is the responsible authority for emergency preparedness and response to any kind of disasters. The Krko Nuclear Power Plant is the only nuclear power plant in Slovenia. To date the plant has operated safely and no serious incidents have been recorded. Slovenia nevertheless, maintains a high level of emergency preparedness, which is reflected in the area of prevention and safety and in the area of emergency response preparedness. The emergency management system for nuclear emergencies is incorporated into an overall preparedness and response system. The paper presents an overview of nuclear or radiological emergency response preparedness in Slovenia and its harmonization with the international guidelines. (author)

  10. ACCIDENT AT «FUKUSHIMA-»I NPP: FIRST RESULTS OF EMERGENCY RESPONSE REPORT 2: ACTIVITIES OF THE ROSPOTREBNADZOR AUTHORITIES FOR THE RADIATION PROTECTION OF THE RUSSIAN FEDERATION POPULATION ON THE EARLY STAGE OF ACCIDENT

    Directory of Open Access Journals (Sweden)

    G. G. Onischenko

    2011-01-01

    Full Text Available Basic measures of the Rospotrebnadzor emergency response during the early stage of the «Fukushima-I» NPP radiation accident are being analyzed in the article. Radiation monitoring of the environmental objects of the territories of the Russian Federation Far East Federal District, radiation control of arriving from Japan vehicles, freights and passengers as well as imported from Japan food products were promptly organized. This allowed to get reliable evaluations of the levels of radioactive contamination at the Russian Federation territory and population exposure doses due to the «Fukushima-I» NPP accident, timely exclude the possibility of import to the Russian territory for the freights, vehicles, food products having contamination exceeding established in the Russian Federation standards.

  11. State-level emergency preparedness and response capabilities.

    Science.gov (United States)

    Watkins, Sharon M; Perrotta, Dennis M; Stanbury, Martha; Heumann, Michael; Anderson, Henry; Simms, Erin; Huang, Monica

    2011-03-01

    Prior assessments of public health readiness had identified gaps in radiation preparedness. In recent years, preparedness planning has involved an "all-hazards" approach. Current assessment of the national status related to radiation public health emergency preparedness capabilities at the state and local health department levels was needed. A survey of state health departments related to radiation readiness was undertaken in 2010 by the Council of State and Territorial Epidemiologists (CSTE). States with nuclear power plants were instructed to consider their responses exclusive of capabilities and resources related to the plants given that the emergency response plans for nuclear power plants are specific and unique. Thirty-eight (76%) state health departments responded to the survey, including 26 of the 31 states with nuclear power plants. Specific strengths noted at the state level included that the majority of states had a written radiation response plan and most plans include a detailed section for communications issues during a radiation emergency. In addition, more than half of the states indicated that their relationship with federal partners is sufficient to provide resources for radiation emergencies, indicating the importance states placed on federal resources and expertise. Specific weaknesses are discussed and include that most states had completed little to no planning for public health surveillance to assess potential human health impacts of a radiation event; less than half had written plans to address exposure assessment, environmental sampling, human specimen collection and analysis, and human health assessment. Few reported having sufficient resources to do public health surveillance, radiation exposure assessment, laboratory functions and other capabilities. Levels of planning, resources and partnerships varied among states, those with nuclear power plants were better prepared. Gaps were evident in all states; however and additional training and

  12. Generic procedures for assessment and response during a radiological emergency

    International Nuclear Information System (INIS)

    2000-08-01

    One of the most important aspects of managing a radiological emergency is the ability to promptly and adequately determine and take actions to protect members of the public and emergency workers. Radiological accident assessment must take account of all critical information available at any time and must be an iterative and dynamic process aimed at reviewing the response as more detailed and complete information becomes available. This manual provides the tools, generic procedures and data needed for an initial response to a non-reactor radiological accident. This manual is one out of a set of IAEA publications on emergency preparedness and response, including Method for the Development of Emergency Response Preparedness for Nuclear or Radiological Accidents (IAEA-TECDOC-953), Generic Assessment Procedures for Determining Protective Actions During a Reactor Accident (IAEA-TECDOC-955) and Intervention Criteria in a Nuclear or Radiation Emergency (Safety Series No. 109)

  13. Technical information management in an emergency response

    International Nuclear Information System (INIS)

    Berry, H.A.; Greve, C.; Best, R.G.; Phillipson, D.S.

    1991-01-01

    Through many experiences in responding to real radiation accidents and emergency response exercises, the Department of Energy (DOE) has developed a technical information management system that will be used in the Federal Radiological Monitoring and Assessment Center (FRMAC) in the event of a major radiological accident. The core of the system is the Data Center in the FRMAC, utilizing a computerized database of all off-site environmental radiological data. The information contained and managed by the Data Center will be comprehensive, accountable, and traceable, providing information to the assessors for immediate health and safety needs as well as for long-term documentation requirements. A DOE task force has been formed to develop compatibility guidelines for video, automated data processing, and communication systems. An electronic mail, information status, and bulletin board system is also being developed to assist in the dissemination of information. Geographic Information Systems (GIS) offer a giant step forward in displaying and analyzing information in a geographically referenced system

  14. Reflections on the emergency preparations and responses of China to Fukushima nuclear accident in Japan

    International Nuclear Information System (INIS)

    Chen Xiaoqiu; Li Bing; Yu Shaoqing

    2012-01-01

    This paper reviewed the emergency response of Japan in Fukushima nuclear accident, provided and discussed the issues should be of concern on emergency preparedness and response in future: (1) modifying the existing emergency preparedness and response system; (2) consolidating the concept of emergency preparedness as the ultimate level of defense-in-depth; (3) promoting the emergency response decision-making support capabilities; (4) valuing the information opening of involving nuclear news and radiation environmental information. (authors)

  15. Caire - A real-time feedback system for emergency response

    International Nuclear Information System (INIS)

    Braun, H.; Brenk, H.D.; de Witt, H.

    1991-01-01

    In cases of nuclear emergencies it is the primary task of emergency response forces and decision making authorities to act properly. Whatever the specific reason for the contingency may be, a quick and most accurate estimate of the radiation exposure in consequence of the emergency must be made. This is a necessary prerequisite for decisions on protective measures and off-site emergency management. With respect to this fact ant the recent experience of the Chernobyl accident, remote monitoring systems have increased their importance as an inherent part of environmental surveillance installations in the FRG and in other countries. The existing systems in Germany are designed to cover both, routine operation and emergency situations. They provide site specific meteorological data, gross effluent dose rates, and dose rate measurements at on-site and approximately 30 off-site locations in the vicinity of a plant. Based on such telemetric surveillance networks an advanced automatic on-line system named CAIRE (Computer Aided Response to Emergencies) has been developed as a real time emergency response tool for nuclear facilities. this tool is designed to provide decision makers with most relevant radiation exposure data of the population at risk. The development phase of CAIRE has already been finished. CAIRE is now in an operational status and available for applications in emergency planning and response

  16. Radiological emergency: Malaysian preparedness and response

    International Nuclear Information System (INIS)

    Yusof, M. A. W.; Ali, H. M.

    2011-01-01

    Planning and preparation in advance for radiological emergencies can help to minimise potential public health and environmental threats if and when an actual emergency occurs. During the planning process, emergency response organisations think through how they would respond to each type of incident and the resources that will be needed. In Malaysia, planning, preparation for and response to radiological emergencies involve many parties. In the event of a radiological emergency and if it is considered a disaster, the National Security Council, the Atomic Energy Licensing Board and the Malaysian Nuclear Agency (Nuclear Malaysia) will work together with other federal agencies, state and local governments, first responders and international organisations to monitor the situation, contain the release, and clean up the contaminated site. Throughout the response, these agencies use their protective action guidelines. This paper discusses Malaysian preparedness for, and response to, any potential radiological emergency. (authors)

  17. Adaptive workflow simulation of emergency response

    NARCIS (Netherlands)

    Bruinsma, Guido Wybe Jan

    2010-01-01

    Recent incidents and major training exercises in and outside the Netherlands have persistently shown that not having or not sharing information during emergency response are major sources of emergency response inefficiency and error, and affect incident mitigation outcomes through workflow planning

  18. Radiation emergency medical preparedness and assistance network in Korea

    International Nuclear Information System (INIS)

    Kim, E. S.; Kong, H. J.; Noh, J. H.; Lim, Y. K.; Kim, C. S.

    2003-01-01

    Nationwide Medical Preparedness for Nuclear Accidents as an integral part of nuclear safety system has been discussed for several years and Radiation Health Research Institute (RHRI) of Korea Hydro and Nuclear Power Co. was established on July, 1999. The National Radiation Emergency Medical Center (NREMC) of Korea Cancer Center Hospital was also founded on September, 2002. Two organizations have established Radiation Emergency Medical Preparedness and Assistance Network in Korea to cope with accidental situations in nuclear power plants and also in handling sites of radionuclides. In order to construct an effective Nationwide Emergency Medical Network System they maintain good cooperation among regional hospitals. RHRI is going to make three types of medical groups, that is to say, the collaboration of the regional (primary appointed) hospital group around the nuclear power plants, the regional core (secondary appointed) hospital group and the central core hospital (RHRI). NREMC is also playing a central role in collaboration with 10 regional hospitals. Two cores are working key role for the maintenance of the network. Firstly, They maintain a radiological emergency response team consisting of physicians, nurses, health physicists, coordinators, and necessary support personnel to provide first-line responders with consultative or direct medical and radiological assistance at their facility or at the accident site. Secondly, they serves educational programs for the emergency personnel of collaborating hospitals not only as a treatment facility but also as a central training and demonstration unit. Regularly scheduled courses for the physician and nurse, and health/medical physicists are conducted. Therefore, to activate Nationwide Emergency Medical Network System and to maintain it for a long time, well-trained specialists and budgetary supports are indispensable

  19. IEA Response System for Oil Supply Emergencies

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2008-12-15

    Emergency response to oil supply disruptions has remained a core mission of the International Energy Agency since its founding in 1974. This information pamphlet explains the decisionmaking process leading to an IEA collective action, the measures available -- focusing on stockdraw -- and finally, the historical background of major oil supply disruptions and the IEA response to them. It also demonstrates the continuing need for emergency preparedness, including the growing importance of engaging key transition and emerging economies in dialogue about energy security.

  20. IEA Response System for Oil Supply Emergencies

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2010-07-15

    Emergency response to oil supply disruptions has remained a core mission of the International Energy Agency since its founding in 1974. This information pamphlet explains the decisionmaking process leading to an IEA collective action, the measures available -- focusing on stockdraw -- and finally, the historical background of major oil supply disruptions and the IEA response to them. It also demonstrates the continuing need for emergency preparedness, including the growing importance of engaging key transition and emerging economies in dialogue about energy security.

  1. Basic data of emergency response centre

    International Nuclear Information System (INIS)

    Jenieek, O.

    1995-01-01

    Emergency Response Centre (ERC) of Czech Republic is a highly specialized institution belonging to Nuclear Safety State Administration (SONS), which assures its activities both organizationally and technically. Main function of the ERC in the case of nuclear emergency is to fulfil the needs of SONS, Governmental Committee for Nuclear Emergencies in ER (GCNE ER) and the regional organs of State Authorities concerning the emergency planning and preparedness, evaluation of nuclear emergency consequences, including the emergency management and response. In the case of major failure or accident on NPP, the ERC carries out the performance analysis and review of a given NPP. It also monitors the dosimetric situation and transfers the recommendation to GCNE ER, Regional Emergency Management Committees and to NPP

  2. Radiation, Inflammation, and Immune Responses in Cancer

    Energy Technology Data Exchange (ETDEWEB)

    Multhoff, Gabriele [Department of Radiation Oncology, Klinikum rechts der Isar, Technische Universität München, Munich (Germany); Helmholtz Zentrum München, Clinical Cooperation Group Innate Immunity in Tumor Biology, Munich (Germany); Radons, Jürgen, E-mail: raj10062@web.de [multimmune GmbH, Munich (Germany)

    2012-06-04

    Chronic inflammation has emerged as one of the hallmarks of cancer. Inflammation also plays a pivotal role in modulating radiation responsiveness of tumors. As discussed in this review, ionizing radiation (IR) leads to activation of several transcription factors modulating the expression of numerous mediators in tumor cells and cells of the microenvironment promoting cancer development. Novel therapeutic approaches thus aim to interfere with the activity or expression of these factors, either in single-agent or combinatorial treatment or as supplements of the existing therapeutic concepts. Among them, NF-κB, STAT-3, and HIF-1 play a crucial role in radiation-induced inflammatory responses embedded in a complex inflammatory network. A great variety of classical or novel drugs including nutraceuticals such as plant phytochemicals have the capacity to interfere with the inflammatory network in cancer and are considered as putative radiosensitizers. Thus, targeting the inflammatory signaling pathways induced by IR offers the opportunity to improve the clinical outcome of radiation therapy by enhancing radiosensitivity and decreasing putative metabolic effects. Since inflammation and sex steroids also impact tumorigenesis, a therapeutic approach targeting glucocorticoid receptors and radiation-induced production of tumorigenic factors might be effective in sensitizing certain tumors to IR.

  3. Radiation, Inflammation, and Immune Responses in Cancer

    International Nuclear Information System (INIS)

    Multhoff, Gabriele; Radons, Jürgen

    2012-01-01

    Chronic inflammation has emerged as one of the hallmarks of cancer. Inflammation also plays a pivotal role in modulating radiation responsiveness of tumors. As discussed in this review, ionizing radiation (IR) leads to activation of several transcription factors modulating the expression of numerous mediators in tumor cells and cells of the microenvironment promoting cancer development. Novel therapeutic approaches thus aim to interfere with the activity or expression of these factors, either in single-agent or combinatorial treatment or as supplements of the existing therapeutic concepts. Among them, NF-κB, STAT-3, and HIF-1 play a crucial role in radiation-induced inflammatory responses embedded in a complex inflammatory network. A great variety of classical or novel drugs including nutraceuticals such as plant phytochemicals have the capacity to interfere with the inflammatory network in cancer and are considered as putative radiosensitizers. Thus, targeting the inflammatory signaling pathways induced by IR offers the opportunity to improve the clinical outcome of radiation therapy by enhancing radiosensitivity and decreasing putative metabolic effects. Since inflammation and sex steroids also impact tumorigenesis, a therapeutic approach targeting glucocorticoid receptors and radiation-induced production of tumorigenic factors might be effective in sensitizing certain tumors to IR.

  4. Understanding Public Responses to Emerging Technologies

    NARCIS (Netherlands)

    Macnaghten, Philip; Davies, S.R.; Kearnes, Matthew

    2015-01-01

    Previous studies aimed at understanding public responses to emerging technologies have given limited attention to the social and cultural processes through which public concerns emerge. When probed, these have tended to be explained either in cognitive social psychological terms, typically in the

  5. Land Transport Emergency Response Technology Report

    International Nuclear Information System (INIS)

    DOTSON, LORI J.; PIERCE, JIM D.

    2003-01-01

    Sandia National Laboratories was tasked by the Japan Nuclear Cycle Development Institute (JNC) to provide assistance in developing an emergency response plan for radioactive material transportation activities. Those tasks included compiling radioactive materials (RAM) transportation accident data FR-om the open literature and databases, investigating emergency response plans for radioactive materials transport in the United States, and developing specific recommendations for the JNC' nuclear material transport emergency response plan, based on information gathered during the first two tasks. These recommendations include developing a RAM database, a public transparency Internet website, an emergency response inFR-astructure designed specifically for transportation needs, and a clear set of directives to provide authority in the case of transportation accidents or incidents involving RAM

  6. Hazardous materials transportation and emergency response programs

    International Nuclear Information System (INIS)

    Joy, D.S.; Fore, C.S.

    1983-01-01

    This presentation consists of the following visual aids; (1) detailed routing capabilities of truck, rail, barge; (2) legislative data base for hazardous materials; and (3) emergency response of accident site Eddyville, Kentucky (airports in vicinity of Eddyville, KY)

  7. Radiological emergency response - a functional approach

    International Nuclear Information System (INIS)

    Chowdhury, P.

    1998-01-01

    The state of Louisiana's radiological emergency response programme is based on the federal guidance 'Criteria for Preparation and Evaluation of Radiological Emergency Response Plans and Preparedness in Support of Nuclear Power Plants' (NUREG-0654, FEMA-REP-1 Rev. 1). Over the past 14 years, the planning and implementation of response capabilities became more organized and efficient; the training programme has strengthened considerably; co-ordination with all participating agencies has assumed a more co-operative role, and as a result, a fairly well integrated response planning has evolved. Recently, a more 'functional' approach is being adopted to maximize the programme's efficiency not only for nuclear power plant emergency response, but radiological emergency response as a whole. First, several broad-based 'components' are identified; clusters of 'nodes' are generated for each component; these 'nodes' may be divided into 'sub-nodes' which will contain some 'attributes'; 'relational bonds' among the 'attributes' will exist. When executed, the process begins and continues with the 'nodes' assuming a functional and dynamic role based on the nature and characteristics of the 'attributes'. The typical response based on stand-alone elements is thus eliminated, the overlapping of functions is avoided, and a well structured and efficient organization is produced, that is essential for today's complex nature of emergency response. (author)

  8. Issues of damage estimation under radiation emergency situation

    International Nuclear Information System (INIS)

    Volobuev, P.V.; Kozlova, N.I.

    2005-01-01

    The specificity of social, economical and ecological consequences of major radiation emergency situation is considered in the paper. The definitions and structure of direct and indirect damage under radiation emergency situation are given. The priority components of immediate expenses and those of long-term living on the contaminated territories are considered in the paper. (author)

  9. Overview of radiation emergencies: international perspective

    International Nuclear Information System (INIS)

    Lindell, B.

    1986-01-01

    The author gives an international perspective to emergency planning focusing on the situation in Sweden after the Chernobyl accident. The situation in Sweden, as in other European countries outside the USSR, was not covered by emergency plans. There was no accident site within the country and, therefore, no local authority responsible for remedial action. Nevertheless, the central authorities had to deal with the immediate situation. The most urgent task was to find areas where milk-producing cattle could be released to the fields. The Swedish authorities decided that an appropriate level for rejecting food on the market would be 300 Bq/kg. In order to ascertain that dairy milk would not exceed 300 Bq/l, the Swedish authorities requested farmers in the most contaminated regions to keep milk-producing cattle indoors about six weeks. Sweden, like many other countries, was lucky that the accident did not happen later in the grazing season and that the rain-out of radioactive material from the cloud did not occur over the main agricultural areas; otherwise, the consequences would have been much worse

  10. Emergency Response Resources guide for nuclear power plant emergencies

    International Nuclear Information System (INIS)

    1992-07-01

    On August 28 and September 18, 1990, the States of Louisiana and Mississippi, Gulf States Utilities, five local parishes, six Federal agencies, and the American Nuclear Insurers participated in a post-emergency TABLETOP exercise in Baton Rouge, Louisiana. One of the products developed from that experience was this guide for understanding the responsibilities and obtaining resources for specific needs from the various participants, particularly from those organizations within the Federal Government. This first revision of that guide broadens the focus of the original document. Also, new information defines the major Federal response facilities. This guide should assist State and local government organizations with identifying and obtaining those resources for the post-emergency response when their resources have been exhausted

  11. Off-site response for radiological emergencies

    International Nuclear Information System (INIS)

    Eldridge, J.S.; Oakes, T.W.; Hubbard, H.M.; Hibbitts, H.W.

    1982-01-01

    Environmental radiological surveillance under emergency conditions at off-site locations is one of the advisory functions provided by DOE within the ORO jurisdiction. The Department of Environmental Management of ORNL has been requested to provide sampling and analytical assistance at such emergency response activities. We have assembled and identified specific individuals and equipment to provide a rapid response force to perform field measurements for environmental radioactivity releases as a consequence of nuclear accidents. Survey teams for sample collection and field measurements are provided along with analytical assistance to operate the radioactivity measuring equipment in the DOE emergency van

  12. Unmanned Mobile Monitoring for Nuclear Emergency Response

    Energy Technology Data Exchange (ETDEWEB)

    Choi, YoungSoo; Park, JongWon; Kim, TaeWon; Jeong, KyungMin [Korea Atomic Energy Research Institute, Daejeon (Korea, Republic of)

    2016-10-15

    Severe accidents at nuclear power plant have led to significant consequences to the people, the environment or the facility. Therefore, the appropriate response is required for the mitigation of the accidents. In the past, most of responses were performed by human beings, but it was dangerous and risky. In this paper, we proposed unmanned mobile system for the monitoring of nuclear accident in order to response effectively. For the integrity of reactor cooling and containment building, reactor cooling pipe and hydrogen distribution monitoring with unmanned ground vehicle was designed. And, for the safety of workers, radiation distribution monitoring with unmanned aerial vehicle was designed. Unmanned mobile monitoring system was proposed to respond nuclear accidents effectively. Concept of reinforcing the integrity of RCS and containment building, and radiation distribution monitoring were described. RCS flow measuring, hydrogen distribution measuring and radiation monitoring deployed at unmanned vehicle were proposed. These systems could be a method for the preparedness of effective response of nuclear accidents.

  13. Ontario Power Generation Fukushima emergency response drill strengthens and lessons learned - Ontario Power Generation Fukushima Emergency Response Drill Highlights

    International Nuclear Information System (INIS)

    Miller, David W.

    2014-01-01

    Japan's Fukushima Daiichi severe nuclear accident in March 2011 has resulted in a reassessment of nuclear emergency response and preparedness in Canada. On May 26, 27 and 28, 2014 Ontario Power Generation (OPG) conducted the first North American full scale nuclear emergency response exercise designed to include regional, provincial and federal bodies as well as the utility. This paper describes the radiological aspects of the OPG Exercise Unified Response (ExUR) with emphasis on deployment of new Fukushima equipment on the Darlington site, management of emergency workers deplored in the vicinity of Darlington to collect environmental samples and radiation measurements, performance of dose calculations, communication of dose projections and protective actions to local, provincial and federal agencies and conduct of vehicle, truck and personnel monitoring and decontamination facilities. The ExUR involved more than 1000 personnel from local, provincial and federal bodies. Also, 200 OPG employees participated in the off-site emergency response duties. The objective of the ExUR was to test and enhance the preparedness of the utility (OPG), government and non-government agencies and communities to respond to a nuclear emergency. The types of radiological instrumentation and mobile facilities employed are highlighted in the presentation. The establishment of temporary emergency rooms with 8 beds and treatment facilities to manage potentially contaminated injuries from the nuclear emergency is also described. (author)

  14. Using risk based tools in emergency response

    International Nuclear Information System (INIS)

    Dixon, B.W.; Ferns, K.G.

    1987-01-01

    Probabilistic Risk Assessment (PRA) techniques are used by the nuclear industry to model the potential response of a reactor subjected to unusual conditions. The knowledge contained in these models can aid in emergency response decision making. This paper presents requirements for a PRA based emergency response support system to date. A brief discussion of published work provides background for a detailed description of recent developments. A rapid deep assessment capability for specific portions of full plant models is presented. The program uses a screening rule base to control search space expansion in a combinational algorithm

  15. Radiological emergency response planning in Pennsylvania

    International Nuclear Information System (INIS)

    Henderson, O.K.

    1981-01-01

    The most important aspect of emergency preparedness is to recognize and accept the fact that there exists a potential for a problem or a condition and that it requires some attention. Emergency plans should be sufficiently flexible so as to accommodate the emergency situation as it unfolds. Of the several emergency responses that may be taken following a nuclear power plant accident evacuation evokes the greatest attention and discussion as to whether it is truly a feasible option. Movements of people confined to mass care facilities or on life support systems involve special requirements. The Three Mile Island accident has been the most studied nuclear incident in the history of the nuclear power reactor industry. The findings of these reports will have a major influence on nuclear power issues as they are addressed in the future. The question remains as to whether the political leadership will be willing to provide the resources required by the emergency plan. Future safety and emergency response to nuclear accidents depend upon Government and industry acting responsibly and not merely responding to regulations. The Three Mile Island accident has had some beneficial side effects for the emergency management community. It has: increased the level of awareness and importance of emergency planning; served as a catalyst for the sharing of experiences and information; encouraged standardization of procedures; and emphasized the need for identifying and assigning responsibilities. The Emergency Management Organization in responding to a disaster situation does not enjoy the luxury of time. It needs to act decisively and correctly. It does not often get a second chance. Governments, at all levels, and the nuclear power industry have been put on notice as a result of Three Mile Island. The future of nuclear energy may well hang in the balance, based upon the public's perception of the adequacy of preparedness and safety measures being taken. (author)

  16. Radiological Emergency Response Health and Safety Manual

    Energy Technology Data Exchange (ETDEWEB)

    D. R. Bowman

    2001-05-01

    This manual was created to provide health and safety (H&S) guidance for emergency response operations. The manual is organized in sections that define each aspect of H and S Management for emergency responses. The sections are as follows: Responsibilities; Health Physics; Industrial Hygiene; Safety; Environmental Compliance; Medical; and Record Maintenance. Each section gives guidance on the types of training expected for managers and responders, safety processes and procedures to be followed when performing work, and what is expected of managers and participants. Also included are generic forms that will be used to facilitate or document activities during an emergency response. These ensure consistency in creating useful real-time and archival records and help to prevent the loss or omission of information.

  17. Radiation Response of Rhombohedral Oxides

    International Nuclear Information System (INIS)

    Devanathan, R.; Weber, W.J.; Mitchell, J.N.; Sickafus, K.E.; Nastasi, M.

    1997-05-01

    The radiation response of three rhombohedral oxides, namely, sapphire (α-Al 2 O 3 ), ilmenite (FeTiO 3 ), and geikielite (MgTiO 3 ), has been examined by irradiating electron transparent samples with 1 MeV Kr(+) and 1.5 MeV Xe(+)ions. The microstructural changes during irradiation were observed in situ in a high-voltage electron microscope using electron diffraction and microscopy. The irradiation conditions were designed to minimize beam heating and chemical effects due to the implanted ion. Of the three oxides studied, ilmenite is the most susceptible to radiation-induced amorphization while sapphire is the least susceptible. In all three materials, the critical temperature for amorphization was below 300 K indicating good room temperature resistance to amorphization by energetic beams

  18. The TransPetro emergency response system

    Energy Technology Data Exchange (ETDEWEB)

    Filho, A.T.F.; Cardoso, V.F.; Carbone, R.; Berardinelli, R.P. [Petrobras-TransPetro, Rio de Janeiro (Brazil); Carvalho, M.T.M.; Casanova, M.A. [Pontificia Univ. Catolica, Rio de Janeiro (Brazil). Dept. de Informatica, TeCGraf

    2004-07-01

    Petrobras-TransPetro developed the TransPetro Emergency Response System in response to emergency situations at large oil pipelines or at terminal facilities located in sea or river harbour areas. The standard of excellence includes full compliance with environmental regulations set by the federal government. A distributed workflow management software called InfoPAE forms the basis of the system in which actions are defined, along with geographic and conventional data. The first prototype of InfoPAE was installed in 1999. Currently it is operational in nearly 80 installations. The basic concepts and functionality of the TransPetro Emergency Response System were outlined in this paper with reference to the mitigative actions that are based on an evaluation of the organization of the emergency teams; the communication procedures; characterization of the installations; definition of accidental scenarios; environmental sensitivity maps; simulation of oil spill trajectories and dispersion behaviour; geographical data of the area surrounding the installations; and, other conventional data related to the installations, including available equipment. The emergency response team can take action as soon as an accident is detected. The action plan involves characterizing several scenarios and delegating mitigative actions to specific sub-teams, each with access to geographic data on the region where the emergency occurred. 13 refs., 3 figs.

  19. Resolution no. 18/2012 Guide for the preparation and emergency response radiological

    International Nuclear Information System (INIS)

    2012-01-01

    This guide aims to establish requirements to ensure an adequate level of entities, for the preparation and response to radiological emergencies and to prepare the Radiation Emergency Plan (PER), asset out in the Basic Safety Standards radiological and authorizations Regulations in force. This guide applies to organizations providing employment practices associated with sources of ionizing radiation, hereinafter sources.

  20. The current status and reinforcement plan for radiation emergency medicine in Korea

    International Nuclear Information System (INIS)

    Kim, Hyun Ki; Lee, Youngmin; Lee, Jai Ki

    2011-01-01

    Korea operating twenty nuclear power plants was ranked 6th in nuclear power generation in the world. The potential risk for radiological emergency also increases along with the growing use of radiation and radioisotopes and a constant expansion of the nuclear industry in neighboring countries, Japan and China. This paper is intended for finding ways to strengthen medical planning and response preparedness from achievements in radiation emergency medicine over the years. 'Integrated Medical Preparedness System' for a radiological disaster is proposed as a practical way to enhance mobilization of existing human and material resources in the health care. It is based on the collaborative response among the related medical institutes : radiation emergency medical institutes around the Korean Institute of Radiological and Medical Sciences, emergency medical centers around the National Emergency Medical Center and other hospitals available. (author)

  1. An emergency response plan for transportation

    International Nuclear Information System (INIS)

    Fontaine, M.V.; Guerel, E.

    2000-01-01

    Transnucleaire is involved in road and rail transport of nuclear fuel cycle materials. To comply with IAEA recommendations, Transnucleaire has to master methods of emergency response in the event of a transport accident. Considering the utmost severe situations, Transnucleaire has studied several cases and focused especially on an accident involving a heavy cask. In France, the sub-prefect of each department is in charge of the organisation of the emergency teams. The sub-prefect may request Transnucleaire to supply experts, organisation, equipment and technical support. The Transnucleaire Emergency Response Plan covers all possible scenarios of land transport accidents and relies on: (i) an organisation ready for emergency situations, (ii) equipment dedicated to intervention, and (iii) training of its own experts and specialised companies. (author)

  2. Radiation protection - radiographer's role and responsibilities

    International Nuclear Information System (INIS)

    Popli, P.K.

    2002-01-01

    Ever since discovery of x-rays, radiographers has been the prime user of radiation. With the passage of time, the harmful effects of radiation were detected. Some of radiographers, radiologists and public were affected by radiation, but today with enough knowledge of radiation, the prime responsibility of radiation protection lies with the radiographers only. The radiologist and physicist are also associated with radiation protection to some extent

  3. Emergency response plan for accidents in Saudi Arabia

    International Nuclear Information System (INIS)

    Al-Solaiman, K.M.; Al-Arfaj, A.M.; Farouk, M.A.

    2000-01-01

    This paper presents a brief description of the general emergency plan for accidents involving radioactive materials in the Kingdom of Saudi Arabia. Uses of radioactive materials and radiation sources and their associated potential accident are specified. Most general accident scenarios of various levels have been determined. Protective measures have been specified to reduce individual and collective doses arising during accident situations. Intervention levels for temporary exposure situations, as established in the IAEA's basic safety standards for protection against ionising radiation and for the safety of radiation sources, are adopted as national intervention levels. General procedures for implementation of the response plan, including notification and radiological monitoring instrumentation and equipment, are described and radiation monitoring teams are nominated. Training programs for the different parties which may be called upon to respond are studied and will be started. (author)

  4. Regional training course on medical response on radiological emergencies. Annex

    International Nuclear Information System (INIS)

    2000-01-01

    This short information is an annex of the documentation distributed to the participants to the International Atomic Energy Agency (IAEA) Regional Training Course on Medical Response on Radiological Emergencies, organised by the IAEA in co-operation with the Government of Argentina thought the Nuclear Regulatory Authority, held in Buenos Aires, Argentina, 16-20 October 2000. The course was intended to people from IAEA Member State in the Latin American and Caribbean region, and to professionals and workers on medicine related with the radiation protection. This annex present information about: Radioactive materials transport; Internal and external contamination; Radiation accidents; Physical dosimetry

  5. Measures against radiation disaster/terrorism and radiation emergency medical assistance team

    International Nuclear Information System (INIS)

    Tominaga, Takako; Akashi, Makoto

    2016-01-01

    The probability of occurrence of radiological terrorism and disaster in Japan is not low. For this reason, preparations for coping with the occurrence of radiological terrorism should be an urgent issue. This paper describes the radiation medical system and the threat of radiological terrorism and disaster in Japan, and introduces the Radiation Emergency Medical Assistance Team (REMAT), one of the radiation accident/disaster response organizations at the National Institute of Radiological Sciences. Radiation exposure medical systems in Japan are constructed only in the location of nuclear facilities and adjacent prefectures. These medical systems have been developed only for the purpose of medical correspondence at the time of nuclear disaster, but preparations are not made by assuming measures against radiological terrorism. REMAT of the National Institute of Radiological Sciences is obligated to dispatch persons to the requesting prefecture to support radiation medical care in case of nuclear disaster or radiation accident. The designation of nuclear disaster orientated hospitals in each region, and the training of nuclear disaster medical staffing team were also started, but preparations are not enough. In addition to enhancing and strengthening experts, specialized agencies, and special forces dealing with radiological terrorism, it is essential to improve regional disaster management capacity and terrorism handling capacity. (A.O.)

  6. Revised radiation emergency procedures at Pakistan research reactor PINSTECH

    International Nuclear Information System (INIS)

    Orfi, S.D.; Javed, M.; Ahmad, S.; Akhtar, K.M.; Mubarak, M.A.

    1984-12-01

    Necessary procedures have been laid down in this report to meet the radiation emergency at Pakistan Research Reactor PINSTECH. The Nuclear Safety Committee PINSTECH (NSCP) had also recommended a number of improvements in the existing procedures. Revision of the procedures was also considered necessary to incorporate into it new radiation units/limits and new emergency equipment available. Radiation emergency preparedness programme is of continuous nature. Latest developments else-where and local experience contribute to the improvement of the existing arrangements under this programme. (A.B.)

  7. Emergency response in the Newfoundland offshore industry

    International Nuclear Information System (INIS)

    Dempsey, J.

    2006-01-01

    This presentation reviewed current offshore oil activities with respect to safety issues regarding year-round marine operations in a harsh environment. Considerable logistics support is required for all offshore activities, including seismic and geotechnical surveys; exploration and production drilling; well testing; subsea construction; on-site production; and, delivery to market. Response to an offshore emergency must address the urgency of the incident along with stakeholder concerns. This presentation described the different types of emergencies and addressed issues regarding contingency planning; preventative measures; response philosophy; response scope; response at site; emergency management; communications links; and, oil spill response. The following current operations were highlighted: ExxonMobil's production drilling from the gravity-based concrete platform at Hibernia; Petro-Canada's production drilling at the Terra Nova FPSO; Husky Energy's production drilling at White Rose; and Chevron Canada's exploration drilling at the Orphan Basin. It was noted that in an emergency situation, the focus is on the welfare of offshore personnel. On an average day, the total offshore population is in the order of 1000 workers, all registered in the Personnel Logistics System which is updated with the departure of every helicopter from St. John's, Newfoundland or from the offshore platform. It is possible to prepare for foreseeable emergency incidents such as fire, explosion or gas leaks; spills to the marine environment; structural damage or collisions; persons lost at sea; helicopter or support vessel accidents; vessel sinking; sabotage; serious injuries or loss of life; severe ice events; and, loss of well control. The establishment of permanent safety zones at the Hibernia, White Rose and Terra Nova production fields are among the preventative measures, along with standby vessels that provide a rescue service for offshore installations. Supply vessels are also

  8. Accidents and emergency conditions: Tasks of the radiation protection expert

    International Nuclear Information System (INIS)

    Hacke, J.

    1985-01-01

    This paper reviews and explains the tasks of the radiation protection expert at a given site in the event of accidents or emergencies involving a radiation hazard to the personnel. The various measures recommended discriminate between the main two types of hazards, namely external radiation or internal radiation. The paper discusses the first-aid and emergency measures recommended in various publications (BG, 1982; ICRP, 1980; MO, 1972; ME, 1980) and also cites recommendations contained therein, referring to preventive means and measures and to communications to the press and the general public. (DG) [de

  9. Post-emergency response resources guide

    International Nuclear Information System (INIS)

    1991-07-01

    On August 28 and September 18, 1990, the States of Louisiana and Mississippi, Gulf States Utilities, five local parishes, six Federal agencies, and the American Nuclear Insurers participated in a post-emergency TABLETOP exercise in Baton Rouge, Louisiana. One of the products developed from that experience is this guide for understanding the responsibilities and obtaining resources for specific needs from the various participants, particularly those organizations within the federal government. This guide should assist state and local government organizations with identifying and obtaining those resources for the post-emergency response when theirs have been exhausted

  10. Radiation response and chromatin dynamics

    International Nuclear Information System (INIS)

    Ikura, Tsuyoshi

    2009-01-01

    Described is a recent progress in studies of chromatin structural alterations induced by DNA damage by radiation. DNA in eukaryotes exists in the chromatin structure and different mechanisms of response to damage and repair of DNA from those in prokaryotes have been recognized. Chromatin is composed from its unit structure of mono-nucleosome, which is formed from DNA and an octamer of core histones of H2A, H2B, H3 and H4. When DNA is damaged, histone structural alterations are required for repair factors and checkpoint proteins to access the damaged site. At the actual genome damage, chemical modification of histone to work as a code occurs dependently on the damage where chromatin remodeling factors and histone chaperone participate for structural alteration and remodeling. As well, the exchange of histone variants and fluidization of histones are recently reported. Known chemical modification involves phosphorylation, acetylation and ubiquitination of H2AX (a variant of H2A), and acetylation and methylation of H3. Each complex of TIP60, NuA4 and INO80 is known to be included in the regulation of chromatin with damaged/repaired DNA for remodeling, but little is known about recruitment of the factors concerned at the damage site. Regulatory mechanisms in above chromatin dynamics with consideration of quality and timing of radiation should be further elucidated for understanding the precise response to DNA damage. (K.T.)

  11. Radioactive materials transportation emergency response plan

    International Nuclear Information System (INIS)

    Karmali, N.

    1987-05-01

    Ontario Hydro transports radioactive material between its nuclear facilities, Atomic Energy of Canada Limited at Chalk River Laboratories and Radiochemical Company in Kanata, on a regular basis. Ontario Hydro also occasionally transports to Whiteshell Laboratories, Hydro-Quebec and New Brunswick Electric Power Commission. Although there are stringent packaging and procedural requirements for these shipments, Ontario Hydro has developed a Radioactive Materials Transportation Emergency Response Plan in the event that there is an accident. The Transportation Emergency Response plan is based on six concepts: 1) the Province id divided into three response areas with each station (Pickering, Darlington, Bruce) having identified response areas; 2) response is activated via a toll-free number. A shift supervisor at Pickering will answer the call, determine the hazards involved from the central shipment log and provide on-line advice to the emergency worker. At the same time he will notify the nearest Ontario Hydro area office to provide initial corporate response, and will request the nearest nuclear station to provide response assistance; 3) all stations have capability in terms of trained personnel and equipment to respond to an accident; 4) all Ontario Hydro shipments are logged with Pickering NGS. Present capability is based on computerized logging with the computer located in the shift office at Pickering to allow quick access to information on the shipment; 5) there is a three tier structure for emergency public information. The local Area Manager is the first Ontario Hydro person at the scene of the accident. The responding facility technical spokesperson is the second line of Corporate presence and the Ontario Hydro Corporate spokesperson is notified in case the accident is a media event; and 6) Ontario Hydro will respond to non-Hydro shipments of radioactive materials in terms of providing assistance, guidance and capability. However, the shipper is responsible

  12. Integrated simulation of emergency response in disasters

    International Nuclear Information System (INIS)

    Kanno, Taro; Furuta, Kazuo

    2005-01-01

    An integrated simulation system of emergency response in disasters is under development that can consider various factors of disasters, such as disaster phenomena, activities of response organizations, resident behavior, and their environment. The aim of this system is to provide support for design and assessment of disaster management systems. This paper introduces the conceptual design of the entire system and presents simulators of organizational behavior in nuclear and earthquake disasters. (author)

  13. Medical Preparedness and Response for a Nuclear or Radiological Emergency. Training Materials

    International Nuclear Information System (INIS)

    2014-01-01

    In almost all nuclear and radiological emergencies, local emergency services (e.g. local medical, law enforcement, and fire brigades) will have the most important role in the early response. Within hours, hospitals may also have an important role to play in the response at the local level. Since nuclear and radiological emergencies are rare, medical responders often have little or no experience in dealing with this type of emergency and inexperience may lead to an inadequate response. For this reason, training in medical preparedness and response for a nuclear or radiological emergency is an important aspect of preparedness and response activities. These materials are designed for use at a training course on medical preparedness and response for a nuclear or radiological emergency. They contain a wide range of lectures and supporting materials, which cover the basic topics and more specific areas of medical preparedness and response. Therefore, in planning their specific courses, organizers are encouraged to choose those lectures and supportive materials from the CD-ROM that best match their training priorities. Materials on the CD-ROM address the following areas: • Terrorism in Perspective; • Malicious Act Scenarios; • Providing Information to the Medical Community and the Public; • Medical Response to a Radiation Mass Casualty Event; • Handling of Contaminated Persons in Malicious Events; • Planning and Preparedness for Medical Response to Malicious Events with Radioactive Material; • Handling the Bodies of Decedents Contaminated with Radioactive Material; • Radiation Emergencies: Scope of the Problem; • Common Sources of Radiation; • Basic Concepts of Ionizing Radiation; • Basic Concepts of Radiation Protection; • Biological Effects of Ionizing Radiation – Basic Notions; • Basics of Radiopathology; • External Radioactive Contamination; • Internal Radioactive Contamination; • Acute Radiation Syndrome; • Cutaneous Radiation

  14. Collaborative situational mapping during emergency response

    NARCIS (Netherlands)

    Gunawan, L.T.; Oomes, A.H.J.; Neerincx, M.; Brinkman, W.-P.; Alers, H.

    2009-01-01

    During emergency response, individuals observe only part of the picture, sharing of information is needed to get the required complete picture. The aim of our study is to get insight in the collaborative mapping process in order to derive requirements for a map-sharing tool. First, we analyzed the

  15. Emerging new modalities in dental radiology and radiation issues

    International Nuclear Information System (INIS)

    Gandhi, Rahul

    2014-01-01

    Dental radiology is emerging day by day with technological innovations and new dental radiological equipments. These sophisticated new emerging technological raise a concern about the radiation emitted by these equipments. This becomes more relevant in the context that there is frequent diagnostic radiographic exposure of head and neck region due to recurrent dental problems. The presentation deals with radiation exposure to the patients and professionals from these equipments. (author)

  16. Radiation emergency planning for medical organizations; Plan de emergencia radiologica en entidades de salud

    Energy Technology Data Exchange (ETDEWEB)

    Jerez Vergueria, Sergio F. [Instituto de Medicina del Trabajo, La Habana (Cuba); Jerez Vergueria, Pablo F. [Centro Nacional de Seguridad Nuclear, La Habana (Cuba)

    1997-12-31

    The possible occurrence of accidents involving sources of ionizing radiation demands response plans to mitigate the consequences of radiological accidents. This paper offers orientations in order to elaborate emergency planning for institutions with medical applications of ionizing radiation. Taking into account that the prevention of accidents is of prime importance in dealing with radioactive materials and others sources of ionizing radiation, such as X-rays, it is recommended that one include in emergency instructions and procedures several aspects relative to causes which originate these radiological events. Topics such as identification of radiological events in these practices and their consequences, protective measures, planning for and emergency response and maintenance of emergency capacity, are considered in this article. (author) 16 refs., 1 tab.; e-mail: sfjerez at rdc.puc-rio.br

  17. Medical response to effects of ionising radiation

    International Nuclear Information System (INIS)

    Crosbie, W.A.; Gittus, J.H.

    1989-01-01

    The proceedings of a conference on 'Medical Response to Effects of Ionising Radiation' in 1989 in the form of nineteen papers published as a book. Topics discussed include radiation accidents at nuclear facilities, the medical management of radiation casualties, the responsibilities, plans and resources for coping with a nuclear accident and finally the long term effects of radiation, including leukaemia epidemiology studies. All papers were selected and indexed separately. (UK)

  18. Radiation Emergency Preparedness Tools: Virtual Community Reception Center

    Centers for Disease Control (CDC) Podcasts

    This podcast is an overview of resources from the Clinician Outreach and Communication Activity (COCA) Call: Practical Tools for Radiation Emergency Preparedness. A specialist working with CDC's Radiation Studies Branch describes a web-based training tool known as a Virtual Community Reception Center (vCRC).

  19. More efficient response to nuclear emergencies

    International Nuclear Information System (INIS)

    1979-12-01

    A working group was appointed in 1978 to consider the problems which would face the local authorities in the unlikely event of a reactor accident considerably more severe than that foreseen as the basis of the emergency provisions as defined in the parliamentary bill of 1960. The group's report is here presented, together with appendices containing population and meteorological data. This report has been used by the Radiation protection Institute in its evaluations, which are presented in vol. 2 of this report. The views expressed in this report are those of the working group. (JIW)

  20. Composition and fundamental requirements of nuclear emergency response monitoring equipment

    International Nuclear Information System (INIS)

    Lai Yongfang; Huang Weiqi; Wang Yonghong

    2009-01-01

    Nuclear emergency monitoring equipment is concrete foundation for accomplishing radiation monitoring in nuclear or radiation accidents. Based on technical report: Generic procedures for monitoring in a nuclear or radiological emergency published by IAEA in 1999, this paper presents the main task and composition of nuclear emergency monitoring briefly, and then the basic equipment and trends of nuclear emergency monitoring equipment is put forward in detail, which is useful to construction and reinforcement of our nuclear emergency monitoring. (authors)

  1. Radiological emergency response - a functional approach

    Energy Technology Data Exchange (ETDEWEB)

    Chowdhury, Prosanta [Louisiana Radiation Protection Div., Baton Rouge, LA (United States)

    1997-12-31

    The radiological emergency response program in the State of Louisiana is discussed. The improved approach intends to maximize the efficiency for both nuclear power plant and radiological emergency response as a whole. Several broad-based components are identified: cluster of `nodes` are generated for each component; these `nodes` may be divided into `sub-nodes` which will contain some `attributes`; `relational bonds` among the `attributes` will exist. When executed, the process begins and continues with the `nodes` assuming a functional and dynamic role based on the nature and characteristics of the `attributes`. The typical response based on stand-alone elements is eliminated; overlapping of functions is avoided, and is produced a well-structure and efficient organization 1 ref., 6 figs.; e-mail: prosanta at deq.state.la.us

  2. Radiological emergency response - a functional approach

    International Nuclear Information System (INIS)

    Chowdhury, Prosanta

    1997-01-01

    The radiological emergency response program in the State of Louisiana is discussed. The improved approach intends to maximize the efficiency for both nuclear power plant and radiological emergency response as a whole. Several broad-based components are identified: cluster of 'nodes' are generated for each component; these 'nodes' may be divided into 'sub-nodes' which will contain some 'attributes'; 'relational bonds' among the 'attributes' will exist. When executed, the process begins and continues with the 'nodes' assuming a functional and dynamic role based on the nature and characteristics of the 'attributes'. The typical response based on stand-alone elements is eliminated; overlapping of functions is avoided, and is produced a well-structure and efficient organization

  3. Exercising the federal radiological emergency response plan

    International Nuclear Information System (INIS)

    Gant, K.S.; Adler, M.V.; Wolff, W.F.

    1986-01-01

    Multiagency exercises were an important part of the development of the Federal Radiological Emergency Response Plan. This paper concentrates on two of these exercises, the Federal Field Exercise in March 1984 and the Relocation Tabletop Exercise in December 1985. The Federal Field Exercise demonstrated the viability and usefulness of the draft plan; lessons learned from the exercise were incorporated into the published plan. The Relocation Tabletop Exercise examined the federal response in the postemergency phase. This exercise highlighted the change over time in the roles of some agencies and suggested response procedures that should be developed or revised. 8 refs

  4. Simulation analysis of the use of emergency resources during the emergency response to a major fire

    NARCIS (Netherlands)

    Zhou, Jianfeng; Reniers, G.L.L.M.E.

    2016-01-01

    During an emergency response to an accident or disaster, emergency response actions often need to use various emergency resources. The use of resources plays an important role in the successful implementation of emergency response, but there may be conflicts in the use of resources for emergency

  5. The emergency medical programs of japan and foreign countries for radiation accidents in nuclear power stations

    International Nuclear Information System (INIS)

    Aoki, Yoshiro

    1994-01-01

    In our country, the medical emergency programs for the people living near nuclear power stations are well organized, however, preparation of medical staffs who are well trained is considered to be not sufficient. In the USA, on call 24 hours response to a radiological emergency is provided and funded by Department of Energy(DOE) or electric companies. Especially, REAC/TS is a part of DOE response network, in which there are provided well-trained physicians, nurses, health physicists, coordinators and support personnels. In United Kingdom, National Radiological Protection Board(NRPB) is responsible to a radiological emergency program. Each nuclear power station has its own emergency program consisting of a team of physicians, nurses and health physicists. In France, French Atomic Energy Commission (CEA) is a responsible agency for a radiological emergency program. On call 24 hours response to a radiological emergency is provided in Fontenay-aux Roses Institute and Curie Institute. Curie Institute also responds to radiological emergencies in other countries at the request of WHO. In Germany(West Germany), compulsory assurance system covers a radiological emergency program and a radiological protection. There are seven centers in West Germany, in which well-trained medical staffs are provided against radiological injuries. In this report, I tried to propose a new concept about emergency medical programs for nuclear power station accidents in Japan. I think it is a very urgent theme to provide on call 24 hours radiological emergency program, in which patients suffered from acute radiation sickness with internal contamination or contaminated radiation burns will be treated without any trouble. We have to make our best efforts to complete basic or clinical research about radiation injuries including bone marrow transplantation, radioprotectors, chelating agents and radiation burns etc. (J.P.N.)

  6. Short radiological emergency response training program

    International Nuclear Information System (INIS)

    Williams, R.D.; Greenhouse, N.A.

    1977-01-01

    This paper presents an outline of a radiological emergency response training program conducted at Brookhaven National Laboratory by the health physics and safety training staff. This course is given to groups from local, county, state, and federal agencies and industrial organizations. It is normally three days in length, although the structure is flexible to accommodate individual needs and prior training. An important feature of the course is an emergency exercise utilizing a short lived radionuclide to better simulate real accident conditions. Groups are encouraged to use their own instruments to gain better familiarity with their operating characteristics under field conditions. Immediately following the exercise, a critical review of the students' performance is conducted

  7. Emerging applications of radiation-modified carrageenans

    Energy Technology Data Exchange (ETDEWEB)

    Abad, Lucille V., E-mail: lvabad@pnri.dost.gov.ph; Aranilla, Charito T.; Relleve, Lorna S.; Dela Rosa, Alumanda M.

    2014-10-01

    The Philippines supplies almost half of the world’s processed carrageenan as ingredient for different applications. In order to maintain the country’s competitive advantage, R and D on radiation processed carrageenan with various potential applications had been undertaken. PVP-carrageenan hydrogels for wound dressing had been developed. A carrageenan-based radiation dose indicator can detect radiation dose of as low as 5 kGy. Irradiated carrageenan has also been tested as plant growth promoter. Irradiated carrageenans have been found have been found to contain some antioxidant properties which increase with increasing dose and concentration. Carboxymethyl carrageenans had also been developed that shows promising effect as super water absorbent for soil conditioner in plants.

  8. Application of Robotic System for Emergency Response in NPP

    International Nuclear Information System (INIS)

    Jeong, Kyung Min; Seo, Yong Chil; Shin, Ho Chul; Lee, Sung Uk; Cho, Jae Wan; Choi, Young Soo; Kim, Chang Hoi; Kim, Seung Ho

    2010-01-01

    Increasing energy demand and concerns over climate change make increasing use of nuclear power plant in worldwide. Even though the probability of accident is greatly reduced, safety is the highest priority issue in the nuclear energy industry. Applying highly reliable and conservative 'defense in depth' concepts with the design and construction of NPP, there are very little possibilities with which accidents are occur and radioactive materials are released to environments in NPP. But NPP have prepared with the emergency response procedures and conduct exercises for post-accident circumstance according to the procedures. The application of robots for emergency response task for post-accident in nuclear facilities is not a new concept. Robots have been sent to recover the damaged reactor at Chernobyl where human workers could receive a lifetime dose of radiation in minutes. Based on NRC's TMI-2 Cleanup Program, several robots were built in the 1980s to help gather information and remove debris from a reactor at the Three Mile Island nuclear power plant that partially melted down in 1979. The first robot was lowered into the basement through a hatch and human operators monitoring in a control room drove it through mud, water and debris, capturing the initial post-accident images of the reactor's basement. It was used for several years equipped with various tools allowing it to scour surfaces, scoop samples and vacuum sludge. A second version carried a core sampler to determine the intensity and depth of the radiation that had permeated into the walls. To perform cleanup tasks, they built Workhorse that featured system redundancy and had a boom extendable to reach high places, but it was never used because it had too many complexities and to clean and fix. While remote robotics technology has proven to remove the human from the radioactive environment, it is also difficult to make it useful because it may requires skill about remote control and obtaining remote

  9. Application of Robotic System for Emergency Response in NPP

    Energy Technology Data Exchange (ETDEWEB)

    Jeong, Kyung Min; Seo, Yong Chil; Shin, Ho Chul; Lee, Sung Uk; Cho, Jae Wan; Choi, Young Soo; Kim, Chang Hoi; Kim, Seung Ho [Korea Atomic Energy Research Institute, Daejeon (Korea, Republic of)

    2010-10-15

    Increasing energy demand and concerns over climate change make increasing use of nuclear power plant in worldwide. Even though the probability of accident is greatly reduced, safety is the highest priority issue in the nuclear energy industry. Applying highly reliable and conservative 'defense in depth' concepts with the design and construction of NPP, there are very little possibilities with which accidents are occur and radioactive materials are released to environments in NPP. But NPP have prepared with the emergency response procedures and conduct exercises for post-accident circumstance according to the procedures. The application of robots for emergency response task for post-accident in nuclear facilities is not a new concept. Robots have been sent to recover the damaged reactor at Chernobyl where human workers could receive a lifetime dose of radiation in minutes. Based on NRC's TMI-2 Cleanup Program, several robots were built in the 1980s to help gather information and remove debris from a reactor at the Three Mile Island nuclear power plant that partially melted down in 1979. The first robot was lowered into the basement through a hatch and human operators monitoring in a control room drove it through mud, water and debris, capturing the initial post-accident images of the reactor's basement. It was used for several years equipped with various tools allowing it to scour surfaces, scoop samples and vacuum sludge. A second version carried a core sampler to determine the intensity and depth of the radiation that had permeated into the walls. To perform cleanup tasks, they built Workhorse that featured system redundancy and had a boom extendable to reach high places, but it was never used because it had too many complexities and to clean and fix. While remote robotics technology has proven to remove the human from the radioactive environment, it is also difficult to make it useful because it may requires skill about remote control and

  10. Severe deterministic effects of external exposure and intake of radioactive material: basis for emergency response criteria

    International Nuclear Information System (INIS)

    Kutkov, V; Buglova, E; McKenna, T

    2011-01-01

    Lessons learned from responses to past events have shown that more guidance is needed for the response to radiation emergencies (in this context, a 'radiation emergency' means the same as a 'nuclear or radiological emergency') which could lead to severe deterministic effects. The International Atomic Energy Agency (IAEA) requirements for preparedness and response for a radiation emergency, inter alia, require that arrangements shall be made to prevent, to a practicable extent, severe deterministic effects and to provide the appropriate specialised treatment for these effects. These requirements apply to all exposure pathways, both internal and external, and all reasonable scenarios, to include those resulting from malicious acts (e.g. dirty bombs). This paper briefly describes the approach used to develop the basis for emergency response criteria for protective actions to prevent severe deterministic effects in the case of external exposure and intake of radioactive material.

  11. Radiation monitoring strategy in nuclear or radiological emergencies

    International Nuclear Information System (INIS)

    Lahtinen, J.

    2003-01-01

    Full text: Radiation measurements provide indispensable data needed for the management of a nuclear or radiological emergency. There must exist pre-prepared emergency monitoring strategies, with accompanying procedures and methods, that help the authorities to perform measurements efficiently and, consequently, to evaluate the radiological situation correctly and to carry out proper countermeasures on time. However, defining a realistic yet comprehensive radiation monitoring strategy for emergencies is far from being an easy task. The very concept of 'emergency monitoring strategy' should be understood in a broad sense. In an ideal case, a strategy has interfaces with all related emergency and information exchange arrangements and agreements both at the national and international level. It covers all activities from the recognition of a potential hazard situation to environmental sampling performed during the late phases of an accident. It integrates routine-monitoring practices with the special requirements set by emergency monitoring and the use of fixed monitoring stations with that of mobile measurement teams. It includes elements for gathering, analyzing, transmitting and presenting data, as well as for combining them with different kinds of forecasts. It also takes into account the various intrinsic characteristics of possible threat scenarios and contains options for adapting measuring activities according to prevailing environmental conditions. Furthermore, a strategy must have relevant links to the social and economical realities and to the primary interests of different stakeholders. In order to assist individual countries in establishing national strategies, international organisations (IAEA, OECD/NEA, EU) have published basic guidelines for emergency response and radiation measurements. Nuclear accidents, especially the Chernobyl case with its large-scale environmental consequences, and other kinds of shocking events (like the one on September 11, 2001

  12. Emergency response in the Newfoundland offshore industry

    Energy Technology Data Exchange (ETDEWEB)

    Dempsey, J. [Cormorant Ltd., St. John' s, NL (Canada)

    2006-07-01

    This presentation reviewed current offshore oil activities with respect to safety issues regarding year-round marine operations in a harsh environment. Considerable logistics support is required for all offshore activities, including seismic and geotechnical surveys; exploration and production drilling; well testing; subsea construction; on-site production; and, delivery to market. Response to an offshore emergency must address the urgency of the incident along with stakeholder concerns. This presentation described the different types of emergencies and addressed issues regarding contingency planning; preventative measures; response philosophy; response scope; response at site; emergency management; communications links; and, oil spill response. The following current operations were highlighted: ExxonMobil's production drilling from the gravity-based concrete platform at Hibernia; Petro-Canada's production drilling at the Terra Nova FPSO; Husky Energy's production drilling at White Rose; and Chevron Canada's exploration drilling at the Orphan Basin. It was noted that in an emergency situation, the focus is on the welfare of offshore personnel. On an average day, the total offshore population is in the order of 1000 workers, all registered in the Personnel Logistics System which is updated with the departure of every helicopter from St. John's, Newfoundland or from the offshore platform. It is possible to prepare for foreseeable emergency incidents such as fire, explosion or gas leaks; spills to the marine environment; structural damage or collisions; persons lost at sea; helicopter or support vessel accidents; vessel sinking; sabotage; serious injuries or loss of life; severe ice events; and, loss of well control. The establishment of permanent safety zones at the Hibernia, White Rose and Terra Nova production fields are among the preventative measures, along with standby vessels that provide a rescue service for offshore installations

  13. Manual for first responders to a radiological emergency. Emergency preparedness and response. Publication date: June 2007

    International Nuclear Information System (INIS)

    2007-08-01

    Under Article 5.a(ii) of the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. As stated in IAEA Safety Standards Series No. GS-R-2 'Preparedness and Response for a Nuclear or Radiological Emergency', which establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, 'first responders shall take all practicable and appropriate actions to minimize the consequences of a nuclear or radiological emergency'. The IAEA General Conference, in resolution GC(49)/RES/9, continues to encourage Member States 'to adopt the relevant Agency standards, procedures and practical tools' and underlines 'the need for first responders to have appropriate training for dealing with ionizing radiation during nuclear and radiological emergencies'. This publication is intended to assist in meeting these requirements and to fulfil Article 5 of the Assistance Convention. Its aim is to provide practical guidance for those who will respond during the first few hours to a radiological emergency (referred to here as 'first responders') and for national officials who would support this early response. It provides guidance in the form of action guides, instructions, and supporting data that can be easily applied by a State to build a basic capability to respond to a radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This report, published as part of the IAEA Emergency Preparedness and Response Series, replaces and builds on IAEA-TECDOC-1162 in the area of early response and first responders' actions. It takes account of the

  14. Manual for first responders to a radiological emergency. Emergency preparedness and response. Publication date: October 2006

    International Nuclear Information System (INIS)

    2006-10-01

    Under Article 5.a(ii) of the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. As stated in IAEA Safety Standards Series No. GS-R-2 'Preparedness and Response for a Nuclear or Radiological Emergency', which establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, 'first responders shall take all practicable and appropriate actions to minimize the consequences of a nuclear or radiological emergency'. The IAEA General Conference, in resolution GC(49)/RES/9, continues to encourage Member States 'to adopt the relevant Agency standards, procedures and practical tools' and underlines 'the need for first responders to have appropriate training for dealing with ionizing radiation during nuclear and radiological emergencies'. This publication is intended to assist in meeting these requirements and to fulfil Article 5 of the Assistance Convention. Its aim is to provide practical guidance for those who will respond during the first few hours to a radiological emergency (referred to here as 'first responders') and for national officials who would support this early response. It provides guidance in the form of action guides, instructions, and supporting data that can be easily applied by a State to build a basic capability to respond to a radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This report, published as part of the IAEA Emergency Preparedness and Response Series, replaces and builds on IAEA-TECDOC-1162 in the area of early response and first responders' actions. It takes account of the

  15. Manual for first responders to a radiological emergency. Emergency preparedness and response

    International Nuclear Information System (INIS)

    2008-01-01

    Under Article 5.a(ii) of the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. As stated in IAEA Safety Standards Series No. GS-R-2 'Preparedness and Response for a Nuclear or Radiological Emergency', which establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, 'first responders shall take all practicable and appropriate actions to minimize the consequences of a nuclear or radiological emergency'. The IAEA General Conference, in resolution GC(49)/RES/9, continues to encourage Member States 'to adopt the relevant Agency standards, procedures and practical tools' and underlines 'the need for first responders to have appropriate training for dealing with ionizing radiation during nuclear and radiological emergencies'. This publication is intended to assist in meeting these requirements and to fulfil Article 5 of the Assistance Convention. Its aim is to provide practical guidance for those who will respond during the first few hours to a radiological emergency (referred to here as 'first responders') and for national officials who would support this early response. It provides guidance in the form of action guides, instructions, and supporting data that can be easily applied by a State to build a basic capability to respond to a radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This report, published as part of the IAEA Emergency Preparedness and Response Series, replaces and builds on IAEA-TECDOC-1162 in the area of early response and first responders' actions. It takes account of the

  16. Programmed cellular response to ionizing radiation damage

    International Nuclear Information System (INIS)

    Crompton, N.E.A.

    1998-01-01

    Three forms of radiation response were investigated to evaluate the hypothesis that cellular radiation response is the result of active molecular signaling and not simply a passive physicochemical process. The decision whether or not a cell should respond to radiation-induced damage either by induction of rescue systems, e.g. mobilization of repair proteins, or induction of suicide mechanisms, e.g. programmed cell death, appears to be the expression of intricate cellular biochemistry. A cell must recognize damage in its genetic material and then activate the appropriate responses. Cell type is important; the response of a fibroblast to radiation damage is both quantitatively and qualitatively different form that of a lymphocyte. The programmed component of radiation response is significant in radiation oncology and predicted to create unique opportunities for enhanced treatment success. (orig.)

  17. Generic Procedures for Medical Response During a Nuclear or Radiological Emergency

    International Nuclear Information System (INIS)

    2009-01-01

    The aim of this manual is to provide the medical community with practical guidance for medical emergency preparedness and response, describing the tasks and actions of different members of the national, regional or local medical infrastructure in accordance with international standards. This document provides generic response procedures for medical personnel responding to different types of radiation emergencies and at the different stages of the emergency response (at the scene of the emergency, pre-hospital, hospital), and during the early post-emergency stage (about 1-2 months afterwards).

  18. Emerging Radiation Health-Risk Mitigation Technologies

    International Nuclear Information System (INIS)

    Wilson, J.W.; Cucinotta, F.A.; Schimmerling, W.

    2004-01-01

    Past space missions beyond the confines of the Earth's protective magnetic field have been of short duration and protection from the effects of solar particle events was of primary concern. The extension of operational infrastructure beyond low-Earth orbit to enable routine access to more interesting regions of space will require protection from the hazards of the accumulated exposures of Galactic Cosmic Rays (GCR). There are significant challenges in providing protection from the long-duration exposure to GCR: the human risks to the exposures are highly uncertain and safety requirements places unreasonable demands in supplying sufficient shielding materials in the design. A vigorous approach to future radiation health-risk mitigation requires a triage of techniques (using biological and technical factors) and reduction of the uncertainty in radiation risk models. The present paper discusses the triage of factors for risk mitigation with associated materials issues and engineering design methods

  19. Emergency response packaging: A conceptual outline

    International Nuclear Information System (INIS)

    Luna, R.E.; McClure, J.D.; Bennett, P.C.; Wheeler, T.A.

    1992-01-01

    The Packaging and Transportation Needs in the 1990's (PATN) component of the Transportation Assessment and Integration (TRAIN) program (DOE Nov. 1991) was designed to survey United States Department of Energy programs, both ongoing and planned, to identify needs for packaging and transportation services over the next decade. PATN also identified transportation elements that should be developed by the DOE Office of Environmental Restoration and Waste Management (DOE EM) Transportation Management Program (TMP). As a result of the predominant involvement of the TMP in radioactive material shipment issues and DOE EM's involvement with waste management issues, the primary focus of PATN was on waste packaging issues. Pending DOE regulations will formalize federal guidelines and regulations for transportation of hazardous and radioactive materials within the boundaries of DOE reservations and facilities and reflect a growing awareness of concern regarding safety environmental responsibility activities on DOE reservations. Future practices involving the transportation of radioactive material within DOE reservations will closely parallel those used for commercial and governmental transportation across the United States. This has added to the perceived need for emergency recovery packaging and emergency response features on primary packaging, for both on-site shipments and shipments between DOE facilities (off-site). Historically, emergency response and recovery functions of packaging have not been adequately considered in packaging design and construction concepts. This paper develops the rationale for emergency response packaging, including both overpack concepts for repackaging compromised packaging and primary packaging redesign to facilitate the recovery of packages via mobile remote handling equipment. The rationale will examine concepts for determination of likely use patterns to identify types of shipments where recovery packaging may have the most favorable payoff

  20. PHMC post-NPH emergency response training

    International Nuclear Information System (INIS)

    Conrads, T.J.

    1997-01-01

    This document describes post-Natural Phenomena Hazard (NPH) emergency response training that was provided to two teams of Project Hanford Management Contractors (PHMC) staff that will be used to assess potential structural damage that may occur as a result of a significant natural phenomena event. This training supports recent plans and procedures to use trained staff to inspect structures following an NPH event on the Hanford Site

  1. CLASSIFICATION OF THE MGR EMERGENCY RESPONSE SYSTEM

    International Nuclear Information System (INIS)

    Zeigler, J.A.

    1999-01-01

    The purpose of this analysis is to document the Quality Assurance (QA) classification of the Monitored Geologic Repository (MGR) emergency response system structures, systems and components (SSCs) performed by the MGR Safety Assurance Department. This analysis also provides the basis for revision of YMP/90-55Q, Q-List (YMP 1998). The Q-List identifies those MGR SSCs subject to the requirements of DOE/RW-0333P7 ''Quality Assurance Requirements and Description'' (QARD) (DOE 1998)

  2. Responsibility modelling for civil emergency planning

    OpenAIRE

    Sommerville, Ian; Storer, Timothy; Lock, Russell

    2009-01-01

    This paper presents a new approach to analysing and understanding civil emergency planning based on the notion of responsibility modelling combined with HAZOPS-style analysis of information requirements. Our goal is to represent complex contingency plans so that they can be more readily understood, so that inconsistencies can be highlighted and vulnerabilities discovered. In this paper, we outline the framework for contingency planning in the United Kingdom and introduce the notion of respons...

  3. PHMC post-NPH emergency response training

    Energy Technology Data Exchange (ETDEWEB)

    Conrads, T.J.

    1997-04-08

    This document describes post-Natural Phenomena Hazard (NPH) emergency response training that was provided to two teams of Project Hanford Management Contractors (PHMC) staff that will be used to assess potential structural damage that may occur as a result of a significant natural phenomena event. This training supports recent plans and procedures to use trained staff to inspect structures following an NPH event on the Hanford Site.

  4. Report on emergency exposure to external radiation

    International Nuclear Information System (INIS)

    Pochin, E.E.; Rock Carling, Ernest; Court Brown, W.M.

    1960-01-01

    The Medical Research Council has continued a study of the effects on the health of persons in the neighbourhood of atomic energy installations should there be a release of radioactive material as a result of fires or other incidents. The Council's Committee on Protection against Ionizing Radiations has already reported (Medical Research Council, 1959) on the maximum permissible dietary contamination for iodine 131, strontium 89, strontium 90 and caesium. 137, since it was considered that for the members of the public normally resident in the area affected ingestion of contaminated food would generally be the limiting source of hazard after any such accident and that intake by inhalation, or radiation from the exterior, would become of importance only in rather special circumstances The present report deals with the problem of exposure from the exterior, namely, from external sources of beta and gamma radiation. This exposure might be derived from two sources, one of relatively short duration from the passage of a cloud of radioactive material, the other of longer duration from deposited material

  5. Report on emergency exposure to external radiation

    Energy Technology Data Exchange (ETDEWEB)

    Pochin, E E; Rock Carling, Ernest; Court Brown, W M [Medical Research Council, Committee on Protection against Ionizing Radiations, London (United Kingdom); and others

    1960-12-01

    The Medical Research Council has continued a study of the effects on the health of persons in the neighbourhood of atomic energy installations should there be a release of radioactive material as a result of fires or other incidents. The Council's Committee on Protection against Ionizing Radiations has already reported (Medical Research Council, 1959) on the maximum permissible dietary contamination for iodine 131, strontium 89, strontium 90 and caesium. 137, since it was considered that for the members of the public normally resident in the area affected ingestion of contaminated food would generally be the limiting source of hazard after any such accident and that intake by inhalation, or radiation from the exterior, would become of importance only in rather special circumstances The present report deals with the problem of exposure from the exterior, namely, from external sources of beta and gamma radiation. This exposure might be derived from two sources, one of relatively short duration from the passage of a cloud of radioactive material, the other of longer duration from deposited material.

  6. Vehicle tracking based technique for radiation monitoring during nuclear or radiological emergency

    International Nuclear Information System (INIS)

    Saindane, Shashank S.; Otari, Anil D.; Suri, M.M.K.; Patil, S.S.; Pradeepkumar, K.S.; Sharma, D.N.

    2010-01-01

    Radiation Safety Systems Division, BARC has developed an advanced online radiation measurement cum vehicle tracking system for use. For the preparedness for response to any nuclear/radiological emergency scenario which may occur anywhere, the system designed is a Global System for Mobile (GSM) based Radiation Monitoring System (GRaMS) along with a Global Positioning System (GPS). It uses an energy compensated GM detector for radiation monitoring and is attached with commercially available Global Positioning System (GPS) for online acquisition of positional coordinates with time, and GSM modem for online data transfer to a remote control centre. The equipment can be operated continuously while the vehicle is moving

  7. How the Nuclear Applications Laboratories Help in Strengthening Emergency Response

    International Nuclear Information System (INIS)

    2014-01-01

    Safety is one of the most important considerations when engaging in highly advanced scientific and technological activities. In this respect, utilizing the potential of nuclear technology for peaceful purposes also involves risks, and nuclear techniques themselves can be useful in strengthening emergency response measures related to the use of nuclear technology. In the case of a nuclear incident, the rapid measurement and subsequent monitoring of radiation levels are top priorities as they help to determine the degree of risk faced by emergency responders and the general public. Instruments for the remote measurement of radioactivity are particularly important when there are potential health risks associated with entering areas with elevated radiation levels. The Nuclear Science and Instrumentation Laboratory (NSIL) — one of the eight laboratories of the Department of Nuclear Sciences and Applications (NA) in Seibersdorf, Austria — focuses on developing a variety of specialized analytical and diagnostic instruments and methods, and transferring knowledge to IAEA Member States. These include instruments capable of carrying out remote measurements. This emergency response work carried out by the NA laboratories supports health and safety in Member States and supports the IAEA’s mandate to promote the safe and peaceful use of nuclear energy

  8. United States Department of Energy radiological emergency response programme - a national capability

    International Nuclear Information System (INIS)

    Gordon-Hagerty, L.E.

    1993-01-01

    In order to respond to a radiological emergency, the United States Department of Energy (USDOE) maintains seven emergency response assets and capabilities in support of a radiological emergency of any proportion within the continental United States and abroad. The seven emergency response assets and capabilities include: Accident Response Group; Aerial Measuring Systems; Atmospheric Release Advisory Capability; Federal Radiological Monitoring and Assessment Center; Nuclear Emergency Search Team; Radiation Emergency Assistance Center/Training Site; and Radiological Assistance Program. Presently, USDOE maintains the most comprehensive national radiological emergency response assets in the United States, capable of dealing with any type of emergency involving nuclear materials. In all, the Department's assets are available to support any type of accident/incident involving radioactive materials in coordination with other United States Federal agencies, as well as state and local governments, as required. (author)

  9. Research on environment monitoring of radiation emergency

    CERN Document Server

    Ito, Y; Otani, N

    2003-01-01

    In a case of a nuclear accident at nuclear facilities, strong radiation such as g-rays and neutrons might radiate at a burst in the initial stage. For the establishment of dose estimation system for such accidents, the experiments were done using the He sup + sup 2 beam accelerated by Tandem in the W-MAST. The following results were obtained. 1) Neutron measurements using a rem counter yielded that dose equivalent was about 9.4 mSv/h at a position 100 cm from the Be target when the beam current of 15 MeV He sup 2 sup + was 0.8 mu A. Neutron measurement by means of Au and In foil activation method and by use of TLD element revealed that dose equivalents were to be 16-27 mu Sv/h for thermal neutron, and 30-41 mu Sv/h for sub-fast neutron (20 keV). Therefore, it was concluded that neutron field was mainly composed by fast neutron. 2) Linearity of the rem-counter out put vs neutron flux was valid under the condition that the count rate of the rem-counter was less than 10 kcps. 3) Computer simulation using NRESP c...

  10. Research on environment monitoring of radiation emergency

    CERN Document Server

    Ito, Y

    2002-01-01

    In a case of a nuclear accident at nuclear facilities, radiation such as gamma-rays and neutrons might radiate at a burst in the initial stage. For the establishment of dose estimation system for such accidents, the experiments were carried out using the Tandem/Synchrotron accelerator. The following results were obtained: (1) Measurements of the gamma-ray emission using the NaI detector together with pile up rejection system revealed that the good signals without the pile up phenomena could be obtained in case of count rate less than 7 kc/s. On assumption that energy distribution function of the gamma-rays was proportional to be E exp(- E/T sub e sub f sub f), the effective temperature T sub e sub f sub f was estimated to be 0.8 - 0.9 MeV by use of non-linear least squares. (2) Doses of gamma-rays were measured using the TLD elements shielded by Pb sheets with various widths. The effective temperature T sub e sub f sub f estimated under the same experimental conditions described in (1) was 0.6-3 MeV. In an ac...

  11. Multibiodose radiation emergency triage categorization software.

    Science.gov (United States)

    Ainsbury, Elizabeth A; Barnard, Stephen; Barrios, Lleonard; Fattibene, Paola; de Gelder, Virginie; Gregoire, Eric; Lindholm, Carita; Lloyd, David; Nergaard, Inger; Rothkamm, Kai; Romm, Horst; Scherthan, Harry; Thierens, Hubert; Vandevoorde, Charlot; Woda, Clemens; Wojcik, Andrzej

    2014-07-01

    In this note, the authors describe the MULTIBIODOSE software, which has been created as part of the MULTIBIODOSE project. The software enables doses estimated by networks of laboratories, using up to five retrospective (biological and physical) assays, to be combined to give a single estimate of triage category for each individual potentially exposed to ionizing radiation in a large scale radiation accident or incident. The MULTIBIODOSE software has been created in Java. The usage of the software is based on the MULTIBIODOSE Guidance: the program creates a link to a single SQLite database for each incident, and the database is administered by the lead laboratory. The software has been tested with Java runtime environment 6 and 7 on a number of different Windows, Mac, and Linux systems, using data from a recent intercomparison exercise. The Java program MULTIBIODOSE_1.0.jar is freely available to download from http://www.multibiodose.eu/software or by contacting the software administrator: MULTIBIODOSE-software@gmx.com.

  12. An emergency response centre (ERC) for the preparedness and response to nuclear and radiological emergencies

    International Nuclear Information System (INIS)

    Pradeepkumar, K.S.; Sharma, D.N.; Abani, M.C.

    2001-01-01

    This paper discusses the requirement for a state of the art Emergency Response Centre (ERC) to be developed and kept in readiness for the quick response to any nuclear or radiological emergencies. For an effective response to any major nuclear emergency an ERC having the facilities of i) environmental dose rate monitoring network established using both mobile and fixed units ii) on-line meteorological data collection and information station iii) on-line computation and prediction of isodose curves in real time and iv) properly developed and tested monitoring methodologies are essential. Vehicles with on-line data transfer facility to the ERC and equipped with different type of monitoring systems can function as Mobile Monitoring Laboratories (MMLs) and can help in quick decision making even during a radiological emergency far away from the ERC. (author)

  13. Radiation hygiene of animal production in normal and emergency situations

    International Nuclear Information System (INIS)

    Stajicj, J.; Petrovicj, B.; Draganovicj, B.

    1977-01-01

    Radiation hazards imposed by contemporary development and peaceful and military uses of nuclear energy have implied the introduction of radiational control in animal production, and radiation-hygienic expertize of animal products and animal foodstuffs. Various treatments in scientific research, education and uses of relevant equipment, undertaken in right time, enabled our Veterinary services to start successfully to solve problems of radiation control and protection of animal production in normal and emergency situations. An important role in this context has the Section of Radiation Hygiene Yugoslav Veterinary Association, as an initiator of many activities that are intended to affirme Radiation Hygiene in the domain of scientific research and in the field of national defence and self-protection

  14. Emergency Response Data System (ERDS) implementation

    International Nuclear Information System (INIS)

    Jolicoeur, J.

    1990-04-01

    The US Nuclear Regulatory Commission has begun implementation of the Emergency Response Data System (ERDS) to upgrade its ability to acquire data from nuclear power plants in the event of an emergency at the plant. ERDS provides a direct real-time transfer of data from licensee plant computers to the NRC Operations Center. The system has been designed to be activated by the licensee during an emergency which has been classified at an ALERT or higher level. The NRC portion of ERDS will receive the data stream, sort and file the data. The users will include the NRC Operations Center, the NRC Regional Office of the affected plant, and if requested the States which are within the ten mile EPZ of the site. The currently installed Emergency Notification System will be used to supplement ERDS data. This report provides the minimum guidance for implementation of ERDS at licensee sites. It is intended to be used for planning implementation under the current voluntary program as well as for providing the minimum standards for implementing the proposed ERDS rule

  15. Emergency Response Data System (ERDS) implementation

    International Nuclear Information System (INIS)

    Jolicoeur, J.

    1991-06-01

    The US Nuclear Regulatory Commission has begun implementation of the Emergency Response Data System (ERDS) to upgrade its ability to acquire data from nuclear power plants in the event of an emergency at the plant. ERDS provides a direct real-time transfer of data from licensee plant computers to the NRC Operations Center. The system has been designed to be activated by the licensee during an emergency which has been classified at an ALERT or higher level. The NRC portion of ERDS will receive the data stream, sort and file the data. The users will include the NRC Operations Center, the NRC Regional Office of the affected plant, and if requested the States which are within the ten mile EPZ of the site. The currently installed Emergency Notification System will be used to supplement ERDS data. This report provides the minimum guidance for implementation of ERDS at licensee sites. It is intended to be used for planning implementation under the current voluntary program as well as for providing the minimum standards for implementing the proposed ERDS rule. 4 refs., 3 figs

  16. Chemical toxicity approach for emergency response

    International Nuclear Information System (INIS)

    Bauer, T.

    2009-01-01

    In the event of an airborne release of chemical agent or toxic industrial chemical by accidental or intentional means, emergency responders must have a reasonable estimate of the location and size of the resulting hazard area. Emergency responders are responsible for warning persons downwind of the hazard to evacuate or shelter-in-place and must know where to look for casualties after the hazard has passed or dissipated. Given the same source characterization, modern hazard assessment models provide comparable concentration versus location and time estimates. Even urban hazard assessment models often provide similar predictions. There is a major shortcoming, though, in applying model output to estimating human toxicity effects. There exist a variety of toxicity values for non-lethal effects ranging from short-term to occupational to lifetime exposures. For health and safety purposes, these estimates are all safe-sided in converting animal data to human effects and in addressing the most sensitive subset of the population. In addition, these values are usually based on an assumed 1 hour exposure duration at constant concentration and do not reflect either a passing clouds concentration profile or duration. Emergency responders need expected value toxicity parameters rather than the existing safe-sided ones. This presentation will specify the types of toxicity values needed to provide appropriate chemical hazard estimates to emergency responders and will demonstrate how dramatically their use changes the hazard area.(author)

  17. Global approach of emergency response, reflection analysis

    International Nuclear Information System (INIS)

    Velasco Garcia, E.; Garcia Ahumada, F.; Albaladejo Vidal, S.

    1998-01-01

    The emergency response management approach must be dealt with adequately within company strategy, since a badly managed emergency situation can adversely affect a company, not only in terms of asset, but also in terms of the negative impact on its credibility, profitability and image. Thereby, it can be said that there are three main supports to manage the response in an emergency situation. a) Diagnosis b) Prognosis. c) Communications. To reach these capabilities it is necessary a co-ordination of different actions at the following levels. i. Facility Operation implies Local level. ii. Facility Property implies National level iii. Local Authority implies Local level iv. National Authority implies National level Taking into account all the last, these following functions must be covered: a) Management: incorporating communication, diagnosis and prognosis areas. b) Decision: incorporating communication and information means. c) Services: in order to facilitate the decision, as well as the execution of this decision. d) Analysis: in order to facilitate the situations that make easier to decide. e) Documentation: to seek the information for the analysts and decision makers. (Author)

  18. The research reactor radiation emergency countermeasure system in Korea

    International Nuclear Information System (INIS)

    Kim, Hee Reyoung; Choi, Geun-Sik; Lee, Wanno; Chung, Kun Ho; Kang, Mun Ja; Lee, Chang-Woo

    2010-01-01

    A disaster prevention system was established for a radiation emergency from an operation of a research reactor with a thermal power of 30 MW th in Korea. A national radiation disaster countermeasure organization was set up to cope with the radiation emergency classified into three cases whose effective doses were more than 1 mSv/h inside the nuclear facility, inside the site boundary and outside the site boundary. Its role consists of the proclamation and consequent withdrawal of a disaster, a general assessment, an emergency medical service, a field control, radiation protection, resident protection implement, an accident analysis, a security plan, a radiation environmental investigation plan and probe, a radiation environmental effect assessment, and others. The emergency planning zone (EPZ) was settled to be within a radius of 800 m, the average distance between the site boundary and the center of a research reactor in operation, as a quick and effective early countermeasure from the result of the radiation environmental effect assessment. The environmental probing zone was chosen to extend to a radius of 2 km from a research reactor according to the moving path of the radioactive cloud so that a densely populated area could be considered and would be extended to 10 km according to the radiation level of the research reactor and atmospheric diffusion. Practically, the environmental probing is implemented at 22 points inside the site and eight points outside the site considering the geography, population and the wind direction. The gamma radiation dose and atmospheric radioactivity are analyzed during an effluence, and the radioactivity of a ground surface deposit and an environmental sample are analyzed after an effluence. The environmental laboratory covers the analysis of the gamma radioisotopes, tritium, strontium, uranium, gross alpha and beta. It is estimated that the habitability can be recovered when the radiation dose rate is less than 1 mSv/h inside the

  19. NNSA/NV Consequence Management Capabilities for Radiological Emergency Response

    International Nuclear Information System (INIS)

    Bowman, D. R.

    2002-01-01

    The U.S. Department of Energy's National Nuclear Security Administration Nevada Operations Office (NNSA/NV) provides an integrated Consequence Management (CM) response capability for the (NNSA) in the event of a radiological emergency. This encompasses planning, technical operations, and home team support. As the lead organization for CM planning and operations, NNSA/NV coordinates the response of the following assets during the planning and operational phases of a radiological accident or incident: (1) Predictive dispersion modeling through the Atmospheric Release Advisory Capability (ARAC) at Lawrence Livermore National Laboratory (LLNL) and the High Consequence Assessment Group at Sandia National Laboratories (SNL); (2) Regional radiological emergency assistance through the eight Radiological Assistance Program (RAP) regional response centers; (3) Medical advice and assistance through the Radiation Emergency Assistance Center/Training Site (REAC/TS) in Oak Ridge, Tennessee; (4) Aerial radiological mapping using the fixed-wing and rotor-wing aircraft of the Aerial Measuring System (AMS); (5) Consequence Management Planning Teams (CMPT) and Consequence Management Response Teams (CMRT) to provide CM field operations and command and control. Descriptions of the technical capabilities employed during planning and operations are given below for each of the elements comprising the integrated CM capability

  20. Planning and Preparing for Emergency Response to Transport Accidents Involving Radioactive Material. Safety Guide

    International Nuclear Information System (INIS)

    2009-01-01

    This Safety Guide provides guidance on various aspects of emergency planning and preparedness for dealing effectively and safely with transport accidents involving radioactive material, including the assignment of responsibilities. It reflects the requirements specified in Safety Standards Series No. TS-R-1, Regulations for the Safe Transport of Radioactive Material, and those of Safety Series No. 115, International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources. Contents: 1. Introduction; 2. Framework for planning and preparing for response to accidents in the transport of radioactive material; 3. Responsibilities for planning and preparing for response to accidents in the transport of radioactive material; 4. Planning for response to accidents in the transport of radioactive material; 5. Preparing for response to accidents in the transport of radioactive material; Appendix I: Features of the transport regulations influencing emergency response to transport accidents; Appendix II: Preliminary emergency response reference matrix; Appendix III: Guide to suitable instrumentation; Appendix IV: Overview of emergency management for a transport accident involving radioactive material; Appendix V: Examples of response to transport accidents; Appendix VI: Example equipment kit for a radiation protection team; Annex I: Example of guidance on emergency response to carriers; Annex II: Emergency response guide.

  1. Radiation Detection Overview for Nuclear Emergency Response

    Energy Technology Data Exchange (ETDEWEB)

    Myers, Steven Charles [Los Alamos National Lab. (LANL), Los Alamos, NM (United States)

    2016-11-16

    This presentation discusses the fundamentals of gamma and neutron detection; presents an overview of the DOE Triage and JTOT Programs, gamma, and neutron signatures in select measurements; and offers a detector demonstration.

  2. IAEA emergency response network ERNET. Emergency preparedness and response. Date effective: 1 December 2002

    International Nuclear Information System (INIS)

    2003-04-01

    The Parties to the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency have undertaken to co-operate among themselves and with the IAEA in facilitating the prompt provision of assistance in the event of a nuclear accident or radiological emergency, and in minimizing the consequences and in protecting life, property and the environment from the effects of any radioactive releases. As part of the IAEA strategy for supporting such co-operation, the Secretariat of the IAEA is establishing a global Emergency Response Network (ERNET) of teams suitably qualified to respond rapidly, on a regional basis, to nuclear accidents or radiological emergencies. This manual sets out the criteria and requirements to be met by ERNET teams. It is intended for use by institutions in Member States in developing, applying and maintaining their emergency response capabilities and in implementing quality assurance programmes within the context of ERNET. The manual is worded on the assumption that a State Competent Authority designated as the body responsible for reacting to nuclear accidents or radiological emergencies which occur outside the jurisdiction of that State will be the State Contact Point for receiving requests for assistance from the IAEA under the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency

  3. IAEA emergency response network ERNET. Emergency preparedness and response. Date effective: 1 December 2000

    International Nuclear Information System (INIS)

    2000-12-01

    The Parties to the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency have undertaken to co-operate among themselves and with the IAEA in facilitating the prompt provision of assistance in the event of a nuclear accident or radiological emergency, and in minimizing the consequences and in protecting life, property and the environment from the effects of any radioactive releases. As part of the IAEA strategy for supporting such co-operation, the Secretariat of the IAEA is establishing a global Emergency Response Network (ERNET) of teams suitably qualified to respond rapidly, on a regional basis, to nuclear accidents or radiological emergencies. This manual sets out the criteria and requirements to be met by ERNET teams. It is intended for use by institutions in Member States in developing, applying and maintaining their emergency response capabilities and in implementing quality assurance programmes within the context of ERNET. The manual is worded on the assumption that a State Competent Authority designated as the body responsible for reacting to nuclear accidents or radiological emergencies which occur outside the jurisdiction of that State will be the State Contact Point for receiving requests for assistance from the IAEA under the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency

  4. Selection and construction of nuclear and radiation emergency medical center in a region

    International Nuclear Information System (INIS)

    Wang Guojun; He Xu; Liao Li; Gao Dong

    2014-01-01

    Three level of first-class comprehensive hospital is an important force of nuclear and radiation accident rescue, has a very rich experience in response to nuclear and radiation accidents and deal with large quantities of the sick and wounded. With the foundation and the ability of the construction and operation of medical emergency rescue center. This paper according to the median model location theory of emergency center, combined with the specific situation of the nuclear and radiation accident in Hunan Province, reference location, rescue experience, emergency allocation of resources, teaching and research capacity, establish regional medical emergency center of nuclear and radiation accidents based on three level of first-class comprehensive hospital, break the traditional concept that the center must be provincial capital,form a multi-level, three-dimensional, network of emergency hospital rescue system. The main duties of the center are accident emergency response, on-site treatment and technical guidance of accident, psychological grooming. The author propose building measures according to the duties of the center: increase national and provincial financial investment, carry out training, drills and first aid knowledge missionaries regularly, innovative materials management, speed up the construction of information platform, establish and improve the hospital rescue system, improve organization institution and system of plans, reengineering rescue process. (authors)

  5. Radiation and radionuclide monitoring during emergencies

    International Nuclear Information System (INIS)

    Wilkins, B.T.; Clark, M.J.

    1988-01-01

    One of the major impacts of the Chernobyl accident has been increased interest in the measurement of radionuclides in the environment. The capability to detect and respond to the arrival of a plume of radioactive material promptly, is under review by governments in many countries. Furthermore, many organizations who previously had little or no involvement in radiation now perceive a need to contribute to the monitoring effort after any future accident. Consequently, facilities set up to collate measurement data and assess the implications of an accident could be deluged with information from a very large number of laboratories. Ideally, such a facility should not have to assess the quality of the data as it is received, whereas after Chernobyl, some of the data generated were inappropriate and created additional and unnecessary pressure. One major lesson of the accident was that contingency monitoring should be well planned, and measurement and sampling protocols agreed beforehand. In the UK, the Government has announced the creation of a new, countrywide, accident detection system which, in the first phase is likely to be based on continual measurement of external dose rate with large, energy compensated, Geiger-Mueller detectors. Many other organizations, especially local government, intend to purchase similar equipment and, after obtaining authorization from central government, will be able to transmit their data to a centralized data base facility. The equipment required for these measurements is relatively cheap, compact and robust, and is likely to find widespread use. 2 refs., 1 fig

  6. Prototyping and validating requirements of radiation and nuclear emergency plan simulator

    Energy Technology Data Exchange (ETDEWEB)

    Hamid, AHA., E-mail: amyhamijah@nm.gov.my [Malaysian Nuclear Agency (NM), Bangi, 43000 Kajang, Selangor (Malaysia); Faculty of Computing, Universiti Teknologi Malaysia (UTM), Skudai, 81310 Johor Bahru, Johor (Malaysia); Rozan, MZA.; Ibrahim, R.; Deris, S.; Selamat, A. [Faculty of Computing, Universiti Teknologi Malaysia (UTM), Skudai, 81310 Johor Bahru, Johor (Malaysia)

    2015-04-29

    Organizational incapability in developing unrealistic, impractical, inadequate and ambiguous mechanisms of radiological and nuclear emergency preparedness and response plan (EPR) causing emergency plan disorder and severe disasters. These situations resulting from 65.6% of poor definition and unidentified roles and duties of the disaster coordinator. Those unexpected conditions brought huge aftermath to the first responders, operators, workers, patients and community at large. Hence, in this report, we discuss prototyping and validating of Malaysia radiation and nuclear emergency preparedness and response plan simulation model (EPRM). A prototyping technique was required to formalize the simulation model requirements. Prototyping as systems requirements validation was carried on to endorse the correctness of the model itself against the stakeholder’s intensions in resolving those organizational incapability. We have made assumptions for the proposed emergency preparedness and response model (EPRM) through the simulation software. Those assumptions provided a twofold of expected mechanisms, planning and handling of the respective emergency plan as well as in bringing off the hazard involved. This model called RANEPF (Radiation and Nuclear Emergency Planning Framework) simulator demonstrated the training emergency response perquisites rather than the intervention principles alone. The demonstrations involved the determination of the casualties’ absorbed dose range screening and the coordination of the capacity planning of the expected trauma triage. Through user-centred design and sociotechnical approach, RANEPF simulator was strategized and simplified, though certainly it is equally complex.

  7. Prototyping and validating requirements of radiation and nuclear emergency plan simulator

    International Nuclear Information System (INIS)

    Hamid, AHA.; Rozan, MZA.; Ibrahim, R.; Deris, S.; Selamat, A.

    2015-01-01

    Organizational incapability in developing unrealistic, impractical, inadequate and ambiguous mechanisms of radiological and nuclear emergency preparedness and response plan (EPR) causing emergency plan disorder and severe disasters. These situations resulting from 65.6% of poor definition and unidentified roles and duties of the disaster coordinator. Those unexpected conditions brought huge aftermath to the first responders, operators, workers, patients and community at large. Hence, in this report, we discuss prototyping and validating of Malaysia radiation and nuclear emergency preparedness and response plan simulation model (EPRM). A prototyping technique was required to formalize the simulation model requirements. Prototyping as systems requirements validation was carried on to endorse the correctness of the model itself against the stakeholder’s intensions in resolving those organizational incapability. We have made assumptions for the proposed emergency preparedness and response model (EPRM) through the simulation software. Those assumptions provided a twofold of expected mechanisms, planning and handling of the respective emergency plan as well as in bringing off the hazard involved. This model called RANEPF (Radiation and Nuclear Emergency Planning Framework) simulator demonstrated the training emergency response perquisites rather than the intervention principles alone. The demonstrations involved the determination of the casualties’ absorbed dose range screening and the coordination of the capacity planning of the expected trauma triage. Through user-centred design and sociotechnical approach, RANEPF simulator was strategized and simplified, though certainly it is equally complex

  8. Prototyping and validating requirements of radiation and nuclear emergency plan simulator

    Science.gov (United States)

    Hamid, AHA.; Rozan, MZA.; Ibrahim, R.; Deris, S.; Selamat, A.

    2015-04-01

    Organizational incapability in developing unrealistic, impractical, inadequate and ambiguous mechanisms of radiological and nuclear emergency preparedness and response plan (EPR) causing emergency plan disorder and severe disasters. These situations resulting from 65.6% of poor definition and unidentified roles and duties of the disaster coordinator. Those unexpected conditions brought huge aftermath to the first responders, operators, workers, patients and community at large. Hence, in this report, we discuss prototyping and validating of Malaysia radiation and nuclear emergency preparedness and response plan simulation model (EPRM). A prototyping technique was required to formalize the simulation model requirements. Prototyping as systems requirements validation was carried on to endorse the correctness of the model itself against the stakeholder's intensions in resolving those organizational incapability. We have made assumptions for the proposed emergency preparedness and response model (EPRM) through the simulation software. Those assumptions provided a twofold of expected mechanisms, planning and handling of the respective emergency plan as well as in bringing off the hazard involved. This model called RANEPF (Radiation and Nuclear Emergency Planning Framework) simulator demonstrated the training emergency response perquisites rather than the intervention principles alone. The demonstrations involved the determination of the casualties' absorbed dose range screening and the coordination of the capacity planning of the expected trauma triage. Through user-centred design and sociotechnical approach, RANEPF simulator was strategized and simplified, though certainly it is equally complex.

  9. Emergency reception of accidents and incidents in working with ionizing radiation

    International Nuclear Information System (INIS)

    Abrahamse, J.C.; Gispen, J.G.W.

    1989-01-01

    This manual is intended to be a general manual for the responsible expert regarding radiation hygienics in order to assist him in establishing an organization for combat of accidents and incidents. First attention is paid considerations underlying emergency measures and aid, subsequently the demands and desirabilities in the practical organization are discussed. (author). 3 figs

  10. Distinguishing human responses to radiological emergencies

    International Nuclear Information System (INIS)

    Johnson, J.H. Jr.; Ziegler, D.J.

    1983-01-01

    Inherent in the revised emergency planning regulations recently issued by the federal government is the assumption that people will follow official protective action advisories during a nuclear reactor accident. In this paper the authors argue that this is an unrealistic assumption and present empirical evidence which supports the proposition that a radiological emergency in likely to give rise to a high degree of extreme public behavior. Their analyses indicate that less than one-third of the households on Long Island are likely to follow instructions in the event of an accident at the Shoreham Nuclear Power Station. Among the families who would not follow instructions, some would underreact but most would overreact. Perceived distance from the plant and age of household head appear to be the strongest discriminators among those who are most likely to follow orders, those most likely to underreact, and those most likely to overreact. Implications for radiological emergency preparedness and response planning are discussed. 71 references, 3 figures, 8 tables

  11. Intervention in emergency situations involving radiation exposure (1990)

    International Nuclear Information System (INIS)

    1992-01-01

    This document covers radiation protection aspects arising in emergency situations. It does not cover the measures necessary to reduce the health consequences of radiation exposure, i.e. the medical care of exposed individuals, nor does it cover psychological problems arising from the exposure of individuals or of a population. These problems may arise from anxiety about possible late effects of radiation exposure and from any actions implemented to reduce exposure. Even though radiation exposure levels may be low and insignificant, these problems must be taken into account in determining any action to be implemented to reduce radiation exposure. The primary concern of this document is with exposure in areas which are close to the source and in the period immediately after a source is out of control. It outlines the principles which can be used for planning and implementing countermeasures for protection of the public. 24 refs., 13 tabs

  12. Further studies into the emergency medical care of radiation accidents

    International Nuclear Information System (INIS)

    Nakao, Isamu

    1989-01-01

    The emergency medical care of radiation accidents constitute a peculier characteristics of radiation protection including the works of the administrative management, environmental radiological monitoring and health physics around the clinical medicine. It is thought to be an interdisciplinary medical field which is designated as a comprehensive medicine for radiation hazard. Moreover, it will be thought that the radiological medicine is not only the medical science which deals with the use of radiant energy in the diagnosis and treatment of disease, but also the art and science of maintenance of health and cure for radiation injuries, just as the two wheels of a cart. It should reward the needs of today. We would like to expect that this symposium will be a clue to the theoretical systematization of the comprehensive medicine of radiation accidents. (author)

  13. Development of supporting system for emergency response to maritime transport accidents involving radioactive material

    International Nuclear Information System (INIS)

    Odano, N.; Matsuoka, T.; Suzuki, H.

    2004-01-01

    National Maritime Research Institute has developed a supporting system for emergency response of competent authority to maritime transport accidents involving radioactive material. The supporting system for emergency response has functions of radiation shielding calculation, marine diffusion simulation, air diffusion simulation and radiological impact evaluation to grasp potential hazard of radiation. Loss of shielding performance accident and loss of sealing ability accident were postulated and impact of the accidents was evaluated based on the postulated accident scenario. Procedures for responding to emergency were examined by the present simulation results

  14. Contraceptive availability during an emergency response in the United States.

    Science.gov (United States)

    Ellington, Sascha R; Kourtis, Athena P; Curtis, Kathryn M; Tepper, Naomi; Gorman, Susan; Jamieson, Denise J; Zotti, Marianne; Barfield, Wanda

    2013-03-01

    This article provides the evidence for contraceptive need to prevent unintended pregnancy during an emergency response, discusses the most appropriate types of contraceptives for disaster situations, and details the current provisions in place to provide contraceptives during an emergency response.

  15. Radiation safety for the emergency situation of the power plant accident. Radiation safety in society and its education

    International Nuclear Information System (INIS)

    Kosako, Toshiso

    2012-01-01

    Great East Japan Earthquake and Tsunamis, and following Fukushima Daiichi Nuclear Power Accident brought about great impact on society in Japan. Accident analysis of inside reactor was studied by reactor physics or reactor engineering knowledge, while dissipation of a large amount of radioactive materials outside reactor facilities, and radiation and radioactivity effects on people by way of atmosphere, water and soil were dealt with radiation safety or radiation protection. Due to extremely low frequency and experience of an emergency, there occurred a great confusion in the response of electric power company concerned, relevant regulating competent authorities, local government and media, and related scholars and researchers, which caused great anxieties amount affected residents and people. This article described radiation safety in the society and its education. Referring to actual examples, how radiation safety or radiation protection knowledge should be dealt with emergency risk management in the society was discussed as well as problem of education related with nuclear power, radiation and prevention of disaster and fostering of personnel for relevant people. (T. Tanaka)

  16. The current situation and future scope of radiation emergency medical care network in Nagasaki

    International Nuclear Information System (INIS)

    Morishita, Mariko; Namba, Hiroyuki; Yamashita, Shunichi; Ohtsuru, Akira

    2005-01-01

    Under the framework of the International Consortium for Medical Care of Hibakusha and Radiation Life Science (Nagasaki University 21st Century COE Program) and bearing in mind the unique history and responsibility of Nagasaki University, several projects on radiation emergency preparedness are in progress. The critical accident in Tokaimura, Japan in 1999 made us realize that nuclear emergencies happen anywhere radionuclides exist. In fact, nuclear accidents possibly take place in factories, research facilities, hospital and wherever radioactive materials are in transit. Therefore, it is necessary to establish an effective preparedness network system for potential radiation emergency that may occur in Nagasaki and nearby prefectures and to cooperate with other Japanese and worldwide networks. (author)

  17. The current situation and future scope of radiation emergency medical care network in Nagasaki

    Energy Technology Data Exchange (ETDEWEB)

    Morishita, Mariko; Namba, Hiroyuki; Yamashita, Shunichi [Nagasaki Univ., Graduate School of Biomedical Sciences, Atomic Bomb Disease Inst., Nagasaki, Nagasaki (Japan); Ohtsuru, Akira [Nagasaki Univ., Hospital, Takashi Nagai Memorial International Hibakusha Medical Center, Nagasaki, Nagasaki (Japan)

    2005-12-15

    Under the framework of the International Consortium for Medical Care of Hibakusha and Radiation Life Science (Nagasaki University 21st Century COE Program) and bearing in mind the unique history and responsibility of Nagasaki University, several projects on radiation emergency preparedness are in progress. The critical accident in Tokaimura, Japan in 1999 made us realize that nuclear emergencies happen anywhere radionuclides exist. In fact, nuclear accidents possibly take place in factories, research facilities, hospital and wherever radioactive materials are in transit. Therefore, it is necessary to establish an effective preparedness network system for potential radiation emergency that may occur in Nagasaki and nearby prefectures and to cooperate with other Japanese and worldwide networks. (author)

  18. The responsibility of the radiation protection expert

    International Nuclear Information System (INIS)

    Varescon, M.

    2008-01-01

    After having recalled the two main different types of responsibility in the French law system (civil liability and criminal responsibility), and how criminal law has been gradually introduced in companies, the author analyzes and describes how the radiation protection expert's responsibility is tightly related to that of his employer, and how both can be committed on a disciplinary and criminal level

  19. 48 CFR 452.236-77 - Emergency Response.

    Science.gov (United States)

    2010-10-01

    ... contracts: Emergency Response (NOV 1996) (a) Contractor's Responsibility for Fire Fighting. (1) The... emergency work (anticipated to be restricted to fire fighting). An equitable adjustment for the temporary... 48 Federal Acquisition Regulations System 4 2010-10-01 2010-10-01 false Emergency Response. 452...

  20. Some Qualitative Requirements for Testing of Nuclear Emergency Response Robots

    International Nuclear Information System (INIS)

    Eom, Heungseop; Cho, Jai Wan; Choi, Youngsoo; Jeong, Kyungmin

    2014-01-01

    Korea Atomic Energy Research Institute (KAERI) is carrying out the project 'Development of Core Technology for Remote Response in Nuclear Emergency Situation', and as a part of the project, we are studying the reliability and performance requirements of nuclear emergency response robots. In this paper, we described some qualitative requirements for testing of nuclear emergency response robots which are different to general emergency response robots. We briefly introduced test requirements of general emergency response robots and described some qualitative aspects of test requirements for nuclear emergency response robots. When considering an immature field-robot technology and variety of nuclear emergency situations, it seems hard to establish quantitative test requirements of these robots at this time. However, based on studies of nuclear severe accidents and the experience of Fukushima NPP accident, we can expect some test requirements including quantitative ones for nuclear emergency response robots

  1. International IAEA Emergency Response Workshop in Fukushima Concludes

    International Nuclear Information System (INIS)

    2013-01-01

    Full text: An IAEA workshop aimed at further strengthening nuclear and radiological emergency preparedness and response capabilities concluded today in Fukushima, Japan. More than 40 participants from 18 countries took part in the four-day Response and Assistance Network (RANET) workshop, which included a field exercise in areas affected following the March 2011 accident at TEPCO's Fukushima Daiichi Nuclear Power Station. During the exercise, participants conducted radiation monitoring and environmental sampling and analysis. They measured the contamination level of the ground surface and conducted gamma spectrum analysis and vehicle-based monitoring - activities that are conducted following any nuclear or radiological incident or emergency. Results were then compared amongst participants. RANET is a network currently comprising 22 countries through which the IAEA can facilitate the provision of expert support and equipment on request under the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency. Pat Kenny, IAEA RANET Officer, said the workshop provided an opportunity to practice cooperation between international teams that would be deployed through RANET following an emergency. 'By bringing together so many experts from different countries in one place, the workshop helped us learn how international teams can work together to provide assistance in a nuclear or radiological emergency situation,' he said. 'It also enabled us to improve the coordination of such assistance, and it gave participants the opportunity to learn from each other.' The workshop was the first activity conducted from the IAEA RANET Capacity Building Centre, a new training centre based in the city of Fukushima that was designated earlier this week with the support of the Japanese Foreign Ministry and Fukushima Prefecture. The Centre will host RANET and other training courses, workshops and exercises aimed at enhancing nuclear emergency preparedness and response

  2. Preparation, conduct and evaluation of exercises to test preparedness for a nuclear or radiological emergency. Emergency preparedness and response

    International Nuclear Information System (INIS)

    2005-04-01

    The aim of this publication is to serve as a practical tool for the preparation, conduct and evaluation of exercises to test preparedness for response to a nuclear or radiological emergency. It fulfils in part the functions assigned to the IAEA under Article 5.a(ii) of the Convention on Assistance in Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), namely, to collect and disseminate to States Parties and Member States information concerning the methodologies, techniques and available results of research on such emergencies. To ensure effective response to radiation emergencies when needed, provisions should be made for regular training of emergency response personnel. As stated in Preparedness and Response for a Nuclear or Radiological Emergency (Safety Requirements, Safety Standard Series No. GS-R-2), 'The operator and the response organizations shall make arrangements for the selection of personnel and training to ensure that the personnel have the requisite knowledge, skills, abilities, equipment, procedures and other arrangements to perform their assigned response functions'. A further requirement is that 'Exercise programmes shall be conducted to ensure that all specified functions required to be performed for emergency response and all organizational interfaces for facilities in threat category I, II or III and the national level programmes for threat category IV or V are tested at suitable intervals'. In 2004 the IAEA General Conference, in resolution GC(48)/RES/10 encouraged Member States to 'implement the Safety Requirements for Preparedness and Response to a Nuclear or Radiological Emergency'. This document is published as part of the IAEA Emergency Preparedness and Response Series to assist in meeting these requirements and to fulfil Article 5 of the Assistance Convention. It was developed based on a number of assumptions about national and local capabilities. Therefore, the exercise structure, terms and scenarios must be

  3. Nuclear radiation sensors and monitoring following a nuclear or radiological emergencies

    International Nuclear Information System (INIS)

    Bhatnagar, P.K.

    2009-01-01

    Management of Nuclear and Radiological Emergencies arising from Radiological Dispersive Device (RDD), Improvised Nuclear Devices (IND), Nuclear Reactors/Power plants and Nuclear War require measurement of ionizing radiations and radioactivity on an enhanced scale relative to the levels encountered in peaceful uses of ionizing radiations and radioactivity. It is heartening that since Hiroshima, Nagasaki nuclear disaster, the world has been quiet but since early 2000 there has been a fear of certain devices to be used by terrorists, which could lead to panic, and disaster due to dispersal of radioactivity by RDD, IND. Nuclear attack would lead to blast, thermal, initial nuclear radiation, nuclear fall out leading to gamma and neutron dose, dose rates in range from few R, R/h to kR, kR/h, and determinations of k Bq or higher order. Such situations have been visualized at national levels and National Disaster Management Authority NDMA has been established and Disaster Management Act 2005 has come into existence. NDMA has prepared guidelines for Nuclear and radiological emergency management highlighting preparedness, mitigation, response, capacity building, etc. Critical point in all these issues is detection of emergency, quick intimation to the concerned for action in shortest possible time. Upper most requirement by those involved in pursuing action, is radiation sensor based radiation monitors for personnel, area, and to assess contamination due to radioactivity.This presentation briefly describes the Indian scenario in the development of the radiation sensors and the sensor-based radiation monitors. (author)

  4. Nuclear radiation sensors and monitoring following a nuclear or radiological emergencies

    Energy Technology Data Exchange (ETDEWEB)

    Bhatnagar, P K [Defence Laboratory, Jodhpur (India)

    2009-01-15

    Management of Nuclear and Radiological Emergencies arising from Radiological Dispersive Device (RDD), Improvised Nuclear Devices (IND), Nuclear Reactors/Power plants and Nuclear War require measurement of ionizing radiations and radioactivity on an enhanced scale relative to the levels encountered in peaceful uses of ionizing radiations and radioactivity. It is heartening that since Hiroshima, Nagasaki nuclear disaster, the world has been quiet but since early 2000 there has been a fear of certain devices to be used by terrorists, which could lead to panic, and disaster due to dispersal of radioactivity by RDD, IND. Nuclear attack would lead to blast, thermal, initial nuclear radiation, nuclear fall out leading to gamma and neutron dose, dose rates in range from few R, R/h to kR, kR/h, and determinations of k Bq or higher order. Such situations have been visualized at national levels and National Disaster Management Authority NDMA has been established and Disaster Management Act 2005 has come into existence. NDMA has prepared guidelines for Nuclear and radiological emergency management highlighting preparedness, mitigation, response, capacity building, etc. Critical point in all these issues is detection of emergency, quick intimation to the concerned for action in shortest possible time. Upper most requirement by those involved in pursuing action, is radiation sensor based radiation monitors for personnel, area, and to assess contamination due to radioactivity.This presentation briefly describes the Indian scenario in the development of the radiation sensors and the sensor-based radiation monitors. (author)

  5. Methodology for Assessing Radiation Detectors Used by Emergency Responders

    International Nuclear Information System (INIS)

    Piotr Wasiolek; April Simpson

    2008-01-01

    The threat of weapons of mass destruction terrorism resulted in the U.S. Department of Homeland Security deploying large quantities of radiation detectors throughout the emergency responder community. However, emergency responders specific needs were not always met by standard health physics instrumentation used in radiation facilities. Several American National Standards Institute standards were developed and approved to evaluate the technical capabilities of detection equipment. Establishing technical capability is a critical step, but it is equally important to emergency responders that the instruments are easy to operate and can withstand the rugged situations they encounter. The System Assessment and Validation for Emergency Responders (SAVER) Program (managed by the U.S. Department of Homeland Security, Office of Grants and Training, Systems Support Division) focuses predominantly on the usability, ergonomics, readability, and other features of the detectors, rather than performance controlled by industry standards and the manufacturers. National Security Technologies, LLC, as a SAVER Technical Agent, conducts equipment evaluations using active emergency responders who are familiar with the detection equipment and knowledgeable of situations encountered in the field, which provides more relevant data to emergency responders

  6. Experiences from exercises associated with nuclear emergency response in Germany

    International Nuclear Information System (INIS)

    Becker, D.E.

    2001-01-01

    Full text: Responsibilities Regarding Emergency Response in Germany - In the Federal Republic of Germany, the 16 federal state Ministries of the Interior are responsible for emergency response (threat through weapons, explosives, etc.). In the case of threats due to radioactive material experts of the competent federal state radiological protection authorities are consulted. The Federal Office for Radiation Protection assists in serious cases of defence against nuclear hazards (nuclear fuels, criticality, risk of dispersion). Currently, exercises are being performed in all 16 federal states to co-ordinate the ways of behaviour, action and thinking of the various necessary organisational units, like police, deactivators, prosecution officials, radiological protection experts and fire brigade. The joint exercises serve the purpose to practice the total chain of necessary measures like: notification chain, organisation at the place of action, co-ordination of appropriate search strategy, investigation of who was responsible, analysis (X-ray pictures, radiological analysis), activity determination, assessment of possible effects due to deactivation measures, determination of dispersion conditions, recommendation of measures for the protection of responders and the general population and measures to limit the consequences. Given Exercise Scenario - Via the emergency emergency call a situation is transmitted that urgently demands joint and co-ordinated action of prosecution authority, emergency response and radiation protection authority, to be able to master the situation successfully. As a rule this means that one deals with an IED (Improvised Explosive Device) secured by a booby trap with added radioactive substances. Organisation at the Place of Action - Experience shows that as a rule the patrol police and the local fire brigade will be the first to arrive at the place of action, already after a few minutes. Gradually, the other experts arrive. Depending on distance

  7. Automated data system for emergency meteorological response

    International Nuclear Information System (INIS)

    Kern, C.D.

    1975-01-01

    The Savannah River Plant (SRP) releases small amounts of radioactive nuclides to the atmosphere as a consequence of the production of radioisotopes. The potential for larger accidental releases to the atmosphere also exists, although the probability for most accidents is low. To provide for emergency meteorological response to accidental releases and to conduct research on the transport and diffusion of radioactive nuclides in the routine releases, a series of high-quality meteorological sensors have been located on towers in and about SRP. These towers are equipped with instrumentation to detect and record temperature and wind turbulence. Signals from the meterological sensors are brought by land-line to the SRL Weather Center-Analysis Laboratory (WC-AL). At the WC-AL, a Weather Information and Display (WIND) system has been installed. The WIND system consists of a minicomputer with graphical displays in the WC-AL and also in the emergency operating center (EOC) of SRP. In addition, data are available to the system from standard weat []er teletype services, which provide both routine surface weather observations and routine upper air wind and temperature observations for the southeastern United States. Should there be an accidental release to the atmosphere, available recorded data and computer codes would allow the calculation and display of the location, time, and downwind concentration of the atmospheric release. These data are made available to decision makers in near real-time to permit rapid decisive action to limit the consequences of such accidental releases. (auth)

  8. Planning and implementing nuclear emergency response facilities

    International Nuclear Information System (INIS)

    Williams, D.H.

    1983-01-01

    After Three Mile Island, Arkansas Nuclear One produced a planning document called TMI-2 Response Program. Phase I of the program defined action plans in nine areas: safety assessment, training, organization, public information, communication, security, fiscal-governmental, technical and logistical support. Under safety assessment, the staff was made even better prepared to handle radioactive material. Under training, on site simulators for each unit at ANO were installed. The other seven topics interface closely with each other. An emergency control center is diagrammed. A habitable technical support system was created. A media center, with a large media area, and an auditorium, was built. Electric door strike systems increased security. Phone networks independently run via microwave were installed. Until Three Mile Island, logistical problems were guesswork. That incident afforded an opportunity to better identify and prepare for these problems

  9. Gap Assessment in the Emergency Response Community

    Energy Technology Data Exchange (ETDEWEB)

    Barr, Jonathan L.; Burtner, Edwin R.; Pike, William A.; Peddicord, Annie M Boe; Minsk, Brian S.

    2010-09-27

    This report describes a gap analysis of the emergency response and management (EM) community, performed during the fall of 2009. Pacific Northwest National Laboratory (PNNL) undertook this effort to identify potential improvements to the functional domains in EM that could be provided by the application of current or future technology. To perform this domain-based gap analysis, PNNL personnel interviewed subject matter experts (SMEs) across the EM domain; to make certain that the analyses reflected a representative view of the community, the SMEs were from a variety of geographic areas and from various sized communities (urban, suburban, and rural). PNNL personnel also examined recent and relevant after-action reports and U.S. Government Accountability Office reports.

  10. The radiative heating response to climate change

    Science.gov (United States)

    Maycock, Amanda

    2016-04-01

    The structure and magnitude of radiative heating rates in the atmosphere can change markedly in response to climate forcings; diagnosing the causes of these changes can aid in understanding parts of the large-scale circulation response to climate change. This study separates the relative drivers of projected changes in longwave and shortwave radiative heating rates over the 21st century into contributions from radiatively active gases, such as carbon dioxide, ozone and water vapour, and from changes in atmospheric and surface temperatures. Results are shown using novel radiative diagnostics applied to timeslice experiments from the UM-UKCA chemistry-climate model; these online estimates are compared to offline radiative transfer calculations. Line-by-line calculations showing spectrally-resolved changes in heating rates due to different gases will also be presented.

  11. An overview of emergency radiation monitoring in Hong Kong

    International Nuclear Information System (INIS)

    Wong, M.C.; Mok, H.Y.; Chan, Y.K.

    2000-01-01

    In relation to the operation of a nuclear power station located some 50 km to the northeast of Hong Kong, a contingency plan has been formulated in Hong Kong to manage the local response in the event of a severe accident occurring at the nuclear power station. As an integral component of the contingency plan, the Hong Kong Observatory has specifically designed and implemented an emergency radiation monitoring programme. The primary objective of emergency monitoring in the early phase of a nuclear accident is to rapidly detect and document the presence of radioactive materials for determining the impact of the release. Even in the case when Hong Kong is outside the plume coverage, the verification that there is no radioactive plume or deposition over Hong Kong is essential for providing reassurance to the local population. Although Hong Kong is a small place, it has a dense network of fixed-station monitors for continuous measurement of the ambient gamma dose-rate over the territory. At Ping Chau, one of the fixed-station closest to the nuclear power station (about 13 km), an automatic gamma spectrometry system is also operated to monitor the activity concentrations of man-made nuclides in air. This system provides both qualitative and quantitative isotopic information on the cause of any rise in ambient gamma dose-rate detected at the station. A number of fire stations over the territory can also be activated during an emergency to conduct ambient gamma dose-rate measurements using portable survey meters. The fixed-station radiation data will be supplemented by measurements taken en-route emergency surveys. Three mobile survey teams can be deployed within an hour of notice. Two of the survey teams will conduct surveys at ground surface. The third survey team will conduct aerial surveys at various altitudes over Hong Kong and the adjacent seas. Environmental samples, including airborne particulate, radioiodine, deposition, soil and water samples are collected at the

  12. Establishing a mobile automatic monitoring station for emergency response

    International Nuclear Information System (INIS)

    Fang, Hsin-Fa

    2008-01-01

    Full text: A radiological/nuclear emergency event may cause environmental contamination. The emergency response works always need to plan an environmental survey programme incorporating the assessment results to see what is happening. The places where are assessed to have the highest radioactive contamination/radiation dose will catch more concern and need continuous monitoring. It will cause unnecessary dangers and dose to command that personnel conduct surveying in such places when the radiological/nuclear accident become more severe. A mobile automatic monitoring station has been established for emergency response by INER (Institute of Nuclear Energy Research) to solve the problem practically. The monitoring station involves a HPIC to monitor radiation dose, an anemometer to monitor wind speed and direction, a GPS to get position data, a GPRS/3G communication module to send monitoring and positioning data to the monitoring centre where can show the monitoring result directly on a map shown on the computer. These instruments are integrated in a trailer easy to be towed to the place need to be monitored. The electric power of the station is supplied by s a solar power energy system. It can supply the station working at least 10 days without extra electric power supply designed based on the expected time length of a nuclear power plant event. The HPIC is very sensitive and stable that can discriminate a 10 nSv/hr increasing of dose rate with the monitoring time period every ten seconds. Where the radiological dispersion device events happened is not predictable, it is difficult to get suitable wind monitoring data to assess the result of radiological dispersion device events. The anemometer added on the station can provide the real time wind monitoring data to help assessment works. (author)

  13. Emergency response to mass casualty incidents in Lebanon.

    Science.gov (United States)

    El Sayed, Mazen J

    2013-08-01

    The emergency response to mass casualty incidents in Lebanon lacks uniformity. Three recent large-scale incidents have challenged the existing emergency response process and have raised the need to improve and develop incident management for better resilience in times of crisis. We describe some simple emergency management principles that are currently applied in the United States. These principles can be easily adopted by Lebanon and other developing countries to standardize and improve their emergency response systems using existing infrastructure.

  14. Method for developing arrangements for response to a nuclear or radiological emergency. Updating IAEA-TECDOC-953. Emergency preparedness and response. Publication date: October 2003

    International Nuclear Information System (INIS)

    2003-09-01

    In 1997 the IAEA compiled, consolidated and organized existing information, and published the TECDOC-953 'Method for Development of Emergency Response Preparedness for Nuclear or Radiological Accidents'. Subsequently this publication was used extensively by the IAEA for training and for evaluation of emergency response programmes. In November 1999 a technical committee meeting (TCM) with representatives of over 20 States reviewed and provided feedback on IAEA-TECDOC-953. In March 2002, the IAEA's Board of Governors approved a Safety Requirements publication, 'Preparedness and Response for a Nuclear or Radiological Emergency', jointly sponsored by seven international organizations, which establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. The IAEA General Conference in resolution GC(46)/RES/9 encouraged Member States to implement, if necessary, instruments for improving their own preparedness and response capabilities for nuclear and radiological incidents and accidents, including their arrangements for responding to acts involving the malicious use of nuclear or radioactive material and to threats of such acts, and has further encouraged them to implement the Safety Requirements for Preparedness and Response to a Nuclear or Radiological Emergency. The obligations, responsibilities and requirements for preparedness and response for radiation emergencies are set out in the safety standards, in particular the 1996 'International Basic Safety Standards for Protection against Ionizing Radiation and for the Safety of Radiation Sources'. Consensus information on relevant radiation protection criteria was established in 1994 and published in 'Intervention Criteria in a Nuclear or Radiation Emergency'. Several other guides and publications in the area of emergency preparedness and response had previously been issued. The present publication now being issued in the Emergency Preparedness and

  15. Problems related to public perceptions of radiological emergency planning and response

    International Nuclear Information System (INIS)

    Reilly, Margaret A.

    1989-01-01

    Beyond the scientific, the administrative and procedural issues of radiological emergency planning and response there is the issue of public perception. This paper emphasises that, radiation crises being a rare occurrence there is no enough database for generating scholarly quantitative reports. It suggests the need for disseminating timely and accurate information through a single spokesman from a responsible public agency

  16. Radiation-Induced Bystander Response: Mechanism and Clinical Implications

    Science.gov (United States)

    Suzuki, Keiji; Yamashita, Shunichi

    2014-01-01

    Significance: Absorption of energy from ionizing radiation (IR) to the genetic material in the cell gives rise to damage to DNA in a dose-dependent manner. There are two types of DNA damage; by a high dose (causing acute or deterministic effects) and by a low dose (related to chronic or stochastic effects), both of which induce different health effects. Among radiation effects, acute cutaneous radiation syndrome results from cell killing as a consequence of high-dose exposure. Recent advances: Recent advances in radiation biology and oncology have demonstrated that bystander effects, which are emerged in cells that have never been exposed, but neighboring irradiated cells, are also involved in radiation effects. Bystander effects are now recognized as an indispensable component of tissue response related to deleterious effects of IR. Critical issues: Evidence has indicated that nonapoptotic premature senescence is commonly observed in various tissues and organs. Senesced cells were found to secrete various proteins, including cytokines, chemokines, and growth factors, most of which are equivalent to those identified as bystander factors. Secreted factors could trigger cell proliferation, angiogenesis, cell migration, inflammatory response, etc., which provide a tissue microenvironment assisting tissue repair and remodeling. Future directions: Understandings of the mechanisms and physiological relevance of radiation-induced bystander effects are quite essential for the beneficial control of wound healing and care. Further studies should extend our knowledge of the mechanisms of bystander effects and mode of cell death in response to IR. PMID:24761341

  17. Joint Radiation Emergency Management Plan of the International Organizations. Date Effective: 1 January 2010

    International Nuclear Information System (INIS)

    2010-01-01

    The purpose of this Plan is to describe the inter-agency framework for preparedness for and response to a radiation5 incident or emergency irrespective of its cause. In particular, its objectives are: 1. To provide a common understanding of the emergency preparedness and response roles and responsibilities, objectives, authorities, capabilities and arrangements of each participating international organization, and any relevant inter-agency arrangements; 2. To provide an overall concept of operations between the international organizations based on the emergency response objectives, responsibilities, authorities, capabilities and arrangements of each participating international organization, and any existing inter-agency arrangements, in order to facilitate a timely, effective and co-ordinated response; 3. To facilitate development of agreements among the participating international organizations on practical issues, if appropriate; 4. To provide a common understanding of the process for improving and changing the inter-agency response arrangements; 5. To provide a common understanding of roles and responsibilities of the participating international organizations with respect to: international standards, supporting national capabilities through provision of guidance and training, relevant research, emergency exercises and other preparedness considerations; 6. To guide the managers in each participating organization who need to ensure that all appropriate arrangements are given the necessary support within their organization; 7. To facilitate the well founded development, maintenance and training of plans and procedures for each organization; 8. To draw the attention of personnel in States and international organizations6 to these arrangements and to facilitate the development of compatible arrangements, if appropriate. The Joint Plan describes the arrangements of the participating international organizations7 for responding to a radiation incident or emergency

  18. An off-site screening process for the public in radiation emergencies and disasters

    International Nuclear Information System (INIS)

    Yoon, Seok Won; Ho, Ha Wi; Jin, Young Woo

    2016-01-01

    A contamination screening process for the local population in radiation emergencies is discussed. We present an overview of the relevant Korean governmental regulations that underpin the development of an effective response system. Moreover, case studies of foreign countries responding to mass casualties are presented, and indicate that responses should be able to handle a large demand for contamination screening of the local public as well as screening of the immediate victims of the incident. We propose operating procedures for an off-site contamination screening post operated by the local government for members of the public who have not been directly harmed in the accident. In order to devise screening categories, sorting strategies assessing contamination and exposure are discussed, as well as a psychological response system. This study will lead to the effective operation of contamination screening clinics if an accident occurs. Furthermore, the role of contamination screening clinics in the overall context of the radiation emergency treatment system should be clearly established

  19. Status and developing of nuclear emergency response techniques in China

    International Nuclear Information System (INIS)

    Jiangang, Zhang; Bing, Zhao; Rongyao, Tang; Xiaoxiao, Xu

    2008-01-01

    Full text: Nuclear Emergency preparedness and response in China is consistent with international basic principle of nuclear safety and emergency response. Nuclear emergency response techniques in China developed with nuclear power from 1980s. The status of nuclear emergency techniques in China are: 1) China have plentiful experiences and abilities in the fields of nuclear facility emergency planning and preparedness, nuclear accident consequence assessment, emergency monitoring, and emergency advisory; 2) Emergency assistance ability in China has a foundation, however it cannot satisfy national requirement; 3) Emergency planning and preparedness is not based on hazard assessment; 4) Remote monitoring and robot techniques in not adaptable to the requirements of nuclear emergency response; 5) A consistent emergency assessment system is lack in China. In this paper, it is analyzed what is the developing focal points of nuclear emergency response techniques in China, and it is proposed that the main points are: a) To develop the research of emergency preparedness on the base of hazard analysis; b) To improve remote monitoring and robot ability during nuclear emergency; c) To develop the response technique research with anti-terrorism. (author)

  20. Emergency response technical centre of the IPSN

    International Nuclear Information System (INIS)

    Dallendre, R.

    2000-01-01

    The Institute for Nuclear Safety and Protection (IPSN), the technical support of the French nuclear safety authority, provides the technical support needed for protect the surrounding population from the consequences of radioactive releases. In the event of an accident arising at a nuclear facility, the IPSN would set up an Emergency Response Technical Centre (CTC) at Fontenay-aux-Roses. The IPSN's objectives are: (a) to diagnose the state of the nuclear facility and monitor its development, (b) to prepare prognosis for the evolution of the accident and to give an estimation of the associated consequences according to the situation evolution, (c) to estimate the risk of radioactive releases and the consequences on man and on the environment, mainly on the basis of weather forecasts and on the prognosis. This diagnosis-prognosis approach is build-up with the information on the state of the installation given by: the concerned site via audio-conference system and telescope, the security panels of the nuclear plant via networks. To perform its missions, the CTC, which has to be both safe and secure, uses multiple telecommunication resources to dialogue with partners and also mapping computer systems, data bases and software tools: (a) the SESAME system, which gives, during an accident of a PWR, a calculation method for the diagnosis-prognosis aforesaid, (b) the CONRAD system, which calculates the atmospheric dispersal of radioactive substances and consequences in the environment in the early phase of an accident, (c) the ASTRAL code, which allows to cope with long lasting situations. In order to be operational, the IPSN expert regularly undergo training in emergency situation management and participate in exercises organised by the government authorities. (author)

  1. Building a year 2000 emergency response plan

    International Nuclear Information System (INIS)

    Riopel, P.

    1998-01-01

    This presentation emphasized the importance of developing an emergency plan to minimize any impacts in the event that something may go wrong when the clock changes over at midnight on December 31, 1999. It is usually impossible to anticipate what kinds of emergencies will happen. Planning for emergencies does not have to be an intimidating task. Hazard analysis is a subjective way to investigate what can go wrong, the likelihood of it happening relative to some other potential emergency, and the seriousness of the event. In general, emergency planning for Y2K should not be significantly different from planning for any other type of emergency. Y2K is not the emergency. The events that occur as a consequence of Y2K are. It is these events that should be the focus of a Year 2000 emergency plan

  2. Radiation protection in nuclear emergencies, including thyroid blockage with iodine

    International Nuclear Information System (INIS)

    Niklas, K.

    1991-01-01

    The Government of the Federal Republic of Germany has set emergency reference levels of radiation doses at which countermeasures such as sheltering, evacuation, iodine prophylaxis and resettlement should be considered in case of severe accidents in nuclear installations. Emergency facilities are to be set up for a range of meausres to protect the public, such as assessment of contamination and subsequent decontamination. Recommendations as to further therapeutic measures will be made by medical personnel. The administration of stable iodine can block or reduce the accumulation of radioiodine in the thyroid gland. Stable potassium iodine tablets (100 mg each) will be distributed by the local authorities. Since iodine deficiency is still prevalent in large parts of the Federal Republic of Germany, iodine prophylaxis will be recommended only when relatively high radiation doses to the thyroid gland are to be expected. Resettlement of the population must be considered if an excessive dose is expected in the affected area over a long period. (orig.) [de

  3. Oil supply security: the emergency response potential of IEA countries

    International Nuclear Information System (INIS)

    1995-01-01

    This work deals with the oil supply security and more particularly with the emergency response potential of International Energy Agency (IEA) countries. The first part describes the changing pattern of IEA emergency response requirements. It begins with the experience from the past, then gives the energy outlook to 2010 and ends with the emergency response policy issues for the future. The second part is an overview on the IEA emergency response potential which includes the organisation, the emergency reserves, the demand restraint and the other response mechanisms. The third part gives the response potential of individual IEA countries. The last part deals with IEA emergency response in practice and more particularly with the gulf crisis of 1990-1991. It includes the initial problems raised by the gulf crisis, the adjustment and preparation and the onset of military action with the IEA response.(O.L.). 7 figs., 85 tabs

  4. Using principles from emergency management to improve emergency response plans for research animals.

    Science.gov (United States)

    Vogelweid, Catherine M

    2013-10-01

    Animal research regulatory agencies have issued updated requirements for emergency response planning by regulated research institutions. A thorough emergency response plan is an essential component of an institution's animal care and use program, but developing an effective plan can be a daunting task. The author provides basic information drawn from the field of emergency management about best practices for developing emergency response plans. Planners should use the basic principles of emergency management to develop a common-sense approach to managing emergencies in their facilities.

  5. Emerging applications of radiation processing. Proceedings of a technical meeting

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2004-01-01

    Approximately 160 gamma irradiators and 1200 electron accelerator based processing units are in operation worldwide. In recent years the IAEA has prepared a directory of industrial gamma irradiators and held several meetings on developments in radiation technology applications. Developments involving the engineering of new sources (both isotope and electrical), high power accelerator applications, etc. have been reported recently, making a review and evaluation of this progress timely. Therefore the IAEA organized a technical meeting in Vienna, Austria, from 28 to 30 April 2003 to review the present situation and the potential contribution of radiation technology to sustainable development. Engineering developments and other features of radiation sources, both isotope and accelerator, were discussed. Recent research has concentrated on three fields: medical and food products, polymers, and environmental pollution control. The stability of radiation sterilized medical implants, as well as the uses of radiation processing for sterilization or decontamination of pharmaceuticals and pharmaceutical raw materials, radiation synthesis and modification of polymers for biomedical applications have been studied. Since separation and enrichment technologies play an important role in product recovery and pollution control, the possibility of radiation synthesis of stimuli-responsive membranes, hydrogels and adsorbents is being investigated. Finally, aside from the technologies for flue gas and wastewater treatment already in use, further research is ongoing on the treatment of organic contaminants in both gaseous and liquid phases. Environmental applications, which also offer new opportunities, should be carefully reviewed to reflect existing regulations and current knowledge. The increasingly serious problem of polyaromatic hydrocarbons (PAH) emissions may be solved in part by the application of radiation technology. This is being studied on a pilot scale for the removal of

  6. Emerging applications of radiation processing. Proceedings of a technical meeting

    International Nuclear Information System (INIS)

    2004-01-01

    Approximately 160 gamma irradiators and 1200 electron accelerator based processing units are in operation worldwide. In recent years the IAEA has prepared a directory of industrial gamma irradiators and held several meetings on developments in radiation technology applications. Developments involving the engineering of new sources (both isotope and electrical), high power accelerator applications, etc. have been reported recently, making a review and evaluation of this progress timely. Therefore the IAEA organized a technical meeting in Vienna, Austria, from 28 to 30 April 2003 to review the present situation and the potential contribution of radiation technology to sustainable development. Engineering developments and other features of radiation sources, both isotope and accelerator, were discussed. Recent research has concentrated on three fields: medical and food products, polymers, and environmental pollution control. The stability of radiation sterilized medical implants, as well as the uses of radiation processing for sterilization or decontamination of pharmaceuticals and pharmaceutical raw materials, radiation synthesis and modification of polymers for biomedical applications have been studied. Since separation and enrichment technologies play an important role in product recovery and pollution control, the possibility of radiation synthesis of stimuli-responsive membranes, hydrogels and adsorbents is being investigated. Finally, aside from the technologies for flue gas and wastewater treatment already in use, further research is ongoing on the treatment of organic contaminants in both gaseous and liquid phases. Environmental applications, which also offer new opportunities, should be carefully reviewed to reflect existing regulations and current knowledge. The increasingly serious problem of polyaromatic hydrocarbons (PAH) emissions may be solved in part by the application of radiation technology. This is being studied on a pilot scale for the removal of

  7. Nordic Mutual Emergency Assistance Agreement in Connection with Radiation Accidents

    International Nuclear Information System (INIS)

    1963-01-01

    The text of the Nordic Mutual Emergency Assistance Agreement in Connection with Radiation Accidents, which was signed on 17 October 1963 by the Director General and by representatives of the Governments of Denmark, Finland, Norway and Sweden, is reproduced in this document for the information of all Members. The entry into force of the Agreement in accordance with Article IX will be notified to Members in an Addendum to this document [es

  8. Nordic Mutual Emergency Assistance Agreement in Connection with Radiation Accidents

    International Nuclear Information System (INIS)

    1963-01-01

    The text of the Nordic Mutual Emergency Assistance Agreement in Connection with Radiation Accidents, which was signed on 17 October 1963 by the Director General and by representatives of the Governments of Denmark, Finland, Norway and Sweden, is reproduced in this document for the information of all Members. The entry into force of the Agreement in accordance with Article IX will be notified to Members in an Addendum to this document

  9. 'REACTS'. A pragmatic approach for providing medical care and physician education for radiation emergencies

    International Nuclear Information System (INIS)

    Lushbaugh, C.C.; Andrews, G.A.; Huebner, K.F.; Cloutier, R.J.; Beck, W.L.; Berger, J.D.

    1976-01-01

    Because serious radiation incidents have been rare, few medical personnel (notably only some in France, Russia, Belgium, Canada, Yugoslavia, Japan, Great Britain and the United States) have first-hand experience in radiation-accident management. The generation of physicians who participated in those accidents now needs to pass on the bits of knowledge that were gleaned from them. These case histories are difficult for the local, non-radiology physician to obtain when he is called upon to help formulate the medical-emergency response plan required everywhere for licensing power reactors. The Radiation Emergency Assistance Center and Training Site (REACTS) in Oak Ridge, Tennessee, supported by the US Energy Research and Development Administration, is designed to meet these medical and educational needs. REACTS, located in the Oak Ridge Hospital of the Methodist Church, is not involved in the hospital's daily community functions except insofar as REACTS is the radiation emergency arm of the area's major disaster plan. Its dual mission is training physicians, nurses, and paramedical emergency personnel in radiation-accident management, and treating irradiated and contaminated persons. Its training activities are carried out by the Special Training Division of Oak Ridge Associated Universities. Formal courses in radiation medicine and health physics and practical laboratory experience are now conducted twice a year for physicians. They will be expanded in the future to include training of paramedical personnel. Follow-up studies of radiation-accident survivors are carried out in REACTS to ensure the preservation of valuable human data and radiation-accident experiences. This unique facility and its staff are dedicated to meet the needs of the far-flung public and private medical domains in the United States for nuclear-production energy

  10. Adriamycin resistance and radiation response

    International Nuclear Information System (INIS)

    Belli, J.A.; Harris, J.R.

    1979-01-01

    Mammalian cells (V79) in culture developed resistance to Adriamycin during continuous exposure to low levels of drug. This resistance was accompanied by change in x-ray survival properties which, in turn, depended upon the isolation of subpopulations from resistant sub lines. These changes in x-ray survival properties were characterized by reduced D/sub Q/ values and a decrease in the D/sub O/. However, these changes were not observed together in the same cell sub line. Adriamycin-resistant cells did not appear to be radiation damage repair deficient. Other phenotypic changes (cell morphology, DNA content and chromosome number) suggested mutational events coincident with the development of Adriamycin resistance

  11. Numerical models and their role in emergency response: a perspective on dispersion modeling for emergency preparedness

    International Nuclear Information System (INIS)

    Greenly, G.D.; Dickerson, M.H.

    1983-03-01

    Numerical models on several levels of complexity should be available to the emergency response planner. They are a basic tool but must be used in conjunction with both measurements and experience. When these tools are used in a complimentary fashion they greatly enhance the capability of the consequence manager to respond in an emergency situation. Because each accident or incident develops it's own characteristics and requirements the system must be capable of a flexible response. Interaction and feedback between model results from a suite of models and measurements (including airborne measurements) serve the emergency response planner's spectrum of needs, ranging from planning exercises and emergency precalculations to a real-time emergency response

  12. Preparing a laboratory for radioanalytical emergency response

    International Nuclear Information System (INIS)

    Bennett, J.; Webb, C.J.; Isch, S.

    2011-01-01

    As the state of the nation's ability to respond to a radiological event is examined, it has become apparent that both capacity and capability are lacking. Department of Homeland Security National Planning Scenario 11 is designed to address the planning activities for the response to an attack using radiological dispersal devices. The scenario details show that the cleanup activity will take several years, and that there will be between 360 000 and 1 000 000 environmental samples in the first year. Based on existing capacity and capabilities it would take four to six years to analyze the samples generated at the lower end of the sample range. The Environmental Protection Agency (EPA) has been given responsibility for the remediation activities following a radiological event, and has awarded cooperative agreements to several laboratories to start the process of developing capacity and capabilities. The Connecticut Department of Public Health Laboratory (DPHL) was awarded one of the cooperative agreements. The DPHL has started activities to further those goals by investigating and implementing procedures to ensure that samples with activity higher than normal background can be processed safely, as well as implementing more rapid methods for radiochemical analysis. The DPHL already served as the primacy radiochemistry laboratory for several New England states and thus had a solid foundation to build upon. The DPHL has taken a process flow approach in preparing for radiological emergency response and recommends that radioanalytical laboratories that are reviewing their roles in such a response: - Ensure that their Nuclear Regulatory Commission licenses allow for appropriate radioisotope types and activities; - Develop procedures and processes to ensure that samples with higher activities can be processed safely, with due regard for sample screening and aliquanting samples; - Provide for enhanced radioanalytical contamination control, with careful consideration of sample

  13. Education and training of physicians for radiation emergency management

    International Nuclear Information System (INIS)

    Reiners, Christoph; Schneider, Rita

    2012-01-01

    The project orders implied the development, testing, and evaluation of a curriculum for educating and training physicians in prehospital radiation accident management and the development of a master curriculum. Objectives were to develop, preserve, and enlarge medical competence concerning prehospital care of radiation accident patients. The project is expected to contribute to qualify emergency physicians challenged by scenarios related to radiological and nuclear hazards. The development and the content of the curriculum for educating and training physicians in prehospital radiation accident management are being described. The conduction and evaluation of two pilot training courses with a total of 40 participating physicians are being presented. Successful testing of the pilot courses proves the value of the curriculum developed. Self-contained courses can be performed according to the master curriculum and the respective master presentations. Moreover, single modules can be integrated in existing education and training programmes. Suggestions for the implementation and accreditation of the curriculum are being made. (orig.)

  14. Lighting the way: how emergency lights survive radiation

    CERN Multimedia

    Stephanie Hills

    2016-01-01

     LHC tunnel emergency lights are part of an essential safety system if you ever need to evacuate.   As part of the design of a new emergency lighting system for the CERN accelerator complex a new design for a radiation resistant power supply has been produced. The design is available from the Open Hardware Repository. (Video: Christoph Madsen/ CERN) Just like a fridge, you only need the lights on in the LHC tunnel when you are in there; but the emergency lights are part of an essential safety system if you ever need to evacuate.  Fortunately, tunnel evacuations are very rare, but if you work there, you need to know that you can rely on the emergency lighting to guide you to safety. When the LHC machine is operating, it is a harsh environment – people are most definitely not allowed access – and the lighting systems need to withstand the effects of radiation to ensure that they will still work when the LHC is switched off and people ar...

  15. Radiation-induced gene responses

    International Nuclear Information System (INIS)

    Woloschak, G.E.; Paunesku, T.; Shearin-Jones, P.; Oryhon, J.

    1996-01-01

    In the process of identifying genes that are differentially regulated in cells exposed to ultraviolet radiation (UV), we identified a transcript that was repressed following the exposure of cells to a combination of UV and salicylate, a known inhibitor of NF-kappaB. Sequencing this band determined that it has identify to lactate dehydrogenase, and Northern blots confirmed the initial expression pattern. Analysis of the sequence of the LDH 5' region established the presence of NF-kappaB, Sp1, and two Ap-2 elements; two partial AP- 1; one partial RE, and two halves of E-UV elements were also found. Electromobility shift assays were then performed for the AP-1, NF- kappaB, and E-UV elements. These experiments revealed that binding to NF-kappaB was induced by UV but repressed with salicylic acid; UV did not affect AP-1 binding, but salicylic acid inhibited it alone or following UV exposure; and E-UV binding was repressed by UV, and salicylic acid had little effect. Since the binding of no single element correlated with the expression pattern of LDH, it is likely that multiple elements govern UV/salicylate-mediated expression

  16. Initial operations in local nuclear emergency response headquarter

    International Nuclear Information System (INIS)

    2012-06-01

    As a result of the Fukushima nuclear accident due to the Great East Japan Earthquake and the tsunami that occurred thereafter, local nuclear emergency response headquarters (local headquarters) was set up at off-site center (OFC). However, several obstacles such as the collapse of means of communication resulting from severed communication lines, food and fuel shortage resulting from stagnant physical distribution, and increasing radiation dose around the center significantly restricted originally intended operation of local headquarters. In such severe situation, the personnel gathered at the OFC from the government, local public bodies and electric companies from March 11 to 15 acted without sufficient food, sleep or rest and did all they could against successively occurring unexpected challenges by using limited means of communication. However, issues requiring further consideration were activities of each functional group, location of OFC and the functions of equipment, machines and materials and reflecting the consideration results into future protective measures and revision of the manual for nuclear emergency response were greatly important. This report described investigated results on initial operations in local headquarters such as situation of activities conducted by local headquarters and operations at functional groups. (T. Tanaka)

  17. Emergency notification and assistance technical operations manual. Emergency preparedness and response. Date effective: 1 February 2007

    International Nuclear Information System (INIS)

    2007-01-01

    The Convention on Early Notification of a Nuclear Accident (the 'Early Notification Convention') and the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the 'Assistance Convention') are the prime legal instruments that establish an international framework to facilitate the exchange of information and the prompt provision of assistance in the event of a nuclear or radiological emergency, with the aim of minimizing the consequences. The International Atomic Energy Agency has specific functions assigned to it under these Conventions, to which, in addition to a large number of States, the World Health Organization (WHO), the World Meteorological Organization (WMO) and the Food and Agriculture Organization of the United Nations (FAO) are full parties. The arrangements provided between the IAEA, States that are IAEA Member States and/or Parties to one or both Conventions, all other relevant international intergovernmental organizations, and other States for facilitating the implementation of these Conventions - specifically concerning those articles that are operational in nature - are documented in the Emergency Notification and Assistance Technical Operations Manual (ENATOM). ENATOM was first issued on 18 January 1989. Member States, Parties to the Early Notification and Assistance Conventions, relevant international organizations and other States have since then regularly received updates to the manual. In 2000, a complete revision of ENATOM was reissued as EPR-ENATOM (2000) to reflect technological developments, changes in operational concepts, views on standards in the area of emergency preparedness and response, and Member States' expectations. Since then ENATOM has been reviewed and reissued biennially in line with the review cycle of the Joint Radiation Emergency Management Plan of the International Organizations (the 'Joint Plan'). Since the last edition of ENATOM in 2004, several factors have warranted some modifications to

  18. Planning for dealing with situations of radiation emergencies: A base proposal for Angola Republic

    International Nuclear Information System (INIS)

    Santos, Jerry Rawlings Pereira dos

    2017-01-01

    This work aims to establish basic procedures for response to radiological emergency to act in an anomalous or accidental situation due to practices (medical, industrial) and use of radioactive sources in the Republic of Angola or any activities against the State, in order to minimize the impact of contamination and exposure on the population, ensuring the protection of people and the environment from the harmful effects of ionizing radiation. This work proposes to create a group or committee to deal with situations of radiological emergencies capable of strengthening the technical and professional competencies existing in the Country, making the professionals trained to attend to any emergency situation that may occur in the national territory, due to the medical and industrial practices that use radioactive sources, as well as possible radiological accidents and illicit actions of the use of radiation. (author)

  19. New strategies based on biomedical approaches for developing countermeasures against radiation and nuclear emergency

    International Nuclear Information System (INIS)

    Mishra, K. P.

    2009-01-01

    Biomedical and radiological research projects are essentially aimed to understanding, evaluation and modification of ionizing radiation induced effects on microorganisms, plants, animals and humans. It is widely recognized that control and management of radiation injury are central to safety assurances for peaceful applications of nuclear energy and radiation technology. Extensive radiobiological research in the past decades have allowed gaining the deeper insight of molecular mechanisms of radiation damage in vital cellular targets, namely, DNA, membrane, proteins and signaling cascades. The radiation induced damaging events in living cells are believed to be mediated by direct as well as indirect effects of radiation on the components of cells involving highly reactive free radicals which has provided basis for developing protocols for radioprotection and cancer radiotherapy. Cellular responses are subject to nature and dose/dose rates of radiation which are eventually reflected in the severity of health effects of population. Radiobiology research has a long-standing goal in understanding the risk, prevention, and treatment of damage to normal tissue after radiation exposure of healthy populations and also, in cancer treatment. However, much remains to be learned in terms of underlying molecular process and factors controlling the radiation injury. Developing high through put diagnostic tools for detection and bio markers for assessing radiation exposures are immediate challenges for policy planners, administrators, medical experts and safety officials in the management and control of mass exposures from nuclear radiation. Present world is faced with a rather new threat scenario from radiological and nuclear attack using radiation and radioisotope material by so called determined groups. To address the threat, new research efforts are required in developing safe and effective countermeasures against radiation emergency. It has become urgent to identify the

  20. Technical Basis for Radiological Emergency Plan Annex for WTD Emergency Response Plan: West Point Treatment Plant

    Energy Technology Data Exchange (ETDEWEB)

    Hickey, Eva E.; Strom, Daniel J.

    2005-08-01

    Staff of the King County Wastewater Treatment Division (WTD) have concern about the aftermath of a radiological dispersion event (RDE) leading to the introduction of significant quantities of radioactive material into the combined sanitary and storm sewer system in King County, Washington. Radioactive material could come from the use of a radiological dispersion device (RDD). RDDs include "dirty bombs" that are not nuclear detonations but are explosives designed to spread radioactive material (National Council on Radiation Protection and Measurements (NCRP) 2001). Radioactive material also could come from deliberate introduction or dispersion of radioactive material into the environment, including waterways and water supply systems. This document, Volume 3 of PNNL-15163 is the technical basis for the Annex to the West Point Treatment Plant (WPTP) Emergency Response Plan related to responding to a radiological emergency at the WPTP. The plan primarily considers response to radioactive material that has been introduced in the other combined sanitary and storm sewer system from a radiological dispersion device, but is applicable to any accidental or deliberate introduction of materials into the system.

  1. Responsibilities and tasks of the Emergency planning organization

    International Nuclear Information System (INIS)

    Jonsson, B.

    1983-10-01

    In order to strengthen the emergency preparedness of the most essential agencies so that all types of nuclear accidents can be mastered, the following measures will be taken: - special training for decision-makers and other personnel - introduction of continuously operating staff emergency organization - introduction of a prompt radiation measurement organization - introduction of reliable telecommunications links. (author)

  2. Survey of state and tribal emergency response capabilities for radiological transportation incidents

    Energy Technology Data Exchange (ETDEWEB)

    Vilardo, F J; Mitter, E L; Palmer, J A; Briggs, H C; Fesenmaier, J [Indiana Univ., Bloomington, IN (USA). School of Public and Environmental Affairs

    1990-05-01

    This publication is the final report of a project to survey the fifty states, the District of Columbia, Puerto Rico, and selected Indian Tribal jurisdictions to ascertain their emergency-preparedness planning and capabilities for responding to transportation incidents involving radioactive materials. The survey was conducted to provide the Nuclear Regulatory Commission and other federal agencies with information concerning the current level of emergency-response preparedness of the states and selected tribes and an assessment of the changes that have occurred since 1980. There have been no major changes in the states' emergency-response planning strategies and field tactics. The changes noted included an increased availability of dedicated emergency-response vehicles, wider availability of specialized radiation-detection instruments, and higher proportions of police and fire personnel with training in the handling of suspected radiation threats. Most Indian tribes have no capability to evaluate suspected radiation threats and have no formal relations with emergency-response personnel in adjacent states. For the nation as a whole, the incidence of suspected radiation threats declined substantially from 1980 to 1988. 58 tabs.

  3. Establishment of exposure dose assessment laboratory in National Radiation Emergency Medical Center (NREMC)

    Energy Technology Data Exchange (ETDEWEB)

    Yoo, Jae Ryong; Ha, Wi Ho; Yoon, Seok Won; Han, Eun Ae; Lee, Seung Sook [Korea Institute of Radiological and Medical Sciences, Seoul (Korea, Republic of)

    2011-10-15

    As unclear industry grown, 432 of the nuclear power plants are operating and 52 of NPPs are under construction currently. Increasing use of radiation or radioisotopes in the field of industry, medical purpose and research such as non-destructive examination, computed tomography and x-ray, etc. constantly. With use of nuclear or radiation has incidence possibility for example the Fukushima NPP incident, the Goiania accident and the Chernobyl Nuclear accident. Also the risk of terror by radioactive material such as Radiological Dispersal Device(RDD) etc. In Korea, since the 'Law on protection of nuclear facilities and countermeasure for radioactive preparedness was enacted in 2003, the Korean institute of Radiological and Medical Sciences(KIRAMS) was established for the radiation emergency medical response in radiological disaster due to nuclear accident, radioactive terror and so on. Especially National Radiation Emergency Medical Center(NREMC) has the duty that is protect citizens from nuclear, radiological accidents or radiological terrors through the emergency medical preparedness. The NREMC was established by the 39-article law on physical protection of nuclear material and facilities and measures for radiological emergencies. Dose assessment or contamination survey should be performed which provide the radiological information for medical response. For this reason, the NREMC establish and re-organized dose assessment system based on the existing dose assessment system of the NREMC recently. The exposure dose could be measured by physical and biological method. With these two methods, we can have conservative dose assessment result. Therefore the NREMC established the exposure dose assessment laboratory which was re-organized laboratory space and introduced specialized equipment for dose assessment. This paper will report the establishment and operation of exposure dose assessment laboratory for radiological emergency response and discuss how to enhance

  4. Some aspects of RF radiation safety guidelines on urgent protective measures in case of radiation emergency at NPP

    International Nuclear Information System (INIS)

    Bulgakov, V.G.; Klepikova, N.V.; Shershakov, V.M.; Ivanov, E.A.

    2003-01-01

    Full text: The work is aimed at developing a decision making strategy and tools for putting into practice the principles of reasonableness and optimization when applying countermeasures in case of a radiation related accident at a nuclear power plant in RF. The presentation discusses results of the study of the legal framework in the RF for decision making to protect the personnel and public in case of a radiation-related accident Consideration is given to issues of methodological support for emergency response systems at NPPs, as required by the RF radiation safety norms to protect personnel and the public. This work was performed as part of methodological support to the national emergency center of Rosenergoatom comprising several technical support centers on the base of leading institutes with large scientific potential in the fields of nuclear power use, environmental and public protection, radioecology etc. Such centers were set up for scientific and technical support to decision making in case of emergency at NPPs. Specialists of die centers are able to quickly assess the emerging situation and propose a set of measures to minimize damage, drawing on expert judgements. The radiation safety guidelines (NRB-99) lays down requirements and criteria for decision making to protect the public in different phases of a radiation accident which should be used when implementing countermeasures and developing emergency response plans with allowance for specific situation and local conditions. These criteria provide a basis for designating areas of emergency response that would be optimum for specific population points, intervention measures etc. Dealing with these tasks requires development of normative and methodological documentation taking into account both the NRB-99 requirements and international recommendations. In accordance with NRB-99: expected and averted radiation doses are the key criteria to be used in application of any protection measures in radiation

  5. Southern states radiological emergency response laws and regulations

    International Nuclear Information System (INIS)

    1989-02-01

    The radiological emergency response laws and regulations of the Southern States Energy Compact member states are in some cases disparate. Several states have very specific laws on radiological emergency response while in others, the statutory law mentions only emergency response to ''natural disasters.'' Some states have adopted extensive regulations on the topic; others have none. For this reason, any general overview must necessarily discuss laws and regulations in general terms

  6. A model national emergency response plan for radiological accidents

    International Nuclear Information System (INIS)

    1993-09-01

    The IAEA has supported several projects for the development of a national response plan for radiological emergencies. As a results, the IAEA has developed a model National Emergency Response Plan for Radiological Accidents (RAD PLAN), particularly for countries that have no nuclear power plants. This plan can be adapted for use by countries interested in developing their own national radiological emergency response plan, and the IAEA will supply the latest version of the RAD PLAN on computer diskette upon request. 2 tabs

  7. A prototype nuclear emergency response decision making expert system

    International Nuclear Information System (INIS)

    Chang, C.; Shih, C.; Hong, M.; Yu, W.; Su, M.; Wang, S.

    1990-01-01

    A prototype of emergency response expert system developed for nuclear power plants, has been fulfilled by Institute of Nuclear Energy Research. Key elements that have been implemented for emergency response include radioactive material dispersion assessment, dynamic transportation evacuation assessment, and meteorological parametric forecasting. A network system consists of five 80386 Personal Computers (PCs) has been installed to perform the system functions above. A further project is still continuing to achieve a more complicated and fanciful computer aid integral emergency response expert system

  8. Meteorological considerations in emergency response capability at nuclear power plant

    International Nuclear Information System (INIS)

    Fairobent, J.E.

    1985-01-01

    Meteorological considerations in emergency response at nuclear power plants are discussed through examination of current regulations and guidance documents, including discussion of the rationale for current regulatory requirements related to meteorological information for emergency response. Areas discussed include: major meteorological features important to emergency response; onsite meteorological measurements programs, including redundant and backup measurements; access to offsite sources of meteorological information; consideration of real-time and forecast conditions and atmospheric dispersion modeling

  9. Aquatic emergency response model at the Savannah River Plant

    International Nuclear Information System (INIS)

    Hayes, D.W.

    1987-01-01

    The Savannah River Plant emergency response plans include a stream/river emergency response model to predict travel times, maximum concentrations, and concentration distributions as a function of time at selected downstream/river locations from each of the major SRP installations. The menu driven model can be operated from any of the terminals that are linked to the real-time computer monitoring system for emergency response

  10. Study on radiation-responsive epigenomes

    Energy Technology Data Exchange (ETDEWEB)

    Kim, Jin Hong; Chung, Byung Yeop; Lee, Seung Sik; Moon, Yu Ran; Lee, Min Hee; Kim, Ji Hong [KAERI, Daejeon (Korea, Republic of)

    2011-01-15

    The purpose of this project is development of world-class headspring techniques of biological science for application of plant genomes/epigenomes through study on radiation- responsive epigenomes and improvement of the national competitiveness in the field of fundamental technology for biological science and industry. Research scope includes 1) Investigation of radiation-responsive epigenomes and elucidation of their relation with phenotypes, 2) Elucidation of interaction and transcription control of epigenomes and epigenetic regulators using ionizing radiation (IR), 3) Investigation of epigenome-mediated traits in plant development, differentiation and antioxidant defense using IR, and 4) Development of application techniques of radiation-responsive epigenomes for eco-monitoring and molecular breeding. Main results are as follow: Setup of conditions for chromatin immunoprecipitation in irradiated plants: investigation of aberrations in DNA methylation after treatment with different IR: elucidation of responses of epigenetic regulators to gamma rays (GR): investigation of aberrations in GR-responsive epigenetic regulators at different developmental stages: elucidation of interactive aberrations of epigenomes and epigenetic regulators after treatment of GR: comparison of functional genomes after treatment of GR or H{sub 2}O{sub 2}: elucidation of relation of epigenomes with GR-induced delay in senescence: elucidation of relation of epigenomes with GR-induced aberrations in pigment metabolism: comparison of antioxidant defense in epigenetic mutants: investigation of senescence-associated changes in epigenomes: investigation of senescence-associated changes in epigenetic regulators: comparison of aberrations in epigenomes at different dose of GR for mutation.

  11. Study on radiation-responsive epigenomes

    International Nuclear Information System (INIS)

    Kim, Jin Hong; Chung, Byung Yeop; Lee, Seung Sik; Moon, Yu Ran; Lee, Min Hee; Kim, Ji Hong

    2011-01-01

    The purpose of this project is development of world-class headspring techniques of biological science for application of plant genomes/epigenomes through study on radiation- responsive epigenomes and improvement of the national competitiveness in the field of fundamental technology for biological science and industry. Research scope includes 1) Investigation of radiation-responsive epigenomes and elucidation of their relation with phenotypes, 2) Elucidation of interaction and transcription control of epigenomes and epigenetic regulators using ionizing radiation (IR), 3) Investigation of epigenome-mediated traits in plant development, differentiation and antioxidant defense using IR, and 4) Development of application techniques of radiation-responsive epigenomes for eco-monitoring and molecular breeding. Main results are as follow: Setup of conditions for chromatin immunoprecipitation in irradiated plants: investigation of aberrations in DNA methylation after treatment with different IR: elucidation of responses of epigenetic regulators to gamma rays (GR): investigation of aberrations in GR-responsive epigenetic regulators at different developmental stages: elucidation of interactive aberrations of epigenomes and epigenetic regulators after treatment of GR: comparison of functional genomes after treatment of GR or H 2 O 2 : elucidation of relation of epigenomes with GR-induced delay in senescence: elucidation of relation of epigenomes with GR-induced aberrations in pigment metabolism: comparison of antioxidant defense in epigenetic mutants: investigation of senescence-associated changes in epigenomes: investigation of senescence-associated changes in epigenetic regulators: comparison of aberrations in epigenomes at different dose of GR for mutation

  12. Lessons Learned from the Accident at the Fukushima Dai-ichi Nuclear Power Plant-More than Basic Knowledge: Education and its Effects Improve the Preparedness and Response to Radiation Emergency.

    Science.gov (United States)

    Hachiya, Misao; Akashi, Makoto

    2016-09-01

    A huge earthquake struck the northeast coast of the main island of Japan on 11 March 2011 triggering an extremely large tsunami to hit the area. The earthquake and tsunami caused serious damage to the Fukushima nuclear power plants (NPPs) of Tokyo Electric Power Company (TEPCO), resulting in large amounts of radioactive materials being released into the environment. The major nuclides released were (131)I, (134)Cs and (137)Cs. The deposition of these radioactive materials on land resulted in a high ambient dose of radiation around the NPPs, especially within a 20-km radius. Dose assessments based on behavior survey and ambient dose rates revealed that external doses to most residents were lower than 5 mSv, with the maximum dose being 25 mSv. It was fortunate that no workers from the NPPs required treatment from the viewpoint of deterministic effects of radiation. However, a lack of exact knowledge of radiation and its effects prevented the system for medical care and transportation of contaminated personnel from functioning. After the accident, demands or requests for training courses have been increasing. We have learned from the response to this disaster that basic knowledge of radiation and its effects is extremely important for not only professionals such as health care providers but also for other professionals including teachers. © World Health Organisation 2016. All rights reserved. The World Health Organization has granted Oxford University Press permission for the reproduction of this article.

  13. Nuclear emergency response planning based on participatory decision analytic approaches

    International Nuclear Information System (INIS)

    Sinkko, K.

    2004-10-01

    This work was undertaken in order to develop methods and techniques for evaluating systematically and comprehensively protective action strategies in the case of a nuclear or radiation emergency. This was done in a way that the concerns and issues of all key players related to decisions on protective actions could be aggregated into decision- making transparently and in an equal manner. An approach called facilitated workshop, based on the theory of Decision Analysis, was tailored and tested in the planning of actions to be taken. The work builds on case studies in which it was assumed that a hypothetical accident in a nuclear power plant had led to a release of considerable amounts of radionuclides and therefore different types of protective actions should be considered. Altogether six workshops were organised in which all key players were represented, i.e., the authorities, expert organisations, industry and agricultural producers. The participants were those responsible for preparing advice or presenting matters for those responsible for the formal decision-making. Many preparatory meetings were held with various experts to prepare information for the workshops. It was considered essential that the set-up strictly follow the decision- making process to which the key players are accustomed. Key players or stakeholders comprise responsible administrators and organisations, politicians as well as representatives of the citizens affected and other persons who will and are likely to take part in decision-making in nuclear emergencies. The realistic nature and the disciplined process of a facilitated workshop and commitment to decision-making yielded up insight in many radiation protection issues. The objectives and attributes which are considered in a decision on protective actions were discussed in many occasions and were defined for different accident scenario to come. In the workshops intervention levels were derived according justification and optimisation

  14. Emergency response facility technical data system of Taiwan Power Company

    International Nuclear Information System (INIS)

    Lin, E.; Liang, T.M.

    1987-01-01

    Taiwan Power Company (Taipower) has developed its emergency response facility program since 1981. This program is integrated with the following activities to enhance the emergency response capability of nuclear power plants: (1) survey of the plant instrumentation based on the requirements of R.G. 1.97; (2) improvement of plant specific emergency operating procedures based on the emergency response guidelines developed by the Owners group; (3) implementation of the detailed control room design review with the consideration of human engineering and task analysis; and (4) organization, staff and communication of emergency planning of nuclear power plant. The emergency response facility programs of Taipower are implemented in Chinshan (GE BWR4/MARK I), Kuosheng (GE BWR6/MARK III) and Maanshan (W PWR). The major items included in each program are: (1) to establish new buildings for On-Site Technical Support Center, Near-Site Emergency Operation Facility; (2) to establish an Emergency Executive Center at Taipower headquarters; (3) to establish the communication network between control room and emergency response facilities; and (4) to install a dedicated Emergency Response Facility Technical Data System (ERFTDS) for each plant. The ERFTDS provides the functions of data acquisition, data processing, data storage and display in meeting with the requirements of NUREG 0696. The ERFTDS is designed with plant specific requirements. These specific requirements are expected to be useful not only for the emergency condition but also for normal operation conditions

  15. Development of an extended framework for emergency response criteria. Interim report for comments

    International Nuclear Information System (INIS)

    2005-01-01

    Experience from response to recent nuclear and radiological emergencies has clearly demonstrated the importance of an efficient response system that includes, among other components, emergency plans, procedures, and internally consistent operational criteria. An analysis of lessons identified from recent responses has shown that a lack of crucial components in the emergency response system could result in major radiological and nonradiological consequences at the national level. One of the reasons for the overwhelming psychological consequences of the Chernobyl and Goiania emergencies was public mistrust of decision-makers, who lost their credibility by frequently changing the criteria for taking action. Moreover, national response arrangements that are incompatible among countries can result in major mistrust by the public. It is considered important to have internationally agreed criteria and guidance for emergency response established in advance of an emergency. Currently there are several IAEA safety standards that contain recommendations for response to radiation emergencies, addressing principles and response criteria. Mindful of the lessons identified from recent emergencies, the IAEA convened in November 2001 a technical committee meeting (TCM) to develop aspects of the technical basis for emergency response to radiation emergencies. At this meeting, the lessons from response to the Chernobyl, Goiania and other emergencies over the past years were examined to identify where revisions were needed to the existing international guidance for response. In particular, the existing international criteria and guidance for taking protective and other actions were examined in the light of these lessons. The objectives of this document are: (1) to propose an extension of existing criteria for undertaking protective and other actions during or following a nuclear or radiological emergency that: addresses the lessons from past emergencies, addresses the recently

  16. Development of multi copter based autonomous unmanned aerial radiation monitoring system for the remote impact assessment of radiation emergencies

    International Nuclear Information System (INIS)

    Jose, Jis Romal; Gupta, Ashutosh; Bahadur, Shuchita; Chaudhury, Probal; Pradeepkumar, K.S.

    2016-01-01

    During any radiation emergency, the level and extent of radioactive contamination need to be monitored for the timely and effective implementation of countermeasures to reduce the radiation exposure to public. In such a scenario, radiation surveillance can be carried out using either ground based mobile monitoring techniques or aerial radiation monitoring. Aerial radiation monitoring is quick and capable of scanning the areas which are not easily accessible by the ground based mobile monitoring. Compact unmanned aerial vehicle based radiation surveillance system is ideal in above mentioned radiation emergency scenarios as it can be rapidly deployed in the affected area and radiation exposure to the monitoring personal can be totally avoided. This paper describes development of multi copter based autonomous unmanned aerial radiation monitoring system for the remote impact assessment of radiation emergencies

  17. Study on radiation-responsive epigenomes

    Energy Technology Data Exchange (ETDEWEB)

    Kim, Jin Hong; Lee, Seung Sik; Bae, Hyung Woo; Kim, Ji Hong; Kim, Ji Eun; Cho, Eun Ju; Lee, Min Hee; Moon, Yu Ran [KAERI, Daejeon (Korea, Republic of)

    2012-01-15

    The purpose of this project is development of world-class headspring techniques of biological science for application of plant genomes/epigenomes through study on radiation- responsive epigenomes and improvement of the national competitiveness in the field of fundamental technology for biological science and industry. Research scope includes 1) Investigation of radiation-responsive epigenomes and elucidation of their relation with phenotypes, 2) Elucidation of interaction and transcription control of epigenomes and epigenetic regulators using IR, 3) Investigation of epigenome-mediated traits in plant development, differentiation and antioxidant defense using IR, and 4) Development of application techniques of radiation-responsive epigenomes for eco-monitoring and molecular breeding. Main results are as follow: practical application of ChIP in GR-treated Arabidopsis using anti-histone antibodies: mapping of DNA methylomes associated with GR-responsive transcriptomes: setup of methylated DNA quantification using HPLC: elucidation of aberrations in epigenetic regulation induced by low-dose GR using gamma phytotron: comparison of gene expression of histone-modifying enzymes after treatment of GR: elucidation of transcriptomes and physiological alterations associated with delayed senescence of drd1-6 mutant: comparison of gene expression of DNA methylation-related enzymes in GR-treated rice callus and Arabidopsis: investigation of germination capacity, low-temperature, salinity and drought stress-resistance in drd1-6 epigenetic mutant: investigation of aberrations in DNA methylation depending on dose rates of gamma radiation

  18. Study on radiation-responsive epigenomes

    International Nuclear Information System (INIS)

    Kim, Jin Hong; Lee, Seung Sik; Bae, Hyung Woo; Kim, Ji Hong; Kim, Ji Eun; Cho, Eun Ju; Lee, Min Hee; Moon, Yu Ran

    2012-01-01

    The purpose of this project is development of world-class headspring techniques of biological science for application of plant genomes/epigenomes through study on radiation- responsive epigenomes and improvement of the national competitiveness in the field of fundamental technology for biological science and industry. Research scope includes 1) Investigation of radiation-responsive epigenomes and elucidation of their relation with phenotypes, 2) Elucidation of interaction and transcription control of epigenomes and epigenetic regulators using IR, 3) Investigation of epigenome-mediated traits in plant development, differentiation and antioxidant defense using IR, and 4) Development of application techniques of radiation-responsive epigenomes for eco-monitoring and molecular breeding. Main results are as follow: practical application of ChIP in GR-treated Arabidopsis using anti-histone antibodies: mapping of DNA methylomes associated with GR-responsive transcriptomes: setup of methylated DNA quantification using HPLC: elucidation of aberrations in epigenetic regulation induced by low-dose GR using gamma phytotron: comparison of gene expression of histone-modifying enzymes after treatment of GR: elucidation of transcriptomes and physiological alterations associated with delayed senescence of drd1-6 mutant: comparison of gene expression of DNA methylation-related enzymes in GR-treated rice callus and Arabidopsis: investigation of germination capacity, low-temperature, salinity and drought stress-resistance in drd1-6 epigenetic mutant: investigation of aberrations in DNA methylation depending on dose rates of gamma radiation

  19. Initial Human Response to Nuclear Radiation

    Science.gov (United States)

    1982-04-01

    symptomatic response to radiation. In the second phase, the models will be used to infer performance effects. DNA staff members Cyrus Knowles and David ...P. Setty ATTN: K. Schwartz ATTN: J. NcGahan Kamn Tempo System Planning Corp ATTN: R. Miller ATTN: J. JonesATTN: G. Perks Kamen Tempo AiT: S. Shrier

  20. Responsibility structure in medical radiation applications

    International Nuclear Information System (INIS)

    Beekman, Z.M.

    1989-01-01

    The author discusses the various aspects of the responsibilities of physicians and clinical physicists with regard to radiation protection in medical applications of ionizing radiation. It becomes still clearer that the physician, who carries out the examination or the treatment, also has to bear the responsibility. this holds for the indication assessment as well as for optimization of the quality of the examination or treatment versus radiation burden of the patient, radiologic worker and thirds. Further it is clear that the physician in these will have to delegate specific tasks and responsibilities, whether or not in the elongated-arm construction. The clinical physicist is responsible in particular for the applications of the physical methods and watches the quality of the apparatus and methods used. As such he also is responsible for the technical workers, who take care of the preventive and corrective maintenance. The principal responsibility of the clinical physicist however lies in the field of standardization and calibration of medical-physical instruments. Besides this investigation into and development of new techniques, methods and apparatus come up, while also education and training of various profession groups involved need attention. (author). 6 refs.; 1 tab

  1. AECB emergency response plan - in brief

    International Nuclear Information System (INIS)

    1995-10-01

    The AECB's mission is to ensure that the use of nuclear energy in Canada does not pose undue risk to health, safety, security and the environment. The mission applies before, during and after emergencies

  2. Current status on educational program for radiation emergency medical preparedness in Korea

    International Nuclear Information System (INIS)

    Kim, E. S.; Kong, H. J.; Noh, J. H.; Kim, C. S.

    2002-01-01

    There are several educational programs in worldwide for the user of radiation, radioisotopes, and nuclear power plant. REAC/TS is one of the most famous centers for radiation emergency personnel. REMPAN, one of the World Health Organization is also to promote the medical preparedness for radiation accident and provide advice and assistance in the case of radiation accident and radiological emergency. There are a variety of educational programs of radiation emergency, but not many programs of medical preparedness in Korea. Therefore, it is introduced here Korean current environment and future direction of educational programs for the radiation emergency medical preparedness

  3. More efficient response to nuclear emergencies

    International Nuclear Information System (INIS)

    1979-12-01

    Three documents related to the first volume of this report are presented here. These are a description of the emergency provisions organisation, an analysis of the weaknesses in the present organisation and proposed improvements (with appendices on the information problem in excercises with the emergency provisions at Ringhals and attitudes to tasks connected with evacuation following a power reactor accident) and agreements with Denmark, Finland, Norway and the IAEA for mutual assistance. (JIW)

  4. radiation dosimetry in cases of normal and emergency situations

    International Nuclear Information System (INIS)

    Morsi, T.M.

    2010-01-01

    The use of radioactive materials in various fields of medicine, industry, agriculture and researches has been increasing steadily during the last few decades. A lot of radiation sources, radiopharmaceuticals, labeled compounds and other radioactive materials are sold and used throughout the world each year. Historically, accidents have occurred during the production, transport and use of radioactive materials. If an accident does occur, it is necessary to cope with it as soon as possible in order to control radiological human exposures and contamination of the environment and to restore normal conditions. Examination of individuals that deal with radioactive isotopes should be carried out in cases of nuclear medicine units, and in other applications including radiotherapy unit and gamma irradiation facility. Identification of the feasibility and efficiency of the counting detectors of internal and external radiation dosimetry, and preparedness in normal and emergency situations are included in the present work. Furthermore, this study also deals with the use of thermoluminescent dosimeters for radiation dose estimation for applications of gamma irradiation, and cobalt-60 treatment unit. Hence, operator dose can be estimated in case of malfunction or stuck of the radioactive source. Three methods were used to measure the radiation dose: (1) TL dosimeters with Harshaw (TLD- 4000) reader were used for measurement of external exposures. (2) FASTSCAN and (3) ACUUSCAN II whole body counters were used for measurement of internal exposures.

  5. The appropriateness of emergency medical service responses in the ...

    African Journals Online (AJOL)

    The appropriateness of emergency medical service responses in the eThekwini district of KwaZulu-Natal, South Africa. PR Newton, R Naidoo, P Brysiewicz. Abstract. Introduction. Emergency medical services (EMS) are sometimes required to respond to cases that are later found not to be emergencies, resulting in high ...

  6. Development of emergency response plans for community water ...

    African Journals Online (AJOL)

    All water services systems, irrespective of size, location etc., should have emergency response plans (ERPs) to guide officials, stakeholders and consumers through emergencies, as part of managing risks in the water supply system. Emergencies in the water supply system may result from, among other causes, natural ...

  7. Radiological emergency response in a medical waste treatment unit

    Energy Technology Data Exchange (ETDEWEB)

    Suzuki, Fabio F.; Boni-Mitake, Malvina; Vianna, Estanislau B.; Nicolau, Jose R.A.; Rodrigues, Demerval L. [Instituto de Pesquisas Energeticas e Nucleares (IPEN), Sao Paulo, SP (Brazil)

    2000-07-01

    Radioactive materials are largely used in medicine, research and industry. The amount of radioactive material employed in each application varies from negligible to large and it can be in sealed or non-sealed form. A medical waste treatment unit that deals only with A-type medical waste (ABNT-NBR 12808), which does not include radioactive waste, detected abnormal radiation levels in a collecting truck and the IPEN-CNEN/SP Nuclear and Radiological Emergency Response Team was called. The presence of radioactive material inside the truck was confirmed; however, its origin and nature were not possible to be determined because the truck had collected medical waste in several facilities. So, an operation in order to segregate and identify that material was carried out. During the operation, a second collecting truck presenting abnormal radiation levels arrived to the unit and the same procedure was carried out on that truck. In both situations, the contaminated objects found were infantile diapers. The radioactive waste was transported to IPEN-CNEN/SP to be managed. Samples of the radioactive materials were submitted to gamma spectrometry and the radionuclide was identified as Iodine-131. Since that attendance, similar occurrences have been frequent. These events suggest that it is necessary a better control of the radioactive waste at the generating facilities and there should be basic radioprotection orientations to the discharging patients that were submitted to nuclear medicine procedures. (author)

  8. Radiological emergency response in a medical waste treatment unit

    International Nuclear Information System (INIS)

    Suzuki, Fabio F.; Boni-Mitake, Malvina; Vianna, Estanislau B.; Nicolau, Jose R.A.; Rodrigues, Demerval L.

    2000-01-01

    Radioactive materials are largely used in medicine, research and industry. The amount of radioactive material employed in each application varies from negligible to large and it can be in sealed or non-sealed form. A medical waste treatment unit that deals only with A-type medical waste (ABNT-NBR 12808), which does not include radioactive waste, detected abnormal radiation levels in a collecting truck and the IPEN-CNEN/SP Nuclear and Radiological Emergency Response Team was called. The presence of radioactive material inside the truck was confirmed; however, its origin and nature were not possible to be determined because the truck had collected medical waste in several facilities. So, an operation in order to segregate and identify that material was carried out. During the operation, a second collecting truck presenting abnormal radiation levels arrived to the unit and the same procedure was carried out on that truck. In both situations, the contaminated objects found were infantile diapers. The radioactive waste was transported to IPEN-CNEN/SP to be managed. Samples of the radioactive materials were submitted to gamma spectrometry and the radionuclide was identified as Iodine-131. Since that attendance, similar occurrences have been frequent. These events suggest that it is necessary a better control of the radioactive waste at the generating facilities and there should be basic radioprotection orientations to the discharging patients that were submitted to nuclear medicine procedures. (author)

  9. Joint Radiation Emergency Management Plan of the International Organizations. Date Effective: 1 July 2013

    International Nuclear Information System (INIS)

    2013-01-01

    The Convention on Early Notification of a Nuclear Accident (the 'Early Notification Convention') and the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the 'Assistance Convention') are prime legal instruments that establish an international framework to facilitate the exchange of information and the prompt provision of assistance in the event of a radiation emergency, with the aim of minimizing the consequences. The International Atomic Energy Agency (IAEA) has specific functions assigned to it under these Conventions, to which the the European Commission, through the European Atomic Energy Community (Euratom), the Food and Agriculture Organization of the United Nations (FAO), the World Health Organization (WHO) and the World Meteorological Organization (WMO) are full Parties. The arrangements between the IAEA, States and international intergovernmental organizations ('international organizations') for facilitating the practical implementation of those articles of the two Conventions that are operational in nature are documented in the IAEA's Operations Manual for Incident and Emergency Communication (IEComm). In addition to the IEComm arrangements and pursuant to the obligations placed on the IAEA by the Conventions, the IAEA regularly convenes the Inter-Agency Committee on Radiological and Nuclear Emergencies (IACRNE), whose purpose is to coordinate the arrangements of the relevant international organizations for preparing for and responding to radiation incidents or emergencies. Although the Conventions assign specific response functions and responsibilities to the IAEA and the Parties, various international organizations have - by virtue of their statutory functions or of related legal instruments (including, for example, the WHO International Health Regulations 2005) - functions and responsibilities that encompass aspects of preparedness and response in this context. Moreover, some regional organizations/bodies (e.g. the

  10. Joint Radiation Emergency Management Plan of the International Organizations. Date Effective: 1 July 2013

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2013-07-01

    The Convention on Early Notification of a Nuclear Accident (the 'Early Notification Convention') and the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the 'Assistance Convention') are prime legal instruments that establish an international framework to facilitate the exchange of information and the prompt provision of assistance in the event of a radiation emergency, with the aim of minimizing the consequences. The International Atomic Energy Agency (IAEA) has specific functions assigned to it under these Conventions, to which the the European Commission, through the European Atomic Energy Community (Euratom), the Food and Agriculture Organization of the United Nations (FAO), the World Health Organization (WHO) and the World Meteorological Organization (WMO) are full Parties. The arrangements between the IAEA, States and international intergovernmental organizations ('international organizations') for facilitating the practical implementation of those articles of the two Conventions that are operational in nature are documented in the IAEA's Operations Manual for Incident and Emergency Communication (IEComm). In addition to the IEComm arrangements and pursuant to the obligations placed on the IAEA by the Conventions, the IAEA regularly convenes the Inter-Agency Committee on Radiological and Nuclear Emergencies (IACRNE), whose purpose is to coordinate the arrangements of the relevant international organizations for preparing for and responding to radiation incidents or emergencies. Although the Conventions assign specific response functions and responsibilities to the IAEA and the Parties, various international organizations have - by virtue of their statutory functions or of related legal instruments (including, for example, the WHO International Health Regulations 2005) - functions and responsibilities that encompass aspects of preparedness and response in this context. Moreover, some regional organizations/bodies (e.g. the

  11. Evaluation criteria for emergency response plans in radiological transportation

    International Nuclear Information System (INIS)

    Lindell, M.K.; Perry, R.W.

    1980-01-01

    This paper identifies a set of general criteria which can be used as guides for evaluating emergency response plans prepared in connection with the transportation of radiological materials. The development of criteria takes the form of examining the meaning and role of emergency plans in general, reviewing the process as it is used in connection with natural disasters and other nonnuclear disasters, and explicitly considering unique aspects of the radiological transportation setting. Eight areas of critical importance for such response plans are isolated: notification procedures; accident assessment; public information; protection of the public at risk; other protective responses; radiological exposure control; responsibility for planning and operations; and emergency response training and exercises. (Auth.)

  12. Functional criteria for emergency response facilities. Technical report (final)

    International Nuclear Information System (INIS)

    1981-02-01

    This report describes the facilities and systems to be used by nuclear power plant licensees to improve responses to emergency situations. The facilities include the Technical Support Center (TSC), Onsite Operational Support Center (OSC), and Nearsite Emergency Operations Facility (EOF), as well as a brief discussion of the emergency response function of the control room. The data systems described are the Safety Parameter Display System (SPDS) and Nuclear Data Link (NDL). Together, these facilities and systems make up the total Emergency Response Facilities (ERFs). Licensees should follow the guidance provided both in this report and in NUREG-0654 (FEMA-REP-1), Revision 1, for design and implementation of the ERFs

  13. Emergency response training with the BNL plant analyzer

    International Nuclear Information System (INIS)

    Cheng, H.S.; Guppy, J.G.; Mallen, A.N.; Wulff, W.

    1987-01-01

    Presented is the experience in the use of the BNL Plant Analyzer for NRC emergency response training to simulated accidents in a BWR. The unique features of the BNL Plant Analyzer that are important for the emergency response training are summarized. A closed-loop simulation of all the key systems of a power plant in question was found essential to the realism of the emergency drills conducted at NRC. The faster than real-time simulation speeds afforded by the BNL Plant Analyzer have demonstrated its usefulness for the timely conduct of the emergency response training

  14. Technology Assessment and Roadmap for the Emergency Radiation Dose Assessment Program

    Energy Technology Data Exchange (ETDEWEB)

    Turteltaub, K W; Hartman-Siantar, C; Easterly, C; Blakely, W

    2005-10-03

    A Joint Interagency Working Group (JIWG) under the auspices of the Department of Homeland Security Office of Research and Development conducted a technology assessment of emergency radiological dose assessment capabilities as part of the overall need for rapid emergency medical response in the event of a radiological terrorist event in the United States. The goal of the evaluation is to identify gaps and recommend general research and development needs to better prepare the Country for mitigating the effects of such an event. Given the capabilities and roles for responding to a radiological event extend across many agencies, a consensus of gaps and suggested development plans was a major goal of this evaluation and road-mapping effort. The working group consisted of experts representing the Departments of Homeland Security, Health and Human Services (Centers for Disease Control and the National Institutes of Health), Food and Drug Administration, Department of Defense and the Department of Energy's National Laboratories (see appendix A for participants). The specific goals of this Technology Assessment and Roadmap were to: (1) Describe the general context for deployment of emergency radiation dose assessment tools following terrorist use of a radiological or nuclear device; (2) Assess current and emerging dose assessment technologies; and (3) Put forward a consensus high-level technology roadmap for interagency research and development in this area. This report provides a summary of the consensus of needs, gaps and recommendations for a research program in the area of radiation dosimetry for early response, followed by a summary of the technologies available and on the near-term horizon. We then present a roadmap for a research program to bring present and emerging near-term technologies to bear on the gaps in radiation dose assessment and triage. Finally we present detailed supporting discussion on the nature of the threats we considered, the status of

  15. Technology Assessment and Roadmap for the Emergency Radiation Dose Assessment Program

    International Nuclear Information System (INIS)

    Turteltaub, K W; Hartman-Siantar, C; Easterly, C; Blakely, W

    2005-01-01

    A Joint Interagency Working Group (JIWG) under the auspices of the Department of Homeland Security Office of Research and Development conducted a technology assessment of emergency radiological dose assessment capabilities as part of the overall need for rapid emergency medical response in the event of a radiological terrorist event in the United States. The goal of the evaluation is to identify gaps and recommend general research and development needs to better prepare the Country for mitigating the effects of such an event. Given the capabilities and roles for responding to a radiological event extend across many agencies, a consensus of gaps and suggested development plans was a major goal of this evaluation and road-mapping effort. The working group consisted of experts representing the Departments of Homeland Security, Health and Human Services (Centers for Disease Control and the National Institutes of Health), Food and Drug Administration, Department of Defense and the Department of Energy's National Laboratories (see appendix A for participants). The specific goals of this Technology Assessment and Roadmap were to: (1) Describe the general context for deployment of emergency radiation dose assessment tools following terrorist use of a radiological or nuclear device; (2) Assess current and emerging dose assessment technologies; and (3) Put forward a consensus high-level technology roadmap for interagency research and development in this area. This report provides a summary of the consensus of needs, gaps and recommendations for a research program in the area of radiation dosimetry for early response, followed by a summary of the technologies available and on the near-term horizon. We then present a roadmap for a research program to bring present and emerging near-term technologies to bear on the gaps in radiation dose assessment and triage. Finally we present detailed supporting discussion on the nature of the threats we considered, the status of technology

  16. Scaling-up Support for Emergency Response Organizations

    NARCIS (Netherlands)

    Oomes, A.H.J.; Neef, R.M.

    2005-01-01

    We present the design of an information system that supports the process of scaling-up of emergency response organizations. This process is vital for effective emergency response but tends to go awry in practice. Our proposed system consists of multiple distributed agents that are capable of

  17. Radiation response of the central nervous system

    International Nuclear Information System (INIS)

    Schultheiss, T.E.; Kun, L.E.; Ang, K.K.; Stephens, L.C.

    1995-01-01

    This report reviews the anatomical, pathophysiological, and clinical aspects of radiation injury to the central nervous system (CNS). Despite the lack of pathognomonic characteristics for CNS radiation lesions, demyelination and malacia are consistently the dominant morphological features of radiation myelopathy. In addition, cerebral atrophy is commonly observed in patients with neurological deficits related to chemotherapy and radiation, and neurocognitive deficits are associated with diffuse white matter changes. Clinical and experimental dose-response information have been evaluated and summarized into specific recommendations for the spinal cord and brain. The common spinal cord dose limit of 45 Gy in 22 to 25 fractions is conservative and can be relaxed if respecting this limit materially reduces the probability of tumor control. It is suggested that the 5% incidence of radiation myelopathy probably lies between 57 and 61 Gy to the spinal cord in the absence of dose modifying chemotherapy. A clinically detectable length effect for the spinal cord has not been observed. The effects of chemotherapy and altered fractionation are also discussed. Brain necrosis in adults is rarely noted below 60 Gy in conventional fractionation, with imaging and clinical changes being observed generally only above 50 Gy. However, neurocognitive effects are observed at lower doses, especially in children. A more pronounced volume effect is believed to exist in the brain than in the spinal cord. Tumor progression may be hard to distinguish from radiation and chemotherapy effects. Diffuse white matter injury can be attributed to radiation and associated with neurological deficits, but leukoencephalopathy is rarely observed in the absence of chemotherapy. Subjective, objective, management, and analytic (SOMA) parameters related to radiation spinal cord and brain injury have been developed and presented on ordinal scales

  18. Radiation response of the central nervous system

    International Nuclear Information System (INIS)

    Schultheiss, T.E.; Kun, L.E.; Stephens, L.C.

    1995-01-01

    This report reviews the anatomical, pathophysiological, and clinical aspects of radiation injury to the central nervous system (CNS). Despite the lack of pathoGyomonic characteristics for CNS radiation lesions, demyelination and malacia are consistently the dominant morphological features of radiation myelopathy. In addition, cerebral atrophy is commonly observed in patients with neurological deficits related to chemotherapy and radiation, and neurocognitive deficits are associated with diffuse white matter changes. Clinical and experimental dose-response information have been evaluated and summarized into specific recommendations for the spinal cord and brain. The common spinal cord dose limit of 45 Gn in 22 to 25 fractions is conservative and can be relaxed if respecting this limit materially reduces the probability of tumor control. It is suggested that the 5% incidence of radiation myelopathy probably lies between 57 and 61 Gy to the spinal cord in the absence of dose modifying chemotherapy. A clinically detectable length effect for the spinal cord has not been observed. The effects of chemotherapy and altered fractionation are also discussed. Brain necrosis in adults is rarely noted below 60 Gy in conventional fractionation, with imaging and clinical changes being observed generally only above 50 Gy. However, neurocognitive effects are observed at lower doses, especially in children. A more pronounced volume effect is believed to exist in the brain than in the spinal cord. Tumor progression may be hard to distinguish from radiation and chemotherapy effects. Diffuse white matter injury can be attributed to radiation and associated with neurological deficits, but leukoencephalopathy is rarely observed in the absence of chemotherapy. Subjective, objective, management, and analytic (SOMA) parameters related to radiation spinal cord and brain injury have been developed and presented on ordinal scales. 140 refs., 3 figs., 6 tabs

  19. Natural products as radiation response modifiers

    International Nuclear Information System (INIS)

    Colin Seymour; Carmel Mothersill

    2007-01-01

    Complete text of publication follows. Protection of cells and organisms against low doses of radiation is a complex issue which must be considered at the level of cells, tissues and organisms. 'Protection' at one level, for example, prevention of cell death, may be adverse at another level, if it allows a damaged cell to survive and form a malignant tumour. Conversely, death of a cell carrying damage can be protective for the organism if it eliminates a damaged cell. Thus, it is important to understand the mechanisms involved in protection against radiation damage at several hierarchical levels. The use of natural products as radiation response modifiers is very attractive. Many of these compounds are readily available and their function and pharmacology is well understood. Some derive from venoms or natural defenses and are currently used in medicine, others include vitamins, antioxidants or cofactors, which are tried and tested nutritional supplements. Radiation effects may be targeted or untargeted. Radiation may interact directly within a cell causing a direct DNA lesion or it may elicit a bystander response from the irradiated cell. A bystander effect is produced when the irradiated cell apparently exhibits no damage from the radiation, but passes on a biochemical signal which induces neighbouring cells to apoptose or undergo a number of other responses usually associated with irradiation such as mutation induction, transformation, induction of ROS responses etc.. Effects induced in progeny of non-targeted cells in receipt of bystander signals include genetic instability, mini and microsatellite mutations and carcinogenesis. A key characteristic of these non targeted effects is that they occur at very low acute doses (of the order of 5mGy) and saturate so that effective prevention requires an agent which can effectively shut off the mechanism. While the mechanism is not fully known, it is thought to involve signals from irradiated cells communicating via

  20. IEA Response System for Oil Supply Emergencies (2012 update)

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2012-09-05

    Emergency response to oil supply disruptions has remained a core mission of the International Energy Agency since its founding in 1974. This information pamphlet explains the decisionmaking process leading to an IEA collective action, the measures available -- focusing on stockdraw -- and finally, the historical background of major oil supply disruptions and the IEA response to them. It also demonstrates the continuing need for emergency preparedness, including the growing importance of engaging key transition and emerging economies in dialogue about energy security.

  1. Proposal of new framework in nuclear emergency response based on problem in East Japan Great Earthquake

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2013-08-15

    In the nuclear emergency response activity in a East Japan great earthquake, the weakness the frame and the activity procedure (scheme) of the emergency response activity of our country that had been constructed after the accident of JCO became clear. Especially, it is necessary to recognize the importance of the enhancement of a prior plan after not only provision to response but also the damage to the environment occurs in the emergency for measures for restoration. Moreover, it is necessary to examine a concrete strategy about the management system strengthening of the radiation exposure at the accident. In this study, the experience and the finding in a East Japan great earthquake are arranged. The accident scenario that should be targeted is rearranged, and it proposes a new frame in the nuclear emergency response field through the requirement examinations such as the points of procedure, equipment, and the capital machine parts that lie a regulations frame of the nuclear emergency response, the activity frame of the nuclear emergency response, and materialized of the nuclear emergency response activity. (author)

  2. Proposal of new framework in nuclear emergency response based on problem in East Japan Great Earthquake

    International Nuclear Information System (INIS)

    2013-01-01

    In the nuclear emergency response activity in a East Japan great earthquake, the weakness the frame and the activity procedure (scheme) of the emergency response activity of our country that had been constructed after the accident of JCO became clear. Especially, it is necessary to recognize the importance of the enhancement of a prior plan after not only provision to response but also the damage to the environment occurs in the emergency for measures for restoration. Moreover, it is necessary to examine a concrete strategy about the management system strengthening of the radiation exposure at the accident. In this study, the experience and the finding in a East Japan great earthquake are arranged. The accident scenario that should be targeted is rearranged, and it proposes a new frame in the nuclear emergency response field through the requirement examinations such as the points of procedure, equipment, and the capital machine parts that lie a regulations frame of the nuclear emergency response, the activity frame of the nuclear emergency response, and materialized of the nuclear emergency response activity. (author)

  3. Proposal of new framework in nuclear emergency response based on problem in East Japan Great Earthquake

    International Nuclear Information System (INIS)

    2012-01-01

    In the nuclear emergency response activity in a East Japan great earthquake, the weakness the frame and the activity procedure (scheme) of the emergency response activity of our country that had been constructed after the accident of JCO became clear. Especially, it is necessary to recognize the importance of the enhancement of a prior plan after not only provision to response but also the damage to the environment occurs in the emergency for measures for restoration. Moreover, it is necessary to examine a concrete strategy about the management system strengthening of the radiation exposure at the accident. In this study, the experience and the finding in a East Japan great earthquake are arranged. The accident scenario that should be targeted is rearranged, and it proposes a new frame in the nuclear emergency response field through the requirement examinations such as the points of procedure, equipment, and the capital machine parts that lie a regulations frame of the nuclear emergency response, the activity frame of the nuclear emergency response, and materialized of the nuclear emergency response activity. (author)

  4. Medical emergency and first aid for radiation accident

    International Nuclear Information System (INIS)

    Suzuki-Yasumoto, Masashi

    1980-01-01

    The thinkings concerning the injuries to human beings in nuclear accidents differ somewhat between Japan and the U.S.A. and other European countries. In accordance with the historical evolution of nuclear power and the characteristics of medical system in respective countries, there are more or less modified measures in the scheme of three phases; i.e. first aid stations on the sites of nuclear facilities, support hospitals, and radiation injury centers, in order. So far, easy reliance on such as the National Institute of Radiological Sciences was large, but with the Three Mile Island nuclear plant accident as the turning point, the emergency and first aid systems are being studied intensively both in the Government and private nuclear power enterprises. The following matters are described: the differences in thinkings between Japan and other countries; fundamentals in the medical emergency scheme in radiation accidents; the systems in U.S.A., U.K., France and West Germany; and the problems and measures in the scheme of Japan. (J.P.N.)

  5. Development of effective emergency preparedness and response

    International Nuclear Information System (INIS)

    2012-01-01

    It has been discussed that there were many differences to international standards and the delay for prior planning implementation of unclear emergency preparedness. Therefore, it was necessary to promote the study to take the concept of the international standard to the Guide 'Emergency Preparedness for Nuclear Facilities', and to apply the Precautionary Action Zone (PAZ) etc. as the protective actions procedure. This study was started since the fiscal year 2010 to enhance the effectiveness of the protective actions, which are corresponding to these requirements based on international aspects in the nuclear disaster occurrence. And the study was conducted to introduce the emergency action level (EAL) as decision criteria and to apply urgent protective action considering PAZ, and the results from this study will be used as the basic data necessary to modify and improve the Guide. In order to fulfill the purposes described above, in fiscal year 2011, followings are executed, (1) analysis and verification for basic evacuation area such as the PAZ, (2) analysis with regard to the EAL and prototype of protective actions for public, and (3) analysis with regard to prototype of protective actions for public including evacuation plan. However, taking account of the significance of the Fukushima Daiichi Nuclear Power Plant accident, Japanese emergency preparedness strategy should be studied and reconstructed in logically, systematically, and with international standard, but also being based on the reflection of individual lessons from this accident. (author)

  6. Capabilities for Clinical Management of Radiation Injuries of the Nikiforov Russian Center of Emergency and Radiation Medicine (EMERCOM of Russia)

    International Nuclear Information System (INIS)

    Aleksanin, S.

    2016-01-01

    This article presents an overview of the capabilities for clinical management of radiation injuries available at the Nikiforov Russian Center of Emergency and Radiation Medicine (NRCERM) of the Ministry of the Russian Federation for Civil Defense, Emergencies and Elimination of Consequences of Natural Disasters (EMERCOM). NRCERM is a federal state budgetary institution and the Russian Federation's head organization for providing medical assistance for persons overexposed to ionizing radiation, responders to radiation emergencies and people evacuated from radiation contaminated areas. As the WHO Collaborating Center for Treatment and Rehabilitation of Accident Recovery Workers of Nuclear and Other Disasters and a member of the WHO Radiation Emergency Medical Preparedness and Assistance Network (REMPAN), NRCERM is prepared to provide assistance and technical support in case of a radiation accident. For this purpose, NRCERM hospitals are equipped with technologically advanced facilities and possess well-trained specialist staff. (authors)

  7. Initial activities of a radiation emergency medical assistance team to Fukushima from Nagasaki

    International Nuclear Information System (INIS)

    Matsuda, Naoki; Yoshida, Kouji; Nakashima, Kanami; Iwatake, Satoshi; Morita, Naoko; Ohba, Takashi; Yusa, Takeshi; Kumagai, Atsushi; Ohtsuru, Akira

    2013-01-01

    As an urgent response to serious radiological accidents in the Fukushima Daiichi nuclear power plant, the radiation emergency medical assistance team (REMAT) from Nagasaki University landed at Fukushima on March 14, 2011, two days after the initiation of radiation crisis by the hydrogen explosion at Unit-1 reactor. During a succession of unexpected disasters, REMAT members were involved in various activities for six days, such as setting the base for radiological triage at the Fukushima Medical University, considerations for administration of stable iodine, and risk communication with health care workers. This report briefly describes what happened around REMAT members and radiation doses measured during their activities. -- Highlights: ► The radiation emergency medical assistance team from Nagasaki was sent to Fukushima. ► The practical action level for body surface contamination was 100 kcpm. ► The ambient radiation dose in Fukushima drastically elevated on March 15, 2011. ► Higher than 10 kBq of I-131, Cs-134, and Cs-137 were detected in soil samples. ► The effective dose of the team members ranged between 51.7 and 127.8 μSv in 6 days

  8. Radiological emergency: road map for radiation accident victim transport; Emergência radiológica: roadmap para o transporte de radioacidentado

    Energy Technology Data Exchange (ETDEWEB)

    Costa, V.S.G.; Alcantara, Y.P. [Faculdade Casa Branca, SP (Brazil); Lima, C.M.A. [MAXIM Cursos, Rio de Janeiro, RJ (Brazil); Silva, F. C. A. da, E-mail: franciscodasilva13uk@gmail.com [Instituto de Radioproteção e Dosimetria (IRD/CNEN-RJ), Rio de Janeiro, RJ (Brazil)

    2017-07-01

    During a radiological or nuclear emergency, a number of necessary actions are taken, both within the radiation protection of individuals and the environment, involving many institutions and highly specialized personnel. Among them it is possible to emphasize the air transportation of radiation accident victims.The procedures and measures for the safe transport of these radiation accident victims are generally the responsibility of the armed forces, specifically the Aeronautics, with the action denominated 'Aeromedical Military Evacuation of Radiation Accident Victims'. The experience with the Radiological Accident of Goiânia demonstrated the importance of adequate preparation and response during a radiological emergency and the need for procedures and measures with regard to the transport of radiation victims are clearly defined and clearly presented for the effectiveness of the actions. This work presents the necessary actions for the transport of radiation accident victim during a radiological emergency, through the road map technique, which has been widely used in scientific technical area to facilitate understanding and show the way to be followed to reach the proposed objectives.

  9. Emergency notification and assistance technical operations manual. Emergency preparedness and response. Date effective: 1 December 2002

    International Nuclear Information System (INIS)

    2002-11-01

    The Convention on Early Notification of a Nuclear Accident (the 'Early Notification Convention') and the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the 'Assistance Convention') are the prime legal instruments that establish an international framework to facilitate the exchange of information and the prompt provision of assistance in the event of a nuclear accident or radiological emergency, with the aim of minimizing their consequences. The International Atomic Energy Agency (IAEA) has specific functions assigned to it under these Conventions, to which, in addition to a large number of States (Section 1.7), the World Health Organization (WHO), the World Meteorological Organization (WMO) and the Food and Agriculture Organization of the United Nations (FAO) are full parties. The arrangements between the IAEA, States that are IAEA Member States and/or Parties to one or both Conventions, all other relevant international intergovernmental organizations, and other States for facilitating the implementation of these Conventions specifically concerning those articles that are operational in nature - are documented in the Emergency Notification and Assistance Technical Operations Manual (ENATOM). In 2000, a complete revision of ENATOM, with all relevant sections updated, withdrawn or replaced with new material, was reissued as EPR-ENATOM (2000) to reflect new technological developments, operational concepts, views on standards in the area of emergency preparedness and response, and Member States' expectations. A separate publication, EPR-JPLAN (2000), the Joint Radiation Emergency Management Plan of the International Organizations (Joint Plan'), described a common understanding of how each of six co-sponsoring international organizations will act during a response and in making preparedness arrangements. It is intended that the ENATOM is reviewed and reissued biennially in line with the review cycle of the Joint Plan. Since the

  10. Value Chain Responsibility in Emerging Technologies

    NARCIS (Netherlands)

    Bos, Colette; van Lente, Harro

    2014-01-01

    Corporate social responsibility (CSR) and value chain responsibility (VCR) have gained increasing importance for firms. The literature on these topics reports on CSR practices for established firms with existing technologies and stable value chains. This raises questions about the viability of CSR

  11. Development of national level preparedness for response to nuclear and radiological emergencies

    International Nuclear Information System (INIS)

    Pradeepkumar, K.S.

    2014-01-01

    In India, DAE being the nodal agency for technical support for response to any radiation emergency nuclear disaster and various nuclear and radiological emergency scenarios and their impacts are identified. To reduce their consequences development of methodologies for detection and quick impact assessment, trained First Responders and Quick Response Teams (QRTs), twenty two DAE Emergency Response Centers, mobile and aerial radiation monitoring systems, aerial and ground based validation trials etc. are carried out. Study related to radiological threats and simulated RDD experiments conducted using stable isotopes indicates that radiation levels for distances more than 50 m will not be very high as hotspots may be restricted to nearby area. The biggest challenge from an RDD explosion will be handling of the radioactive contamination and 'fear factor' compared to radiation exposure to public or First Responders. Level and pattern of radioactive contamination on ground following releases during nuclear accidents and minimum strength of orphan radioactive sources to be detected are taken into account for optimizing systems and monitoring methodology required for emergency preparedness

  12. Irregular radiation response of a chondrosarcoma

    International Nuclear Information System (INIS)

    Marsden, J.J.; Kember, N.F.; Shaw, J.E.H.

    1980-01-01

    The DC II mouse chondrosarcoma was shown to be a potentially valuable radiobiological tumour system since it recovered from radiation injury by regrowth from clones that could be counted in histological sections. Unfortunately, the normal growth of this tumour following s.c. implantation in the thigh was irregular both in the time before growth became evident and in the rate of growth. The response to radiation was also unreliable since tumours irradiated with the same dose (e.g. 30 Gy) showed a range of responses from shrinkage to no detectable change in growth rate. The delay in normal growth can be attributed largely to delays in vascularization while changes in growth rate may be explained by differences in tumour architecture. Radiation response may depend on variations in hypoxic fraction and in relative cellularity. Tumours having the same external dimensions may differ by a factor of 80 in the numbers of tumour cells they contain. This chondrosarcoma may prove a closer model to some human tumours than many transplantable tumours that display regular growth patterns. (author)

  13. Study on radiation-responsive epigenomes

    Energy Technology Data Exchange (ETDEWEB)

    Lee, Seung Sik; Lee, Seung Sik; Chung, Byung Yeoup; and others

    2013-01-15

    The purpose of this project is development of world-class head spring techniques of biological science for application of plant genomes/epigenomes through study on radiation-responsive epigenomes and improvement of the national competitiveness in the field of fundamental technology for biological science and industry. Research scope includes 1) Investigation of radiation-responsive epigenomes and elucidation of their relation with phenotypes, 2) Elucidation of interaction and transcription control of epigenomes and epigenetic regulators using IR, 3) Investigation of epigenome-mediated traits in plant development, differentiation and antioxidant defense using IR, and 4) Development of application techniques of radiation-responsive epigenomes for eco-monitoring and molecular breeding. Main results are as follow: investigation of the expression level of histone-modifying enzymes by IR; elucidation of the structural and functional changes of chaperone protein by IR; development of transgenic plant (DRD1-6); investigation of transcription control of epigenetic regulators by IR; investigation of relevance between DNA methylation and miRNA; comparison of gene expression in wild type and cmt mutant from Arabidopsis using gene chip; investigation control of epigenetic regulators in drd1-6 mutant by drought stress; development of transgenic plant using epigenetic regulators.

  14. Science in Emergency Response at CDC: Structure and Functions.

    Science.gov (United States)

    Iskander, John; Rose, Dale A; Ghiya, Neelam D

    2017-09-01

    Recent high-profile activations of the US Centers for Disease Control and Prevention (CDC) Emergency Operations Center (EOC) include responses to the West African Ebola and Zika virus epidemics. Within the EOC, emergency responses are organized according to the Incident Management System, which provides a standardized structure and chain of command, regardless of whether the EOC activation occurs in response to an outbreak, natural disaster, or other type of public health emergency. By embedding key scientific roles, such as the associate director for science, and functions within a Scientific Response Section, the current CDC emergency response structure ensures that both urgent and important science issues receive needed attention. Key functions during emergency responses include internal coordination of scientific work, data management, information dissemination, and scientific publication. We describe a case example involving the ongoing Zika virus response that demonstrates how the scientific response structure can be used to rapidly produce high-quality science needed to answer urgent public health questions and guide policy. Within the context of emergency response, longer-term priorities at CDC include both streamlining administrative requirements and funding mechanisms for scientific research.

  15. Nonlinear response matrix methods for radiative transfer

    International Nuclear Information System (INIS)

    Miller, W.F. Jr.; Lewis, E.E.

    1987-01-01

    A nonlinear response matrix formalism is presented for the solution of time-dependent radiative transfer problems. The essential feature of the method is that within each computational cell the temperature is calculated in response to the incoming photons from all frequency groups. Thus the updating of the temperature distribution is placed within the iterative solution of the spaceangle transport problem, instead of being placed outside of it. The method is formulated for both grey and multifrequency problems and applied in slab geometry. The method is compared to the more conventional source iteration technique. 7 refs., 1 fig., 4 tabs

  16. Quartz gauge response in ion radiation

    International Nuclear Information System (INIS)

    Taylor, P.E.; Gilbert, P.H.; Kernthaler, C.; Anderson, M.U.

    1995-01-01

    This paper describes recent work to make high quality quartz gauge (temporal and spatial) shock wave measurements in a pulsed ion beam environment. Intense ion beam radiation, nominally 1 MeV protons, was deposited into material samples instrumented with shunted quartz gauges adjacent to the ion deposition zone. Fluence levels were chosen to excite three fundamentally different material response modes (1) strong vapor, (2) combined vapor and melt phase and (3) thermoelastic material response. A unique quartz gauge design was utilized that employed printed circuit board (PCB) technology to facilitate electrical shielding, ruggedness, and fabrication at sign e meeting the essential one dimensional requirements of the characterized Sandia shunted quartz gauge. Shock loading and unloading experiments were conducted to evaluate the piezoelectric response of the coupled quartz gauge/PCB transducer. High fidelity shock wave profiles were recorded at the three ion fluence levels providing dynamic material response data for vapor, melt and solid material phases

  17. Radiation response of Philippine natural rubber latex

    International Nuclear Information System (INIS)

    Dela Rosa, A.M.; Abad, L.V.; Ana-Relleve, L.S.; Tranquilan-Aranilla, C.; Pascual, C.L.

    1998-01-01

    Our earlier work has shown that the natural rubber latex (NRL) produced and processed in the Philippines is suited for radiation vulcanization. The cast films from NRL with 50% TSC exhibited maximum tensile strengths of 25-32 MPa at 15 kGy, which is the vulcanization dose or Dv. In the manufacture of dipped NRL products, certain specifications such as %TSC, protein content and tensile properties, must be met to ensure an acceptable product. For radiation vulcanization of natural rubber latex (RVNRL) to be accepted as an alternative process, it must also meet the requirements. Thus, this paper presents additional data on the radiation response of local NRL at different total solids contents (TSC), leachable proteins from NRL films as a function of dose, and the thermal activities of irradiated natural rubber latex (INRL). Different formulations of NRL showed varying tolerances to nBA. Data showed that as %TSC increases, the maximum concentration of nBA that can be added without affecting the stability of the latex decreases. The Dv increases as the %TSC increases and the nBA content decreases. This difference in response may be attributed to a lower concentration of nBA in formulations with higher %TSC. These data indicate that the parameters in the radiation treatment will be dictated by the intended applications of INRL. The thermogravimetric data showed greater stability of INRL to thermal oxidation relative to the unirradiated NRL, which correlates directly with the tensile properties of the INRL. A radiation dose of 10 kGy increased the amount of proteins leached from cast latex films. The amount of extractable proteins did not increase significantly at higher doses. The SDS PAGE analysis of the extractable proteins from unirradiated latex film showed distinct bands. An additional band at 60 Kda appeared at 10 kGy. All these bands became diffuse at higher doses, indicating the radiolysis of the proteins

  18. Updating Dosimetry for Emergency Response Dose Projections.

    Science.gov (United States)

    DeCair, Sara

    2016-02-01

    In 2013, the U.S. Environmental Protection Agency (EPA) proposed an update to the 1992 Protective Action Guides (PAG) Manual. The PAG Manual provides guidance to state and local officials planning for radiological emergencies. EPA requested public comment on the proposed revisions, while making them available for interim use by officials faced with an emergency situation. Developed with interagency partners, EPA's proposal incorporates newer dosimetric methods, identifies tools and guidelines developed since the current document was issued, and extends the scope of the PAGs to all significant radiological incidents, including radiological dispersal devices or improvised nuclear devices. In order to best serve the emergency management community, scientific policy direction had to be set on how to use International Commission on Radiological Protection Publication 60 age groups in dose assessment when implementing emergency guidelines. Certain guidelines that lend themselves to different PAGs for different subpopulations are the PAGs for potassium iodide (KI), food, and water. These guidelines provide age-specific recommendations because of the radiosensitivity of the thyroid and young children with respect to ingestion and inhalation doses in particular. Taking protective actions like using KI, avoiding certain foods or using alternative sources of drinking water can be relatively simple to implement by the parents of young children. Clear public messages can convey which age groups should take which action, unlike how an evacuation or relocation order should apply to entire households or neighborhoods. New in the PAG Manual is planning guidance for the late phase of an incident, after the situation is stabilized and efforts turn toward recovery. Because the late phase can take years to complete, decision makers are faced with managing public exposures in areas not fully remediated. The proposal includes quick-reference operational guidelines to inform re-entry to

  19. WORTMANNIN affect cellular response by radiation

    International Nuclear Information System (INIS)

    Li Yu; Li Bailong

    2010-01-01

    Objective: To observe radiation Response of cells by WORTMANNIN (WT), which is inhibitor for Phosphatidylinositol-3 Kinase (PI-3K). Methods: LP3 cells are prepared with different concentration of WT for 1 hour and receive different dose γ irradiation. To continue the cell for clone culture, and get the production of dose-survival curve. 1800 pulsed-field gel electrophoresis is used to detect DNA double-strand breaks after the 20 Gy γ irradiation. Continue to use the mobility shift assays (Electrophoresis Mobility Shift Assay, EMSA) to observe NF-kB transcription factor of the corresponding changes. Result: WT can be found to increase the radiation sensitivity of SP3 cells, the best sensitizer concentration in 20 μmol /L or more, obvious sensitizing effect within 6 h time; the electrophoresis experiments showed that after irradiation with time, by 50 μmol /L WT group DNA the gel is higher than that of the simple exposure group; transcription factor NF-kB binding activity in the 6 hours after exposure experiences a low-rise and then the process of rising with its the peak of the change reaching after about 3 hours after irradiation. Conclusion: It suggests the existence of PI-3K-mediated radiation sensitizer pathways. Ionizing radiation may activate NF-kB, which caused some DNA damage repair and other defense mechanisms and cell-related gene activity in order to reduce radiation damage. WT may block this process through the early stages of radiation-sensitizing effect. (authors)

  20. The development of nuclear power and emergency response

    International Nuclear Information System (INIS)

    Pan Ziqiang

    2007-01-01

    Nuclear power is a safe, clean energy, which has been evidenced by the history of nuclear power development. Nuclear power is associated with very low risk but not equal to zero. Accident emergency response and preparedness is a final barrier necessary to reduce potential risks that may arise from nuclear power plants, which must be enhanced. In the course of accident emergency response and preparedness, it is highly necessary to draw domestic and foreign experiences and lessons. Lastly, the paper presents the discussions of some issues which merit attention with respect to emergency response and preparedness in China. (authors)

  1. An advanced system for environmental emergency response

    Energy Technology Data Exchange (ETDEWEB)

    Ellis, James S.; Sullivan, Thomas J. [Lawrence Livermore National Laboratory, Livermore, California (United States)

    2000-05-01

    The Atmospheric Release Advisory Capability, better known as ARAC, is a hybrid system of models, computers, databases, communications and highly skilled staff dedicated to emergency consequence analysis and prediction of atmospheric hazardous material releases. The ARAC system is located at and operated by Lawrence Livermore National Laboratory (in Livermore, California, USA). It's development and operational support for the U.S. government have been funded by the U.S. Departments of Energy and Defense for the purpose of providing real-time, down-wind consequence assessments for emergency responders and managers for radiological and other hazardous releases. This service is available for both fixed facilities and any location in the world whenever and wherever the U.S. government has interest or concern. Over the past 26 years ARAC has provided consequence assessments for more than 160 potential and actual hazardous releases. This capability has been applied to diverse real-world releases such as the 1978 reentry of the COSMOS 954 nuclear powered satellite over Canada, the Three Mile Island and Chernobyl nuclear powerplant accidents, the Tomsk nuclear facility accident in Russia, two radiological accidents at Tokai (Japan) the Algeciras (Spain) melt of a radiotherapy source, and several non-radiological events such as chemical releases, toxic fires including the Kuwait oil fires, and even volcanic ash emissions. (author)

  2. Estimating Derived Response Levels at the Savannah River Site for Use with Emergency Response Models

    International Nuclear Information System (INIS)

    Simpkins, A.A.

    2002-01-01

    Emergency response computer models at the Savannah River Site (SRS) are coupled with real-time meteorological data to estimate dose to individuals downwind of accidental radioactive releases. Currently, these models estimate doses for inhalation and shine pathways, but do not consider dose due to ingestion of contaminated food products. The Food and Drug Administration (FDA) has developed derived intervention levels (DIL) which refer to the radionuclide-specific concentration in food present throughout the relevant period of time, with no intervention, that could lead to an individual receiving a radiation dose equal to the protective action guide. In the event of an emergency, concentrations in various food types are compared with these levels to make interdictions decisions. Prior to monitoring results being available, concentrations in the environmental media (i.e. soil), called derived response levels (DRLs), can be estimated from the DILs and directly compared with computer output to provide preliminary guidance as to whether intervention is necessary. Site-specific derived response levels (DRLs) are developed for ingestion pathways pertinent to SRS: milk, meat, fish, grain, produce, and beverage. This provides decision-makers with an additional tool for use immediately following an accident prior to the acquisition of food monitoring data

  3. Method for Developing a Communication Strategy and Plan for a Nuclear or Radiological Emergency. Emergency Preparedness and Response. Publication Date: July 2015

    International Nuclear Information System (INIS)

    2015-08-01

    The aim of this publication is to provide a practical resource for emergency planning in the area of public communication in the development of a radiation emergency communication plan (RECP). The term 'public communication' is defined as any activity that communicates information to the public and the media during a nuclear or radiological emergency. To avoid confusion, the term public communication has been used in this publication rather than public information, which may be used in other IAEA publications and documents to ensure consistency with the terminology used in describing the command and control system. This publication also aims to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(11) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research with regard to the response to nuclear or radiological emergencies. This publication is intended to provide guidance to national and local authorities on developing an RECP which incorporates the specific functions, arrangements and capabilities that will be required for public communication during a nuclear or radiological emergency. The two main features of this publication are the template provided to develop an RECP and detailed guidance on developing a communication strategy for emergency preparedness and response to nuclear or radiological emergencies. The template is consistent with the outline of the national radiation emergency plan proposed in Method for Developing Arrangements for Response to a Nuclear or Radiological Emergency (EPR-Method 2003). This publication is part of the IAEA

  4. Exploring mHealth Participation for Emergency Response Communities

    Directory of Open Access Journals (Sweden)

    David G. Schwartz

    2017-03-01

    Full Text Available We explore the challenges of participation by members of emergency response communities who share a similar condition and treatment, and are called upon to participate in emergency events experienced by fellow members. Smartphones and location-based social networking technologies present an opportunity to re-engineer certain aspects of emergency medical response. Life-saving prescription medication extended in an emergency by one individual to another occurs on a micro level, anecdotally documented. We illustrate the issues and our approach through the example of an app to support patients prone to anaphylaxis and prescribed to carry epinephrine auto-injectors. We address unique participation challenges in an mHealth environment in which interventions are primarily short-term interactions which require clear and precise decision-making and constant tracking of potential participants in responding to an emergency medical event. The conflicting effects of diffused responsibility and shared identity are identified as key factors in modeling participation.

  5. First response to transportation emergencies involving radioactive materials

    International Nuclear Information System (INIS)

    1994-01-01

    This FEMA/DOE/DOT videocourse describes the basis for procedures to be used by emergency first responders for transportation accidents which involve radioactive materials. Various commercial and government sector radioactive materials shipment programs will be described and will include information about hazards and the elements of safety, proper first response actions, notification procedures, and state or federal assistance during emergencies. Primary audience: fire service and emergency management personnel

  6. Emergency response planning for transport accidents involving radioactive materials

    International Nuclear Information System (INIS)

    1982-03-01

    The document presents a basic discussion of the various aspects and philosophies of emergency planning and preparedness along with a consideration of the problems which might be encountered in a transportation accident involving a release of radioactive materials. Readers who are responsible for preparing emergency plans and procedures will have to decide on how best to apply this guidance to their own organizational structures and will also have to decide on an emergency planning and preparedness philosophy suitable to their own situations

  7. Emergency response during the radiological control of scraps in Cuba

    International Nuclear Information System (INIS)

    Ramos Viltre, Enma O.; Cardenas Herrera, Juan; Dominguez Ley, Orlando; Capote Ferrera, Eduardo; Fernandez Gomez, Isis M.; Caveda Ramos, Celia; Carrazana, Jorge; Barroso Perez, Idelisa

    2008-01-01

    In the last few years, in the international scene, incidents have been reported due to the presence of radioactive materials in the scrap. This reality has motivated the adoption of measures of radiological security, due to the implications that these incidents have for the public and the environment, as well as for the international trade. Among theses actions is the implementation of the radiological control of scrap, with the additional requirement that this control has to be implemented in the framework of a Quality Management Program.Taking into account the international experience, our institution designed and organized in 2002 a national service for the radiological monitoring of scrap, being the clients the main exporting and trading enterprises of this material in the country. During these years, several contaminated materials have been detected, causing incidents that activated the radiological emergency response system. In this sense, since some years ago, our country has been working in the implementation of a national and ministerial system for facing and mitigating the consequences of accidental radiological situations, conjugating efforts and wills from different national institutions with the leadership of the Center of Radiation Protection and Hygiene (CPHR) and the Center of Nuclear Security (CNSN) in correspondence with the social responsibility assigned to the them. These incidents propitiate to have not only a system of capacity and quick response oriented to limit the exposure of people, to control the sources, to mitigate the consequences of the accident and to reestablish the conditions of normality, but also a previous adequate planning that guarantees the speed and effectiveness of it. In these work the experiences reached by the specialists of the CPHR from Cuba during the occurrence of an incident in the execution of the service of radiological monitoring of scraps are exposed. (author)

  8. Nuclear accident/radiological emergency assistance plan. NAREAP - edition 2000. Emergency preparedness and response

    International Nuclear Information System (INIS)

    2000-01-01

    The purpose of the Nuclear Accident/Radiological Emergency Assistance Plan (NAREAP) is to describe the framework for systematic, integrated, co-ordinated, and effective preparedness and response for a nuclear accident or radiological emergency involving facilities or practices that may give rise to a threat to health, the environment or property. The purpose of the NAREAP is: to define the emergency response objectives of the Agency's staff in a nuclear accident or a radiological emergency; to assign responsibilities for performing the tasks and authorities for making the decisions that comprise the Agency staff's response to a nuclear accident or radiological emergency; to guide the Agency managers who must ensure that all necessary tasks are given the necessary support in discharging the Agency staff responsibilities and fulfilling its obligations in response to an emergency; to ensure that the development and maintenance of detailed and coherent response procedures are well founded; to act as a point of reference for individual Agency staff members on their responsibilities (as an individual or a team member) throughout a response; to identify interrelationships with other international intergovernmental Organizations; and to serve as a training aid to maintain readiness of personnel. The NAREAP refers to the arrangements of the International Atomic Energy Agency and of the United Nations Security and Safety Section at the Vienna International Centre (UNSSS-VIC) that may be necessary for the IAEA to respond to a nuclear accident or radiological emergency, as defined in the Early Notification and Assistance Conventions. It covers response arrangements for any situation that may have actual, potential or perceived radiological consequences and that could require a response from the IAEA, as well as the arrangements for developing, maintaining and exercising preparedness. The implementing procedures themselves are not included in the NAREAP, but they are required

  9. 77 FR 23161 - Onsite Emergency Response Capabilities

    Science.gov (United States)

    2012-04-18

    ... Operating Procedures B. Severe Accident Management Guidelines C. Extensive Damage Mitigation Guidelines D... the EOPs. B. Severe Accident Management Guidelines During the 1990s, the nuclear industry developed Severe Accident Management Guidelines (SAMGs) as a voluntary industry initiative in response to Generic...

  10. 45 CFR 673.5 - Emergency response plan.

    Science.gov (United States)

    2010-10-01

    ... ensure that: (a) The vessel owner's or operator's shipboard oil pollution emergency plan, prepared and... Pollution from Ships, 1973, as modified by the Protocol of 1978 relating thereto (MARPOL 73/78), has provisions for prompt and effective response action to such emergencies as might arise in the performance of...

  11. Report of the emergency preparedness and response task force

    International Nuclear Information System (INIS)

    Dynes, R.R.; Purcell, A.H.; Wenger, D.E.; Stern, P.S.; Stallings, R.A.; Johnson, Q.T.

    1979-10-01

    The accident at Three Mile Island (TMI) marked the first time in the US when traditional planning for emergencies was applied to a possible radiological emergency. This report examines the planning that existed in the counties surrounding the plant and at the state and federal levels. It also examines the responses of the various governmental units following the initial accident

  12. Report of the Emergency Preparedness and Response Task Force

    International Nuclear Information System (INIS)

    Dynes, R.R.; Purcell, A.H.; Wenger, D.E.; Stern, P.S.; Stallings, R.A.; Johnson, Q.T.

    1979-10-01

    The accident at Three Mile Island (TMI) marked the first time in the US when traditional planning for emergencies was applied to a possible radiological emergency. This report examines the planning that existed in the counties surrounding the plant and at the state and federal levels. It also examines the responses of the various governmental units following the initial accident

  13. Emergency Response Capability Baseline Needs Assessment - Requirements Document

    Energy Technology Data Exchange (ETDEWEB)

    Sharry, J A

    2016-10-04

    This document was prepared by John A. Sharry, LLNL Fire Marshal and LLNL Division Leader for Fire Protection and reviewed by LLNL Emergency Management Department Head James Colson. The document follows and expands upon the format and contents of the DOE Model Fire Protection Baseline Capabilities Assessment document contained on the DOE Fire Protection Web Site, but only addresses emergency response.

  14. General RMP Guidance - Chapter 8: Emergency Response Program

    Science.gov (United States)

    If you have a Program 2 or 3 process at your facility, 40 CFR Part 68 (risk management program) requires an emergency response program in place if employees respond to some releases involving regulated toxic or flammable substances.

  15. Simulation of operators' response in emergencies

    International Nuclear Information System (INIS)

    Rasmussen, J.

    1986-09-01

    For the simulation of the accidential course of events in industrial process plants, a model is needed of operators' response to the cues presented by the system. A model is proposed, based on the simplifications which can be made when restricting attention to the operator functions having significants for a probabilistic risk analysis, and to anly skill and rule based performance, i.e., to responses in the early phase of an accident. The model is based on Brunswik's lens model, a model of the normal task repertoire, and on a taxonomy of human errors. To bring the model in perspective, a review of the state of the art of cognitive models of human behaviour is included. (author)

  16. Simulation of Operators' Response in Emergencies

    DEFF Research Database (Denmark)

    Rasmussen, Jens

    1986-01-01

    significants for a probabilistic risk analysis, and to only skill and rule based performance, i.e., to responses in the early phase of an accident. The model is based on Brunswik's lens model, a model of the normal task repertoire, and on a taxonomy of human errors. To bring the model in perspective, a review...... of the state of the art of cognitive models of human behaviour is included....

  17. Wide Range Portable Radiation Survey Meter for Emergency Monitoring

    Energy Technology Data Exchange (ETDEWEB)

    Gangadharan, P.; Bhave, D. G.; Gokarn, R. S.; Khadake, R. G. [Directorate Of Radiation Protection, Bhabha Atomic Research Centre, Trombay, Bombay (India)

    1969-05-15

    The paper describes a portable battery-operated radiation survey meter for monitoring a wide range of X- and gamma-ray exposure rates from 1 mR/h to 100 R/h. The instrument Incorporates a halogen GM tube as the detector and a count-rate meter for indication. A transistorized d.c. -d.c. converter supplies the necessary high voltage to the GM counter. The instrument response has been made energy independent in the energy range 80 keV to 1.25 MeV. Further, the response is linear over the entire range of exposure rates. Suitable extension rods have been designed to provide sufficient separation between the probe and the meter in cases where remote monitoring is necessary because of high fields. (author)

  18. The Dose Response Relationship for Radiation Carcinogenesis

    Science.gov (United States)

    Hall, Eric

    2008-03-01

    Recent surveys show that the collective population radiation dose from medical procedures in the U.S. has increased by 750% in the past two decades. It would be impossible to imagine the practice of medicine today without diagnostic and therapeutic radiology, but nevertheless the widespread and rapidly increasing use of a modality which is a known human carcinogen is a cause for concern. To assess the magnitude of the problem it is necessary to establish the shape of the dose response relationship for radiation carcinogenesis. Information on radiation carcinogenesis comes from the A-bomb survivors, from occupationally exposed individuals and from radiotherapy patients. The A-bomb survivor data indicates a linear relationship between dose and the risk of solid cancers up to a dose of about 2.5 Sv. The lowest dose at which there is a significant excess cancer risk is debatable, but it would appear to be between 40 and 100 mSv. Data from the occupation exposure of nuclear workers shows an excess cancer risk at an average dose of 19.4 mSv. At the other end of the dose scale, data on second cancers in radiotherapy patients indicates that cancer risk does not continue to rise as a linear function of dose, but tends towards a plateau of 40 to 60 Gy, delivered in a fractionated regime. These data can be used to estimate the impact of diagnostic radiology at the low dose end of the dose response relationship, and the impact of new radiotherapy modalities at the high end of the dose response relationship. In the case of diagnostic radiology about 90% of the collective population dose comes from procedures (principally CT scans) which involve doses at which there is credible evidence of an excess cancer incidence. While the risk to the individual is small and justified in a symptomatic patient, the same is not true of some screening procedures is asymptomatic individuals, and in any case the huge number of procedures must add up to a potential public health problem. In the

  19. An expert system for emergency response

    International Nuclear Information System (INIS)

    Sebo, D.

    1989-01-01

    An expert system, the Reactor Safety Assessment System (RSAS), is being developed by the Idaho National Engineering Laboratory and the US Nuclear Regulatory Commission (NRC) for the NRC Operations Center. The RSAS is intended to aid the reactor safety team (RST) at the operations center in monitoring and projecting core and containment status during an emergency at a licensed nuclear power plant. The RSAS system development has two major aspects. The first is the compilation and storage of knowledge required for RST assessment tasks. The knowledge structure used by RSAS is a goal tree-success tree (GTST) model. The upper level structure of the GTST model is generic in nature. This allows development of models for generic plant-specific GTST models. The second aspect of the RSAS is the development of inferencing techniques for the access, display, and manipulation of the knowledge to meet RST requirements in a real-time manner during the activation of the operations center. This objective is achieved by critical safety function and success path monitoring. This basic strategy is used to determine the current status and estimate future challenges to the status of the reactor, identify procedures and equipment required to maintain or regain the critical safety functions, identify critical equipment, determine information requirements, and display pertinent information concerning current reactor status

  20. ANS-8.23: Criticality accident emergency planning and response

    International Nuclear Information System (INIS)

    Pruvost, N.L.

    1991-01-01

    A study group has been formed under the auspices of ANS-8 to examine the need for a standard on nuclear criticality accident emergency planning and response. This standard would be ANS-8.23. ANSI/ANS-8.19-1984, Administrative Practices for Nuclear Criticality Safety, provides some guidance on the subject in Section 10 titled -- Planned Response to Nuclear Criticality Accidents. However, the study group has formed a consensus that Section 10 is inadequate in that technical guidance in addition to administrative guidance is needed. The group believes that a new standard which specifically addresses emergency planning and response to a perceived criticality accident is needed. Plans for underway to request the study group be designated a writing group to create a draft of such a new standard. The proposed standard will divide responsibility between management and technical staff. Generally, management will be charged with providing the necessary elements of emergency planning such as a criticality detection and alarm system, training, safe evacuation routes and assembly areas, a system for timely accountability of personnel, and an effective emergency response organization. The technical staff, on the other hand, will be made responsible for establishing specific items such as safe and clearly posted evacuation evacuation routes and dose criteria for personnel assembly areas. The key to the question of responsibilities is that management must provide the resources for the technical staff to establish the elements of an emergency response effort

  1. Emergency response preparedness analysis for radioactive materials transportation

    International Nuclear Information System (INIS)

    Parentela, E.M.; Burli, S.S.; Sathisan, S.K.; Vodrazka, W.C.

    1994-01-01

    This paper evaluates the emergency response capabilities of first responders, specifically fire services, within the state of Nevada. It addresses issues relating to the available emergency responders such as general capabilities, jurisdictions, and response times. Graphical displays of the response units and attribute tables were created using GIS ARC/INFO. These coverages, plus the existing Census Bureau TIGER Files and highway network for the state of Nevada, were utilized to determine approximate service areas of each response unit, population density served by each response unit, population density served by each response unit and the areas that can be served by a response unit for 3, 5, 10, and 30 minutes response times. Results of the analysis enabled identification of the critical areas along the proposed highway route corridor

  2. Radiation protection of workers in radiological emergency situation. Proceedings of the technical day

    International Nuclear Information System (INIS)

    Rannou, Alain; Gosset, Eric; Lahaye, Thierry; Foucher, Laurent; Couasnon, Olivier; Bouchery, Pascal; Gaillard-Lecanu, Emmanuelle; Pectorin, Xavier; Fusil, Laurence; Boudergui, Karim; Adhemar, Bruno; Devin, Patrick; Mace, Jean-Reynald; Chevallier, Michel; Leautaud, Jean-Marc; LANCE, Benoit

    2015-03-01

    Following the Fukushima-Daichi accident, several actions have been taken in France from the lessons learnt from the accident: the elaboration of a national plan for the management of a major nuclear or radiological accident, and the safety complementary evaluations to be carried out by nuclear operators. As a complement to the measures to be implemented for the protection of the overall population in emergency radiological situation, the protection of workers mobilized for the management of the crisis has also to be taken into account in the framework of these measures. The French Society of Radiation Protection (SFRP) has organized a technical day to take stock of this question. The program comprises 4 topical sessions dealing with: the main actions taken at the national scale after the Fukushima-Daichi accident, the strategies and intervention means of nuclear operators in case of radiological emergency, the radiation protection R and D for the protection of intervenors in case of radiological emergency, and the main actions implemented at the international scale and their perspectives. This document brings together the abstracts and the presentations (slides) of the different talks given at the meeting: 1 - Health status and lessons learnt from the Fukushima accident - workers (Alain RANNOU, IRSN); 2 - National response plan to a major nuclear or radiologic accident (Eric GOSSET, SGDSN); 3 - Legal framework applicable to intervenors (Thierry LAHAYE, DGT); 4 - Prescriptions linked with complementary safety and liability studies (Laurent FOUCHER, ASN); 5 - EDF: radiological risk management in emergency situation (Pascal BOUCHERY, EDF); 6 - CEA: intervention strategy, means and radiation protection (Xavier PECTORIN, Laurence FUSIL - CEA); 7 - AREVA: FINA's Intervention and workers' radiation protection (Bruno ADHEMAR, Patrick DEVIN - AREVA); 8 - Intervention in radiological emergency situation: the INTRA (Robots intervention on accidents) economic

  3. Challenges in designing interactive systems for emergency response

    DEFF Research Database (Denmark)

    Kristensen, Margit; Kyng, Morten; Nielsen, Esben Toftdahl

    2007-01-01

    and visions as ways to bridge between fieldwork and literature studies on the one hand and the emerging computer based prototypes on the other. Our case concerns design of innovative interactive systems for support in emergency response, including patient identification and monitoring as well as construction......This paper presents research on participatory design of interactive systems for emergency response. We present the work by going through the design method with a focus on the new elements that we developed for the participatory design toolkit, in particular we emphasize the use of challenges...

  4. Emergency preparedness and response plan for nuclear facilities in Indonesia

    International Nuclear Information System (INIS)

    Nur Rahmah Hidayati; Pande Made Udiyani

    2009-01-01

    All nuclear facilities in Indonesia are owned and operated by the National Nuclear Energy Agency (BATAN). The programs and activities of emergency planning and preparedness in Indonesia are based on the existing nuclear facilities, i.e. research reactors, research reactor fuel fabrication plant, radioactive waste treatment installation and radioisotopes production installation. The assessment is conducted to learn of status of emergency preparedness and response plan for nuclear facilities in Indonesia and to support the preparation of future Nuclear Power Plant. The assessment is conducted by comparing the emergency preparedness and response system in Indonesia to the system in other countries such as Japan and Republic of Korea, since the countries have many Nuclear Power Plants and other nuclear facilities. As a result, emergency preparedness response plan for existing nuclear facility in Indonesia has been implemented in many activities such as environmental monitoring program, facility monitoring equipment, and the continuous exercise of emergency preparedness and response. However, the implementation need law enforcement for imposing the responsibility of the coordinators in National Emergency Preparedness Plan. It also needs some additional technical support systems which refer to the system in Japan or Republic of Korea. The systems must be completed with some real time monitors which will support the emergency preparedness and response organization. The system should be built in NPP site before the first NPP will be operated. The system should be connected to an Off Site Emergency Center under coordination of BAPETEN as the regulatory body which has responsibility to control of nuclear energy in Indonesia. (Author)

  5. Disaster Monitoring and Emergency Response Services in China

    Science.gov (United States)

    Wu, J.; Han, X.; Zhou, Y.; Yue, P.; Wang, X.; Lu, J.; Jiang, W.; Li, J.; Tang, H.; Wang, F.; Li, X.; Fan, J.

    2018-04-01

    The Disaster Monitoring and Emergency Response Service(DIMERS) project was kicked off in 2017 in China, with the purpose to improve timely responsive service of the institutions involved in the management of natural disasters and man-made emergency situations with the timely and high-quality products derived from Space-based, Air-based and the in-situ Earth observation. The project team brought together a group of top universities and research institutions in the field of Earth observations as well as the operational institute in typical disaster services at national level. The project will bridge the scientific research and the response services of massive catastrophe in order to improve the emergency response capability of China and provide scientific and technological support for the implementation of the national emergency response strategy. In response to the call for proposal of "Earth Observation and Navigation" of 2017 National Key R&D Program of China, Professor Wu Jianjun, the deputy chairman of Faculty of Geographical Science of Beijing Normal University, submitted the Disaster Monitoring and Emergency Response Service (DIMERS) project, jointly with the experts and scholars from Institute of Remote Sensing and Digital Earth, Chinese Academy of Sciences, Wuhan University, China Institute of Earthquake Forecasting of China Earthquake Administration and China Institute of Water Resources and Hydropower Science. After two round evaluations, the proposal was funded by Ministry of Science and Technology of China.

  6. Updated tool for nuclear criticality accident emergency response

    International Nuclear Information System (INIS)

    Broadhead, B.L.; Hopper, C.M.

    1995-01-01

    Some 20 yr ago a hand-held slide rule was developed at the Oak Ridge Y-12 Plant to aid in the response to several postulated nuclear criticality accidents. These assumed accidents involved highly enriched uranium in either a bare metal or a uranyl nitrate system. The slide rule consisted of a sliding scale based on the total fission yield and four corresponding dose indicators: (1) a prompt radiation dose relationship as a function of distance; (2) a delayed fission product gamma dose rate relationship as a function of time and distance; (3) the total dose relationship with time and distance; and (4) the I-min integrated dose relationship with time and distance. The original slide rule was generated assuming very simplistic numerical procedures such as the inverse-square relationship of dose with distance and the Way-Wigner relationship to express the time dependence of the dose. The simple prescriptions were tied to actual dose measurements from similar systems to yield a meaningful, yet simple approach to emergency planning and response needs. This paper describes the application of an advanced procedure to the updating of the original slide rule for five critical systems. These five systems include (a) an unreflected sphere of 93.2 wt% enriched uranium metal, (b) an unreflected sphere of 93.2 wt% enriched uranyl nitrate solution with a H/ 235 U ratio of 500, (c) an unreflected sphere of damp 93.2 wt% enriched uranium oxide with a H/ 235 U ratio of 10, (d) an unreflected sphere of 4.95 wt% enriched uranyl fluoride solution having a H/ 235 U ratio of 410, and (e) an unreflected sphere of damp 5 wt% enriched uranium dioxide having a H/ 235 U ratio of 200

  7. Evaluating nuclear power plant crew performance during emergency response drills

    International Nuclear Information System (INIS)

    Rabin, D.

    1999-01-01

    The Atomic Energy Control Board (AECB) is responsible for the regulation of the health, safety and environmental consequences of nuclear activities in Canada. Recently, the Human Factors Specialists of the AECB have become involved in the assessment of emergency preparedness and emergency response at nuclear facilities. One key contribution to existing AECB methodology is the introduction of Behaviourally Anchored Rating Scales (BARS) to measure crew interaction skills during emergency response drills. This report presents results of an on-going pilot study to determine if the BARS provide a reliable and valid means of rating the key dimensions of communications, openness, task coordination and adaptability under simulated emergency circumstances. To date, the objectivity of the BARS is supported by good inter-rater reliability while the validity of the BARS is supported by the agreement between ratings of crew interaction and qualitative and quantitative observations of crew performance. (author)

  8. Nuclear and radiation emergency evaluation and decision-making support system for ministry of environmental protection

    International Nuclear Information System (INIS)

    Yue Huiguo; Lin Quanyi; Zhang Jiangang

    2010-01-01

    This article introduces the design features and main functions of The Nuclear and Radiation Emergency Evaluation and Decision Support System. The Ministry of Environmental Protection will construct a complete set of evaluation and decision-making system at the Nuclear Safety Center of Ministry of Environmental Protection to cope with the sudden event. The system will provide a comprehensive technical support for the consequence evaluation and decision-making of anti-terrorism event according to the responsibility of MEP in the sudden event, with the data provided by the MEP's anti-terrorism information platform. (authors)

  9. Training programs for emergency response personnel at Hanford

    International Nuclear Information System (INIS)

    Oscarson, E.E.

    1979-01-01

    The Three Mile Island reactor accident has focused attention on emergency planning and preparedness including selection and training of personnel. At Hanford, Pacific Northwest Laboratory (PNL) is in the unique position of providing emergency response personnel, planning, training and equipment not only for its own organization and facilities but also for the Hanford Site in general, as well as the Interagency Radiological Assistance Plan (IRAP) Region 8 Team. Team members are chosen for one or more of the emergency teams based upon professional education and/or experience as well as interest, aptitude and specialized knowledge. Consequently, the initial training orientation of each new team member is not directed toward general professional ability, but rather toward specialized knowledge required to carry out their assigned emergency tasks. Continual training and practice is necessary to maintain the interest and skills for effectively coping with major emergencies. The types of training which are conducted include: tests of emergency systems and/or procedures; drills involving plant employees and/or emergency team members (e.g., activation of emergency notification systems); short training sessions on special topics; and realistic emergency exercises involving the simulation of major accidents wherein the emergency team must solve specific problems on a real time basis

  10. Preparedness and response for a nuclear or radiological emergency. Safety requirements

    International Nuclear Information System (INIS)

    2004-01-01

    This Safety Requirements publication establishes the requirements for an adequate level of preparedness and response for a nuclear or radiological emergency in any State. Their implementation is intended to minimize the consequences for people, property and the environment of any nuclear or radiological emergency. The fulfilment of these requirements will also contribute to the harmonization of arrangements in the event of a transnational emergency. These requirements are intended to be applied by authorities at the national level by means of adopting legislation, establishing regulations and assigning responsibilities. The requirements apply to all those practices and sources that have the potential for causing radiation exposure or environmental radioactive contamination warranting an emergency intervention and that are: (a) Used in a State that chooses to adopt the requirements or that requests any of the sponsoring organizations to provide for the application of the requirements. (B) Used by States with the assistance of the FAO, IAEA, ILO, PAHO, OCHA or WHO in compliance with applicable national rules and regulations. (C) Used by the IAEA or which involve the use of materials, services, equipment, facilities and non-published information made available by the IAEA or at its request or under its control or supervision. Or (d) Used under any bilateral or multilateral arrangement whereby the parties request the IAEA to provide for the application of the requirements. The requirements also apply to the off-site jurisdictions that may need to make an emergency intervention in a State that adopts the requirements. The types of practices and sources covered by these requirements include: fixed and mobile nuclear reactors. Facilities for the mining and processing of radioactive ores. Facilities for fuel reprocessing and other fuel cycle facilities. Facilities for the management of radioactive waste. The transport of radioactive material. Sources of radiation used in

  11. Spatial data requirements for emergency response

    International Nuclear Information System (INIS)

    Walker, H.

    1985-01-01

    The Atmospheric Release Advisory Capability (ARAC) provides real-time assessments of the consequences resulting from an atmospheric radioactive material. In support of this operation, a system has been created which integrates numerical models, data acquisition systems, data analysis techniques, and professional staff. Components of this system rely to large degree on spatial data of various kinds. Of particular importance is the rapid generation of digital terrain models for any area in the continental U.S. The digital terrain models are used as input to atmospheric models and serve to familiarize assessors to new areas by presenting the terrain surface as a graphical image. In addition, base map data (roads, rivers, political boundaries) must also be supplied as an overlay to ARAC graphical products. A terrain data base and an associated acquisition system have been developed that provide the required terrain data within ten minutes. This terrain data base was derived from the Defense Mapping Ageny's planar data. A digital base map data base is currently being developed from the U.S. Geographical Survey's 1:2,000,000 Digital Line Graph data as well as their Geographic Names Information System. This base map data base improves ARAC's response to its mapping needs anywhere in the continental U.S

  12. Radiation response issues for infrared detectors

    Science.gov (United States)

    Kalma, Arne H.

    1990-01-01

    Researchers describe the most important radiation response issues for infrared detectors. In general, the two key degradation mechanisms in infrared detectors are the noise produced by exposure to a flux of ionizing particles (e.g.; trapped electronics and protons, debris gammas and electrons, radioactive decay of neutron-activated materials) and permanent damage produced by exposure to total dose. Total-dose-induced damage is most often the result of charge trapping in insulators or at interfaces. Exposure to short pulses of ionization (e.g.; prompt x rays or gammas, delayed gammas) will cause detector upset. However, this upset is not important to a sensor unless the recovery time is too long. A few detector technologies are vulnerable to neutron-induced displacement damage, but fortunately most are not. Researchers compare the responses of the new technologies with those of the mainstream technologies of PV HgCdTe and IBC Si:As. One important reason for this comparison is to note where some of the newer technologies have the potential to provide significantly improved radiation hardness compared with that of the mainstream technologies, and thus to provide greater motivation for the pursuit of these technologies.

  13. Emergency response planning in hospitals, United States: 2003-2004.

    Science.gov (United States)

    Niska, Richard W; Burt, Catharine W

    2007-08-20

    This study presents baseline data to determine which hospital characteristics are associated with preparedness for terrorism and natural disaster in the areas of emergency response planning and availability of equipment and specialized care units. Information from the Bioterrorism and Mass Casualty Preparedness Supplements to the 2003 and 2004 National Hospital Ambulatory Medical Care Surveys was used to provide national estimates of variations in hospital emergency response plans and resources by residency and medical school affiliation, hospital size, ownership, metropolitan statistical area status, and Joint Commission accreditation. Of 874 sampled hospitals with emergency or outpatient departments, 739 responded for an 84.6 percent response rate. Estimates are presented with 95 percent confidence intervals. About 92 percent of hospitals had revised their emergency response plans since September 11, 2001, but only about 63 percent had addressed natural disasters and biological, chemical, radiological, and explosive terrorism in those plans. Only about 9 percent of hospitals had provided for all 10 of the response plan components studied. Hospitals had a mean of about 14 personal protective suits, 21 critical care beds, 12 mechanical ventilators, 7 negative pressure isolation rooms, and 2 decontamination showers each. Hospital bed capacity was the factor most consistently associated with emergency response planning and availability of resources.

  14. Adaptive response to high LET radiations

    International Nuclear Information System (INIS)

    Dam, Annamaria; Bogdandi, E. Noemi; Polonyi, Istvan; Sardy, M. Marta; Balashazy, Imre; Palfalvy, Jozsef

    2001-01-01

    The biological consequences of exposure to ionizing radiation include gene mutation, chromosome aberrations, cellular transformation and cell death. These effects are attributed to the DNA damaging effects of the irradiation resulting in irreversible changes during DNA replication or during the processing of the DNA damage by enzymatic repair processes. These repair processes could initiate some adaptive mechanisms in the cell, which could lead to radioadaptive response (RAR). Adaptive responses have typically been detected by exposing cells to a low radiation dose (1-50 mGy) and then challenging the cells with a higher dose of radiation (2-4 Gy) and comparing the outcome to that seen with the challenge dose only. For adaptive response to be seen the challenge dose must be delivered within 24 hour of the inducing dose. Radio-adaptation is extensively studied for low LET radiation. Nevertheless, few data are available for high LET radiation at very low doses and dose rate. Our study was aimed to investigate the radioadaptive response to low-dose neutron irradiation by detection of the genotoxic damage i.e.: hprt-mutant colonies induced. Altered protein synthesis was also studied to identify stress proteins may responsible for radio-adaptation. New alpha particle irradiator system was also built up to study the biological effects of low dose alpha irradiation. The experiments were carried out on monolayers of human melanoma and CHO (Chines Hamster Ovary) cells irradiated by neutrons produced in the biological irradiation channel of the Research Reactor of Budapest Neutron Center. Cells were exposed to 0.5-50 mGy neutron doses with dose rates of 1.59-10 mGy/min. The challenge doses of 2-4 Gy gamma rays were administrated within 1-48 hours after priming treatment. The induced mutants at hprt locus were selected by adding 6-thioguanine and allow to grow for 10 days for expression of the phenotype. The protein synthesis was studied by PAGE, the molecular mass of specific

  15. Analysis of emergency response procedures and air traffic accidents ...

    African Journals Online (AJOL)

    Incessant air transport accidents have been a source of concern to stakeholders and aviation experts in Nigeria, yet the response and process has not been adequately appraised. This study attempts an evaluation of the emergency response procedures in the aviation industry with particular focus on Murtala Muhammed ...

  16. An expert system for improving nuclear emergency response

    International Nuclear Information System (INIS)

    Salame-Alfie, A.; Goldbogen, G.C.; Ryan, R.M.; Wallace, W.A.; Yeater, M.L.

    1987-01-01

    The accidents at TMI-2 and Chernobyl have produced initiatives aimed at improving nuclear plant emergency response capabilities. Among them are the development of emergency response facilities with capabilities for the acquisition, processing, and diagnosis of data which are needed to help coordinate plant operations, engineering support and management under emergency conditions. An effort in this direction prompted the development of an expert system. EP (EMERGENCY PLANNER) is a prototype expert system that is intended to help coordinate the overall management during emergency conditions. The EP system was built using the GEN-X expert system shell. GEN-X has a variety of knowledge representation mechanisms including AND/OR trees, Decision trees, and IF/THEN tables, and runs on an IBM PC-XT or AT computer or compatible. Among the main features, EP is portable, modular, user friendly, can interact with external programs and interrogate data bases. The knowledge base is made of New York State (NYS) Procedures for Emergency Classification, NYS Radiological Emergency Preparedness Plan (REPP) and knowledge from experts of the NYS Radiological Emergency Preparedness Group and the Office of Radiological Health and Chemistry of the New York Power Authority (NYPA)

  17. Emergency Preparedness and Response at Nuclear Power Plants in Pakistan

    Energy Technology Data Exchange (ETDEWEB)

    Khan, L. A.; Qamar, M. A.; Liaquat, M.R., E-mail: samasl@yahoo.com [Pakistan Atomic Energy Commission, Islamabad (Pakistan)

    2014-10-15

    Emergency preparedness and response arrangements at Nuclear Power Plants (NPPs) in Pakistan have been reevaluated in the light of Fukushima Daiichi accident. Appropriate measures have been taken to strengthen and effectively implement the on-site and off-site emergency plans. Verification of these plans is conducted through regulatory review and by witnessing periodic emergency drills and exercises conducted by the NPPs in the fulfilment of the regulatory requirements. Emergency Planning Zones (EPZs) have been revised at NPPs. A multi discipline reserve force has been formed for assistance during severe accidents. Nuclear Emergency Management System (NEMS) has been established at the national level in order to make necessary arrangements for responding to nuclear and radiological emergencies. Training programs for first responders and medical professionals have been launched. Emergencies coordination centres have been established at national and corporate levels. Public awareness program has been initiated to ensure that the surrounding population is provided with appropriate information on emergency planning and response. To share national and international operational experience, Pakistan has arranged various workshops and developed a strong link with International Atomic Energy Agency (IAEA). (author)

  18. Employer Requirements to Work during Emergency Responses: Key Ethics Considerations.

    Science.gov (United States)

    Rutkow, Lainie; Taylor, Holly A; Powell, Tia

    2017-03-01

    Local health departments and their employees are at the forefront of emergency preparedness and response. Yet, recent studies have found that some local public health workers are unwilling to report to work in a variety of disaster scenarios. This can greatly compromise a response, as many local health departments need "all hands on deck" to effectively meet increased demands. To address these concerns, local health departments have employed varied policy strategies to ensure that employees do report to work. After describing different approaches taken by local health departments throughout the United States, we briefly identify and explore key ethics considerations that arise for local health departments when employees are required to report to work for emergency responses. We then discuss how these ethics considerations may inform local health department practices intended to promote a robust emergency response.

  19. The radiation response of human dermal fibroblasts

    Science.gov (United States)

    Mitchell, Stephen Andrew

    A clinically reliable predictive assay based on normal-tissue radiosensitivity may lead to improved tumour control through individualised dose prescriptions. In-vitro fibroblast radiosensitivity has been shown, in several studies, to correlate with late radiation morbidity. The aim of this study was to investigate some of the cellular mechanisms underlying the normal-tissue response. In this study, seventeen primary fibroblast strains were established by enzymatic disaggregation of skin biopsies obtained from patients. These comprised seven who experienced acute tissue reactions to radiotherapy, four patients with a normal response and six non-cancer volunteers. An AT cell line was included as a positive control for radiosensitivity. In-vitro radiosensitivity was measured using a clonogenic assay at both high (HDR: 1.6 Gymin-1) and low dose rate (LDR: 0.01 Gymin-1). The radiation parameter HDR SF2 was the most sensitive in discriminating the seven sensitive patients from the remaining ten normal patients (range 0.11-0.19 sensitive patients compared with 0.17-0.34 control patients: puse of an internal control or LDR radiation protocol increased this discrimination. Pulsed-field gel electrophoresis (PFGE) was used to measure the level of initial and residual double-strand breaks following irradiation. No correlation was found between HDR SF2 and initial DNA damage. However, a strong correlation was found between clonogenic survival and both residual DNA damage (measured over 10-70 Gy, allowing 4 h repair, correlation coefficient: 0.90, <0.0001) and the ratio of residual/initial DNA damage, with the sensitive cell lines generally showing a higher level of residual DNA damage. Cell-cycle delays were found in all 18 cell strains in response to 2 Gy irradiation, but were not found to discriminate between sensitive and normal patients. Associated studies found no mutations of the ATM gene in the five radiosensitive patients studied. However, a coding sequence alteration

  20. Radioecology teaching: response to a nuclear or radiological emergency

    Science.gov (United States)

    Anjos, R. M.

    2006-03-01

    The study of environmental radioactivity is a topic not usually included in physics courses in Brazilian and Latin American universities. Consequently, high-school teachers rarely have the opportunity to discuss with their students the effects of radioactive contamination in forest and agricultural ecosystems following a nuclear or radiological emergency, or to conduct experiments to illustrate the methodology employed to assess the consequences of such an event. This paper presents a laboratory experiment which could be included as part of a teaching programme on ionizing radiation physics, addressing some of the aspects related to the fate and effects of anthropogenic radionuclides following a radiation emergency, and the possible physical countermeasures that could be adopted in order to reduce their impact on the environment.

  1. Radioecology teaching: response to a nuclear or radiological emergency

    International Nuclear Information System (INIS)

    Anjos, R M

    2006-01-01

    The study of environmental radioactivity is a topic not usually included in physics courses in Brazilian and Latin American universities. Consequently, high-school teachers rarely have the opportunity to discuss with their students the effects of radioactive contamination in forest and agricultural ecosystems following a nuclear or radiological emergency, or to conduct experiments to illustrate the methodology employed to assess the consequences of such an event. This paper presents a laboratory experiment which could be included as part of a teaching programme on ionizing radiation physics, addressing some of the aspects related to the fate and effects of anthropogenic radionuclides following a radiation emergency, and the possible physical countermeasures that could be adopted in order to reduce their impact on the environment

  2. A century of quantitating radiation response

    International Nuclear Information System (INIS)

    Withers, H.R.; Geffen, D.

    2003-01-01

    As their name indicates, X rays were a surprise serendipitous discovery about which nothing was known a little over a century ago. Not surprisingly, characterizing of dose responses evolved slowly, reflecting difficulties in quantifying both physical dose and biological responses. It was about 35 years after Roentgen's discovery before an international standard (the R) was accepted for measuring dose and named after him. Within 10 years of that there was pressure to change from measuring ionization of air to absorbed dose in tissue but another 20 years and a second World War before the rad was adopted. Thirty years later the rad was dropped in favor of SI units to describe the same thing and named the Gray after the main proponent of the concept of the rad. Early on, radiochemical dosimetry was introduced in the form of color changes in proprietary pastilles. Biological function was also used as a dosimeter in the early times, examples being erythema of the skin, inhibition of growth of bean roots, or the suppression of hatching of eggs from fruit flies or worms. Other biological responses were measured (eg destruction of fertility by irradiating testes), but were not used as dosimeters. Dose survival curves based on clonal regrowth by survivors were first described for bacteria about 30 years before Puck's first description of mammalian ceFll radiosensitivity, using Chinese hamster cells. Functional changes in irradiated normal tissues after a multifraction course of radiation therapy can provide a very precise estimate of cell survival per single dose fraction but conversely, it requires very precise measurement of survival from a single dose fraction to be able to predict the ultimate response to a series of doses, a level of precision never likely to be achieved for clinical application. It seems that there is not a wide spread in radiosensitivities of normal tissues within the population. Progress is slow in predicting which tumors will respond poorly to

  3. Modeling operators' emergency response time for chemical processing operations.

    Science.gov (United States)

    Murray, Susan L; Harputlu, Emrah; Mentzer, Ray A; Mannan, M Sam

    2014-01-01

    Operators have a crucial role during emergencies at a variety of facilities such as chemical processing plants. When an abnormality occurs in the production process, the operator often has limited time to either take corrective actions or evacuate before the situation becomes deadly. It is crucial that system designers and safety professionals can estimate the time required for a response before procedures and facilities are designed and operations are initiated. There are existing industrial engineering techniques to establish time standards for tasks performed at a normal working pace. However, it is reasonable to expect the time required to take action in emergency situations will be different than working at a normal production pace. It is possible that in an emergency, operators will act faster compared to a normal pace. It would be useful for system designers to be able to establish a time range for operators' response times for emergency situations. This article develops a modeling approach to estimate the time standard range for operators taking corrective actions or following evacuation procedures in emergency situations. This will aid engineers and managers in establishing time requirements for operators in emergency situations. The methodology used for this study combines a well-established industrial engineering technique for determining time requirements (predetermined time standard system) and adjustment coefficients for emergency situations developed by the authors. Numerous videos of workers performing well-established tasks at a maximum pace were studied. As an example, one of the tasks analyzed was pit crew workers changing tires as quickly as they could during a race. The operations in these videos were decomposed into basic, fundamental motions (such as walking, reaching for a tool, and bending over) by studying the videos frame by frame. A comparison analysis was then performed between the emergency pace and the normal working pace operations

  4. Medical and radiological aspects of emergency preparedness and response at SevRAO facilities.

    Science.gov (United States)

    Savkin, M N; Sneve, M K; Grachev, M I; Frolov, G P; Shinkarev, S M; Jaworska, A

    2008-12-01

    Regulatory cooperation between the Norwegian Radiation Protection Authority and the Federal Medical Biological Agency (FMBA) of the Russian Federation has the overall goal of promoting improvements in radiation protection in Northwest Russia. One of the projects in this programme has the objectives to review and improve the existing medical emergency preparedness capabilities at the sites for temporary storage of spent nuclear fuel and radioactive waste. These are operated by SevRAO at Andreeva Bay and in Gremikha village on the Kola Peninsula. The work is also intended to provide a better basis for regulation of emergency response and medical emergency preparedness at similar facilities elsewhere in Russia. The purpose of this paper is to present the main results of that project, implemented by the Burnasyan Federal Medical Biophysical Centre. The first task was an analysis of the regulatory requirements and the current state of preparedness for medical emergency response at the SevRAO facilities. Although Russian regulatory documents are mostly consistent with international recommendations, some distinctions lead to numerical differences in operational intervention criteria under otherwise similar conditions. Radiological threats relating to possible accidents, and related gaps in the regulation of SevRAO facilities, were also identified. As part of the project, a special exercise on emergency medical response on-site at Andreeva Bay was prepared and carried out, and recommendations were proposed after the exercise. Following fruitful dialogue among regulators, designers and operators, special regulatory guidance has been issued by FMBA to account for the specific and unusual features of the SevRAO facilities. Detailed sections relate to the prevention of accidents, and emergency preparedness and response, supplementing the basic Russian regulatory requirements. Overall it is concluded that (a) the provision of medical and sanitary components of emergency

  5. Elements of a national emergency response system for nuclear accidents

    International Nuclear Information System (INIS)

    Dickerson, M.H.

    1987-01-01

    The purpose of this paper is to suggest elements for a general emergency response system, employed at a national level, to detect, evaluate and assess the consequences of a radiological atmospheric release occurring within or outside of national boundaries. These elements are focused on the total aspect of emergency response ranging from providing an initial alarm to a total assessment of the environmental and health effects. Elements of the emergency response system are described in such a way that existing resources can be directly applied if appropriate; if not, newly developed or an expansion of existing resources can be employed. The major thrust of this paper is toward a philosophical discussion and general description of resources that would be required to implementation. If the major features of this proposal system are judged desirable for implementation, then the next level of detail can be added. The philosophy underlying this paper is preparedness - preparedness through planning, awareness and the application of technology. More specifically, it is establishment of reasonable guidelines including the definition of reference and protective action levels for public exposure to accidents involving nuclear material; education of the public, government officials and the news media; and the application of models and measurements coupled to computer systems to address a series of questions related to emergency planning, response and assessment. It is the role of a proven national emergency response system to provide reliable, quality-controlled information to decision makers for the management of environmental crises

  6. Real-time information support for managing plant emergency responses

    International Nuclear Information System (INIS)

    Cain, D.G.; Lord, R.J.; Wilkinson, C.D.

    1983-01-01

    The Three Mile Island Unit 2 accident highlighted the need to develop a systematic approach to managing plant emergency responses, to identify a better decision-making process, and to implement real-time information support for decision-making. The overall process management function is described and general information requirements for management of plant emergencies are identified. Basic information systems are being incorporated and future extensions and problem areas are discussed. (U.K.)

  7. SRNL EMERGENCY RESPONSE CAPABILITY FOR ATMOSPHERIC CONTAMINANT RELEASES

    International Nuclear Information System (INIS)

    Koffman, L; Chuck Hunter, C; Robert Buckley, R; Robert Addis, R

    2006-01-01

    Emergency response to an atmospheric release of chemical or radiological contamination is enhanced when plume predictions, field measurements, and real-time weather information are integrated into a geospatial framework. The Weather Information and Display (WIND) System at Savannah River National Laboratory (SRNL) utilizes such an integrated framework. The rapid availability of predictions from a suite of atmospheric transport models within this geospatial framework has proven to be of great value to decision makers during an emergency involving an atmospheric contaminant release

  8. Assessing Emergency Preparedness and Response Capacity Using Community Assessment for Public Health Emergency Response Methodology: Portsmouth, Virginia, 2013.

    Science.gov (United States)

    Kurkjian, Katie M; Winz, Michelle; Yang, Jun; Corvese, Kate; Colón, Ana; Levine, Seth J; Mullen, Jessica; Ruth, Donna; Anson-Dwamena, Rexford; Bayleyegn, Tesfaye; Chang, David S

    2016-04-01

    For the past decade, emergency preparedness campaigns have encouraged households to meet preparedness metrics, such as having a household evacuation plan and emergency supplies of food, water, and medication. To estimate current household preparedness levels and to enhance disaster response planning, the Virginia Department of Health with remote technical assistance from the Centers for Disease Control and Prevention conducted a community health assessment in 2013 in Portsmouth, Virginia. Using the Community Assessment for Public Health Emergency Response (CASPER) methodology with 2-stage cluster sampling, we randomly selected 210 households for in-person interviews. Households were questioned about emergency planning and supplies, information sources during emergencies, and chronic health conditions. Interview teams completed 180 interviews (86%). Interviews revealed that 70% of households had an emergency evacuation plan, 67% had a 3-day supply of water for each member, and 77% had a first aid kit. Most households (65%) reported that the television was the primary source of information during an emergency. Heart disease (54%) and obesity (40%) were the most frequently reported chronic conditions. The Virginia Department of Health identified important gaps in local household preparedness. Data from the assessment have been used to inform community health partners, enhance disaster response planning, set community health priorities, and influence Portsmouth's Community Health Improvement Plan.

  9. Emergency Response Capability Baseline Needs Assessment Compliance Assessment

    Energy Technology Data Exchange (ETDEWEB)

    Sharry, John A. [Lawrence Livermore National Lab. (LLNL), Livermore, CA (United States)

    2013-09-16

    This document is the second of a two-part analysis of Emergency Response Capabilities of Lawrence Livermore National Laboratory. The first part, 2013 Baseline Needs Assessment Requirements Document established the minimum performance criteria necessary to meet mandatory requirements. This second part analyses the performance of Lawrence Livermore Laboratory Emergency Management Department to the contents of the Requirements Document. The document was prepared based on an extensive review of information contained in the 2009 BNA, the 2012 BNA document, a review of Emergency Planning Hazards Assessments, a review of building construction, occupancy, fire protection features, dispatch records, LLNL alarm system records, fire department training records, and fire department policies and procedures.

  10. Emergency preparedness and response in transport of radioactive material

    International Nuclear Information System (INIS)

    Takani, Michio

    2008-01-01

    Nuclear power has been providing clean, affordable electricity in many parts of the world for nearly half a century. The national and international transport of nuclear fuel cycle materials is essential to support this activity. To sustain the nuclear power industry, fuel cycle materials have to be transported safely and efficiently. The nature of the industry is such that most countries with large-scale nuclear power industries cannot provide all the necessary fuel services themselves and consequently nuclear fuel cycle transport activities are international. The radioactive material transport industry has an outstanding safety record spanning over 45 years; however the transport of radioactive materials cannot and most not be taken for granted. Efficient emergency preparedness and response in the transport of radioactive material is an important element to ensure the maximum safety in accident conditions. The World Nuclear Transport Institute (WNTI), founded by International Nuclear Services (INS) of the United Kingdom, AREVA of France an the Federation of Electric Power Companies (FEPC) of Japan, represents the collective interest of the radioactive material transport sector, and those who rely on safe, effective and reliable transport. As part of its activities, WNTI has conducted two surveys through its members on emergency preparedness and response in the transport of radioactive material and emergency exercises. After recalling the International Atomic Energy Agency approach on emergency response, this paper will be discussing the main conclusion of surveys, in particular the national variations in emergency response and preparedness on the national and local levels of regulations, the emergency preparedness in place, the emergency response organisation (who and how), communication and exercises. (author)

  11. Emergency response preparedness: the French experience of large scale exercises

    International Nuclear Information System (INIS)

    Chanson, D.; Desnoyers, B.; Chabane, J.M.

    2004-01-01

    In compliance with the IAEA regulations for the transport of radioactive material in the event of accidents during transport of radioactive material, emergency provisions to protect persons, property and environment have to be established and developed by the relevant national organisations. In France, the prefect of the department where the accident occurs is responsible for decisions and measures required to ensure the protection of both population and property at risk owing to the accident. During an accident, the ministers concerned provide the prefect with recommendations and information, in order to help him take the requisite decisions. On their side, the nuclear industry and transport companies also have to be prepared to intervene and to support the authorities at their request, depending on their capacities and their specialities. To prepare the emergency teams properly and acquire effective emergency plans, training exercises have to be conducted regularly with every ministerial department involved, the nuclear industry and transport companies, members of the public and the media. Then, the feedback from such exercises shall be taken into account to improve the emergency procedures. This paper will introduce: - emergency response preparedness: what is required by the relevant regulations? - emergency response preparedness: how is France organised? - the French experience of conducting large training exercises simulating accidents involving the transport of radioactive material; - the main difficulties and lessons learned; - the perspectives

  12. Direct analysis of quantal radiation response data

    International Nuclear Information System (INIS)

    Thames, H.D. Jr.; Rozell, M.E.; Tucker, S.L.; Ang, K.K.; Travis, E.L.; Fisher, D.R.

    1986-01-01

    A direct analysis is proposed for quantal (all-or-nothing) responses to fractionated radiation and endpoint-dilution assays of cell survival. As opposed to two-step methods such as the reciprocal-dose technique, in which ED 50 values are first estimated for different fractionation schemes and then fit (as reciprocals) against dose per fraction, all raw data are included in a single maximum-likelihood treatment. The method accommodates variations such as short-interval fractionation regimens designed to determine tissue repair kinetics, tissue response to continuous exposures, and data obtained using endpoint-dilution assays of cell survival after fractionated doses. Monte-Carlo techniques were used to compare the direct and reciprocal-dose methods for analysis of small-scale and large-scale studies of response to fractionated doses. Both methods tended toward biased estimates in the analysis of small-scale (3 fraction numbers) studies. The α/β ratios showed less scatter when estimated by the direct method. The 95% confidence intervals determined by the direct method were more appropriate than those determined by reciprocal-dose analysis, for which 18% (small-scale study) or 8% (large-scale study) of the confidence intervals did not include the 'true' value of α/β. (author)

  13. Integrating Social Media Monitoring Into Public Health Emergency Response Operations.

    Science.gov (United States)

    Hadi, Tamer A; Fleshler, Keren

    2016-10-01

    Social media monitoring for public health emergency response and recovery is an essential response capability for any health department. The value of social media for emergency response lies not only in the capacity to rapidly communicate official and critical incident information, but as a rich source of incoming data that can be gathered to inform leadership decision-making. Social media monitoring is a function that can be formally integrated into the Incident Command System of any response agency. The approach to planning and required resources, such as staffing, logistics, and technology, is flexible and adaptable based on the needs of the agency and size and scope of the emergency. The New York City Department of Health and Mental Hygiene has successfully used its Social Media Monitoring Team during public health emergency responses and planned events including major Ebola and Legionnaires' disease responses. The concepts and implementations described can be applied by any agency, large or small, interested in building a social media monitoring capacity. (Disaster Med Public Health Preparedness. 2016;page 1 of 6).

  14. Applications of complex terrain meteorological models to emergency response management

    International Nuclear Information System (INIS)

    Yamada, Tetsuji; Leone, J.M. Jr.; Rao, K.S.; Dickerson, M.H.; Bader, D.C.; Williams, M.D.

    1989-01-01

    The Office of Health and Environmental Research (OHER), US Department of Energy (DOE), has supported the development of mesoscale transport and diffusion and meteorological models for several decades. The model development activities are closely tied to the OHER field measurement program which has generated a large amount of meteorological and tracer gas data that have been used extensively to test and improve both meteorological and dispersion models. This paper briefly discusses the history of the model development activities associated with the OHER atmospheric science program. The discussion will then focus on how results from this program have made their way into the emergency response community in the past, and what activities are presently being pursued to improve real-time emergency response capabilities. Finally, fruitful areas of research for improving real-time emergency response modeling capabilities are suggested. 35 refs., 5 figs

  15. Guidance Manual for preparing Nuclear and Radiological Emergency Preparedness and Response Plan

    Energy Technology Data Exchange (ETDEWEB)

    Muhammed, Kabiru [Korea Advanced Institute of Science and Technology, Daejeon (Korea, Republic of); Jeong, Seung-Young [Korea Institute of Nuclear Safety, Daejeon (Korea, Republic of)

    2014-10-15

    The Nuclear and Radiological Emergency Preparedness and Response Plan(NREPRP) describes the capabilities, responsibilities and authorities of government agencies and a conceptual basis for integrating the activities of these agencies to protect public health and safety. The NREPRP addresses issues related to actual or perceived radiation hazard requiring a national response in order to: i. Provide co-ordination of a response involving multi-jurisdictions or significant national responsibilities; or ii. Provide national support to state and local governments. The objective of this research is to establish Guidance Manual for preparing a timely, organized and coordinated emergency response plan for Authorities/agencies to promptly and adequately determine and take actions to protect members of the public and emergency workers. The manual will not provide sufficient details for an adequate response. This level of details is contained in standard operating procedures that are being developed based on the plan developed. Base on the data obtain from integrated planning levels and responsibility sharing, the legal document of major government agencies participating in NREPRP form the legal basis for the response plan. Also the following documents should be some international legal binding documents. Base on the international safety requirement and some countries well developed NREPRP, we have drafted a guidance manual for new comer countries for easy development of their countries NREPRP. Also we have taken in to consideration lessons learn from most accident especially Fukushima accident.

  16. Guidance Manual for preparing Nuclear and Radiological Emergency Preparedness and Response Plan

    International Nuclear Information System (INIS)

    Muhammed, Kabiru; Jeong, Seung-Young

    2014-01-01

    The Nuclear and Radiological Emergency Preparedness and Response Plan(NREPRP) describes the capabilities, responsibilities and authorities of government agencies and a conceptual basis for integrating the activities of these agencies to protect public health and safety. The NREPRP addresses issues related to actual or perceived radiation hazard requiring a national response in order to: i. Provide co-ordination of a response involving multi-jurisdictions or significant national responsibilities; or ii. Provide national support to state and local governments. The objective of this research is to establish Guidance Manual for preparing a timely, organized and coordinated emergency response plan for Authorities/agencies to promptly and adequately determine and take actions to protect members of the public and emergency workers. The manual will not provide sufficient details for an adequate response. This level of details is contained in standard operating procedures that are being developed based on the plan developed. Base on the data obtain from integrated planning levels and responsibility sharing, the legal document of major government agencies participating in NREPRP form the legal basis for the response plan. Also the following documents should be some international legal binding documents. Base on the international safety requirement and some countries well developed NREPRP, we have drafted a guidance manual for new comer countries for easy development of their countries NREPRP. Also we have taken in to consideration lessons learn from most accident especially Fukushima accident

  17. Multi-objective evolutionary emergency response optimization for major accidents

    International Nuclear Information System (INIS)

    Georgiadou, Paraskevi S.; Papazoglou, Ioannis A.; Kiranoudis, Chris T.; Markatos, Nikolaos C.

    2010-01-01

    Emergency response planning in case of a major accident (hazardous material event, nuclear accident) is very important for the protection of the public and workers' safety and health. In this context, several protective actions can be performed, such as, evacuation of an area; protection of the population in buildings; and use of personal protective equipment. The best solution is not unique when multiple criteria are taken into consideration (e.g. health consequences, social disruption, economic cost). This paper presents a methodology for multi-objective optimization of emergency response planning in case of a major accident. The emergency policy with regards to protective actions to be implemented is optimized. An evolutionary algorithm has been used as the optimization tool. Case studies demonstrating the methodology and its application in emergency response decision-making in case of accidents related to hazardous materials installations are presented. However, the methodology with appropriate modification is suitable for supporting decisions in assessing emergency response procedures in other cases (nuclear accidents, transportation of hazardous materials) or for land-use planning issues.

  18. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response (Chinese Edition)

    International Nuclear Information System (INIS)

    2013-01-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  19. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response (Chinese Edition)

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2013-09-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  20. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response (Arabic Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  1. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response (Russian Edition)

    International Nuclear Information System (INIS)

    2014-01-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  2. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response (French Edition)

    International Nuclear Information System (INIS)

    2013-01-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  3. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response

    International Nuclear Information System (INIS)

    2012-05-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  4. Communication with the Public in a Nuclear or Radiological Emergency. Emergency Preparedness and Response (Spanish Edition)

    International Nuclear Information System (INIS)

    2013-01-01

    The aim of this publication is to provide practical guidance for public information officers on the preparation for and response to a nuclear or radiological emergency, and to fulfil in part functions assigned to the IAEA in the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (Assistance Convention), as well as meeting requirements stated in IAEA Safety Standards Series No. SF-1, Fundamental Safety Principles, and in IAEA Safety Standards No. GS-R-2, Preparedness and Response for a Nuclear or Radiological Emergency. Under Article 5(a)(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and results of research relating to response to nuclear or radiological emergencies. IAEA Safety Standards Series No. GS-R-2 establishes the requirements for an adequate level of preparedness for and response to a nuclear or radiological emergency in any State, and specifies that 'All practicable steps shall be taken to provide the public with useful, timely, truthful, consistent and appropriate information throughout a nuclear or radiological emergency' in the response phase. It also requires 'responding to incorrect information and rumours; and responding to requests for information from the public and from the news and information media'. This publication provides guidance in the form of action guides and information sheets that can be easily applied by a State to build a basic capability to respond to a nuclear or radiological emergency. This guidance should be adapted to fit the user State's organizational arrangements, language, terminology, concept of operation and capabilities. This publication is published as part of the IAEA's Emergency Preparedness and Response series and complements the Manual for First Responders to a Radiological Emergency in the parts related to the tasks of public information officers. It takes

  5. Atypical radiation response of SCID cells

    Science.gov (United States)

    Chawapun, Nisa

    Murine SCID (severe combined immune deficiency) cells are well known for their defect in DNA double-strand break repair and in variable(diversity)joining [V(D)J] recombination due to a mutation in a catalytic subunit of DNA-dependent protein kinase (DNA-PKcs). As a consequence, scid cells are hypersensitive to ionizing radiation. The present study showed that asynchronous populations of scid cells were about two-fold more sensitive than Balb/c with respect to cell killing and the defect in scid cells was corrected by complementation with human chromosome 8. Analysis of the survival of synchronized populations as a function of the cell cycle revealed that while scid cells were hypersensitive in all cell cycle phases compared to wild-type cells, this hypersensitivity is even more pronounced in G1 phase. The hypersensitivity reduced as the cells progressed into S phase suggested that homologous recombination repair plays a role. The results imply that there are at least two pathways for the repair of DSB DNA, consistent with a model previously proposed by others. The scid cells were also more sensitive to UVC light (254 nm) killing as compared to wild type cells by clonogenic survival. Using a host cell reactivation (HCR) assay to study the nucleotide excision repair (NER) which is the major repair pathway for UV-photoproducts, the results showed that NER in scid cells was not as efficient as CB- 17. This suggests that DNA-PK is involved in NER as well as non-homologous end-joining (NHEJ) DSB repair which is responsible for ionizing radiation sensitivity in scid cells. Repair in scid cells was not totally absent as shown by low dose rate sparing of cell killing after exposure to 137Cs γ-rays at dose rate of 0.6 cGy/h, 1.36 cGy/h, 6 cGy/h as compared to high dose rate at 171 cGy/min, although this phenomenon could be explained partly by proliferation. However, for radiation induced transformation, no significant dose rate effect was seen. A plot of transformation

  6. DAE emergency response centre (ERC) at Kalpakkam for response to nuclear and radiological emergencies in public domain

    International Nuclear Information System (INIS)

    Meenakshisundaram, V.; Rajagopal, V.; Mathiyarasu, R.; Subramanian, V.; Rajaram, S.; Somayaji, K.M.; Kannan, V.; Rajagopalan, H.

    2008-01-01

    In India, Department of Atomic Energy (DAE) has been identified as the nodal agency/authority in respect of providing the necessary technical inputs in the event of any radiation emergency that may occur in public domain. The overall system takes into consideration statutory requirements, executive decisions as well as National and International obligations. This paper highlights the details about the strength of the Kalpakkam ERC and other essential requisites and their compliance since its formation

  7. Emergency planning and response - role nad responsibilities of the regulatory body

    International Nuclear Information System (INIS)

    Nizamska, M.

    1999-01-01

    The development of a emergency plan and organisation of adequate emergency preparedness in case of radiological accident in NPP cannot be effective without the appropriate preparatory work. In most countries, also in Republic of Bulgaria, several organisations are identified to have a potential role to play in a radiological emergency. For these reason is very important to have a national organisation, with a mandate to organise, inspect and co-ordinate the possibility of ministries and institution to react in case of radiological emergency, i.e. to quarantine the possibility for implementation of adequate counter measure for protection of the population and environment in case of radiological emergency in NPP. For the purposes of the emergency planning and response the NPP operator, ministries and the institutions developed an Emergency plan - NPP Emergency Plan and National Emergency Plan. The development of the emergency plans will be impossible without the good co-operation of the organisations which have a responsibilities in a radiological emergency. Once emergency plans are adopted, each individual organisation, also the NPP operator, must ensure that in can carry out its role effectively in accordance with the emergency plan and can develop the appropriate organisation for action and implementation of protection counter measures. For testing the emergency plans a regular exercise must be organised. Periodic reviews of the plan and modifications, based on actual events and exercise experience must be performed. The main aim of these report is to present the Bulgarian emergency planning organisation and response by explaining the national emergency panning and response legislation, implementation of IAEA recommendations and exercise experience

  8. Nuclear emergency planning and response in the Netherlands after Chernobyl

    International Nuclear Information System (INIS)

    Bergman, L.J.W.M.; Kerkhoven, I.P.

    1989-01-01

    After Chernobyl an extensive project on nuclear emergency planning and response was started in the Netherlands. The objective of this project was to develop a (governmental) structure to cope with accidents with radioactive materials, that can threaten the Dutch community and neighbouring countries. The project has resulted in a new organizational structure for nuclear emergency response, that differs on major points from the existing plans and procedures. In this paper an outline of the new structure is given. Emphasis is placed on accidents with nuclear power plants

  9. Emergency response information within the National LLW Information Management System

    International Nuclear Information System (INIS)

    Paukert, J.G.; Fuchs, R.L.

    1986-01-01

    The U.S. Department of Energy, with operational assistance from EG and G Idaho, Inc., maintains the National Low-Level Waste Information Management System, a relational data base management system with extensive information collection and reporting capabilities. The system operates on an IBM 4341 main-frame computer in Idaho Falls, Idaho and is accessible through terminals in 46 states. One of the many programs available on the system is an emergency response data network, which was developed jointly by EG and G Idaho, Inc. and the Federal Emergency Management Agency. As a prototype, the program comprises emergency response team contacts, policies, activities and decisions; federal, state and local government contacts; facility and support center locations; and news releases for nine reactor sites in the southeast. The emergency response program provides a method for consolidating currently fragmented information into a central and user-friendly system. When the program is implemented, immediate answers to response questions will be available through a remote terminal or telephone on a 24-hour basis. In view of current hazardous and low-level waste shipment rates and future movements of high-level waste, the program can offer needed and timely information for transportation as well as site incident response

  10. The IAEAs incident and emergency centre: the global focal point for nuclear and radiological emergency preparedness and response

    Energy Technology Data Exchange (ETDEWEB)

    Buglova, E.

    2016-08-01

    The continuous use of nuclear power to generate electricity and the continued threat of radioactive materials being used for nefarious reasons reminds us of the importance to stay prepared to respond to nuclear or radiological emergencies. Stringent nuclear safety and nuclear security requirements, the training of personnel, operational checks and legal frameworks cannot always prevent radiation-related emergencies. Though these events can range in severity, each has the potential to cause harm to the public, employees, patients, property and the environment. Until the Chernobyl nuclear accident in 1986, there was no international information exchange system. Immediately following that accident, the international community negotiated the so-called Emergency Conventions to ensure that the country suffering an accident with an international transboundary release of radioactive material would issue timely, authenticated information, while the States that could field technical support, would do so in a coordinated fashion. The Conventions also place specific legal obligations on the International Atomic energy Agency (IAEA) with regard to emergency preparedness and response. (Author)

  11. Oil supply security -- Emergency response of IEA countries 2007

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2007-11-29

    When Hurricane Katrina hit the Gulf of Mexico in 2005, the region's oil production and refining infrastructure was devastated and world energy markets were disrupted. The International Energy Agency decided in a matter of days to bring 60 million barrels of additional oil to the market. The emergency response system worked - the collective action helped to stabilise global markets. Since its founding in 1974, oil supply security has been a core mission of the IEA and the Agency has improved its mechanisms to respond to short-term oil supply disruptions. Nevertheless, numerous factors will continue to test the delicate balance of supply and demand. Oil demand growth will continue to accelerate in Asia; oil will be increasingly produced by a shrinking number of countries; and capacities in the supply chain will need to expand. These are just a few of the challenges facing an already tight market. What are the emergency response systems of IEA countries? How are their emergency structures organised? How prepared is the IEA to deal with an oil supply disruption? This publication addresses these questions. It presents another cycle of rigorous reviews of the emergency response mechanisms of IEA member countries. The goal of these reviews is to ensure that the IEA stays ready to respond effectively to oil supply disruptions. This publication also includes overviews of how China, India and countries of Southeast Asia are progressing with domestic policies to improve oil supply security, based on emergency stocks.

  12. Oil supply security -- Emergency response of IEA countries 2007

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2007-11-29

    When Hurricane Katrina hit the Gulf of Mexico in 2005, the region's oil production and refining infrastructure was devastated and world energy markets were disrupted. The International Energy Agency decided in a matter of days to bring 60 million barrels of additional oil to the market. The emergency response system worked - the collective action helped to stabilise global markets. Since its founding in 1974, oil supply security has been a core mission of the IEA and the Agency has improved its mechanisms to respond to short-term oil supply disruptions. Nevertheless, numerous factors will continue to test the delicate balance of supply and demand. Oil demand growth will continue to accelerate in Asia; oil will be increasingly produced by a shrinking number of countries; and capacities in the supply chain will need to expand. These are just a few of the challenges facing an already tight market. What are the emergency response systems of IEA countries? How are their emergency structures organised? How prepared is the IEA to deal with an oil supply disruption? This publication addresses these questions. It presents another cycle of rigorous reviews of the emergency response mechanisms of IEA member countries. The goal of these reviews is to ensure that the IEA stays ready to respond effectively to oil supply disruptions. This publication also includes overviews of how China, India and countries of Southeast Asia are progressing with domestic policies to improve oil supply security, based on emergency stocks.

  13. Analyzing and sense making of human factors in the Malaysian radiation and nuclear emergency planning framework

    Science.gov (United States)

    Hamid, A. H. A.; Rozan, M. Z. A.; Deris, S.; Ibrahim, R.; Abdullah, W. S. W.; Rahman, A. A.; Yunus, M. N. M.

    2016-01-01

    The evolution of current Radiation and Nuclear Emergency Planning Framework (RANEPF) simulator emphasizes on the human factors to be analyzed and interpreted according to the stakeholder's tacit and explicit knowledge. These human factor criteria are analyzed and interpreted according to the "sense making theory" and Disaster Emergency Response Management Information System (DERMIS) design premises. These criteria are corroborated by the statistical criteria. In recent findings, there were no differences of distributions among the stakeholders according to gender and organizational expertise. These criteria are incrementally accepted and agreed the research elements indicated in the respective emergency planning frameworks and simulator (i.e. 78.18 to 84.32, p-value <0.05). This paper suggested these human factors criteria in the associated analyses and theoretical perspectives to be further acomodated in the future simulator development. This development is in conjunction with the proposed hypothesis building of the process factors and responses diagram. We proposed that future work which implies the additional functionality of the simulator, as strategized, condensed and concise, comprehensive public disaster preparedness and intervention guidelines, to be a useful and efficient computer simulation.

  14. Analyzing and sense making of human factors in the Malaysian radiation and nuclear emergency planning framework

    International Nuclear Information System (INIS)

    Hamid, A. H. A.; Rozan, M. Z. A.; Ibrahim, R.; Deris, S.; Abdullah, W. S. W.; Yunus, M. N. M.; Rahman, A. A.

    2016-01-01

    The evolution of current Radiation and Nuclear Emergency Planning Framework (RANEPF) simulator emphasizes on the human factors to be analyzed and interpreted according to the stakeholder’s tacit and explicit knowledge. These human factor criteria are analyzed and interpreted according to the “sense making theory” and Disaster Emergency Response Management Information System (DERMIS) design premises. These criteria are corroborated by the statistical criteria. In recent findings, there were no differences of distributions among the stakeholders according to gender and organizational expertise. These criteria are incrementally accepted and agreed the research elements indicated in the respective emergency planning frameworks and simulator (i.e. 78.18 to 84.32, p-value <0.05). This paper suggested these human factors criteria in the associated analyses and theoretical perspectives to be further acomodated in the future simulator development. This development is in conjunction with the proposed hypothesis building of the process factors and responses diagram. We proposed that future work which implies the additional functionality of the simulator, as strategized, condensed and concise, comprehensive public disaster preparedness and intervention guidelines, to be a useful and efficient computer simulation

  15. Analyzing and sense making of human factors in the Malaysian radiation and nuclear emergency planning framework

    Energy Technology Data Exchange (ETDEWEB)

    Hamid, A. H. A., E-mail: amyhamijah@gmail.com, E-mail: amyhamijah@nm.gov.my [Faculty of Computing, Universiti Teknologi Malaysia (UTM), Skudai, 81310 Johor Bahru, Johor (Malaysia); Universiti Malaysia Kelantan (UMK), Pengkalan Chepa, 16100 Kota Bharu, Kelantan (Malaysia); Rozan, M. Z. A., E-mail: drmohdzaidi@gmail.com; Ibrahim, R. [Faculty of Computing, Universiti Teknologi Malaysia (UTM), Skudai, 81310 Johor Bahru, Johor (Malaysia); Deris, S. [Universiti Malaysia Kelantan (UMK), Pengkalan Chepa, 16100 Kota Bharu, Kelantan (Malaysia); Abdullah, W. S. W.; Yunus, M. N. M. [Malaysian Nuclear Agency (NM), Bangi, 43000 Kajang, Selangor (Malaysia); Rahman, A. A. [Faculty of Medicine and Health Sciences, Universiti Putra Malaysia (UPM), 43400 Serdang, Selangor (Malaysia)

    2016-01-22

    The evolution of current Radiation and Nuclear Emergency Planning Framework (RANEPF) simulator emphasizes on the human factors to be analyzed and interpreted according to the stakeholder’s tacit and explicit knowledge. These human factor criteria are analyzed and interpreted according to the “sense making theory” and Disaster Emergency Response Management Information System (DERMIS) design premises. These criteria are corroborated by the statistical criteria. In recent findings, there were no differences of distributions among the stakeholders according to gender and organizational expertise. These criteria are incrementally accepted and agreed the research elements indicated in the respective emergency planning frameworks and simulator (i.e. 78.18 to 84.32, p-value <0.05). This paper suggested these human factors criteria in the associated analyses and theoretical perspectives to be further acomodated in the future simulator development. This development is in conjunction with the proposed hypothesis building of the process factors and responses diagram. We proposed that future work which implies the additional functionality of the simulator, as strategized, condensed and concise, comprehensive public disaster preparedness and intervention guidelines, to be a useful and efficient computer simulation.

  16. Emergency Response Capability Baseline Needs Assessment - Compliance Assessment

    Energy Technology Data Exchange (ETDEWEB)

    Sharry, John A. [Lawrence Livermore National Lab. (LLNL), Livermore, CA (United States)

    2016-09-01

    This document was prepared by John A. Sharry, LLNL Fire Marshal and Division Leader for Fire Protection and was reviewed by LLNL Emergency Management Department Head, James Colson. This document is the second of a two-part analysis on Emergency Response Capabilities of Lawrence Livermore National Laboratory. The first part, 2016 Baseline Needs Assessment Requirements Document established the minimum performance criteria necessary to meet mandatory requirements. This second part analyses the performance of Lawrence Livermore Laboratory Emergency Management Department to the contents of the Requirements Document. The document was prepared based on an extensive review of information contained in the 2016 BNA, a review of Emergency Planning Hazards Assessments, a review of building construction, occupancy, fire protection features, dispatch records, LLNL alarm system records, fire department training records, and fire department policies and procedures. The 2013 BNA was approved by NNSA’s Livermore Field Office on January 22, 2014.

  17. Emergency response capability for pollutant releases to streams and rivers

    International Nuclear Information System (INIS)

    Buckner, M.R.; Hayes, D.W.; Watts, J.R.

    1975-01-01

    Stream-river models have been developed which provide an accurate prediction of normal and accidental pollutant releases to streams and rivers. Stream parameters are being developed for the Savannah River Plant streams and the Savannah River to allow quick response in case of an accidental release of radioactive material. These data are stored on permanent disk storage for quick access via the JOSHUA operating system. This system provides an efficient and flexible emergency response capability for pollutant releases to streams and rivers

  18. Application of geographic information system for radiologic emergency response

    International Nuclear Information System (INIS)

    Best, R.G.; Doyle, J.F.; Mueller, P.G.

    1998-01-01

    Comprehensive and timely radiological, cultural, and environmental data are required in order to make informed decisions during a radiological emergency. Within the Federal Radiological Monitoring and Assessment Center (FRMAC), there is a continuing effort to improve the data management and communication process. The most recent addition to this essential function has been the development of the Field Analysis System for Emergency Response (FASER). It is an integrated system with compatible digital image processing and Geographic Information System (GIS) capabilities. FASER is configured with commercially available off-the-shelf hardware and software components. To demonstrate the potential of the FASER system for radiological emergency response, the system has been utilized in interagency FRMAC exercises to analyze the available spatial data to help determine the impact of a hypothetical radiological release and to develop mitigation plans. (R.P.)

  19. Emergency preparedness: a responsibility of the medical profession

    International Nuclear Information System (INIS)

    Sammons, J.H.

    1986-01-01

    There are a series of things that we might do with regard to emergency planning. Some are clearly obvious, some perhaps are less so. Obviously, we should try to prevent a disaster from occurring. But we know that disasters are going to happen. Second, we should attempt to minimize the number of casualties in the event of an emergency. A part of planning is traffic control, with the traffic control designed to prevent that particular difficulty. Clearly we need to prevent additional casualties once the natural or man-made disaster has occurred. Without question, we have to rescue the injured, we have to be able to provide first aid, and we have to make value judgments instantly on who needs aid and who does not. Obviously, the medical community has to supply the leaders in terms of the care of the injured. Equally obvious is that other people in the community, such as the governor, the mayor, the city manager, the chief of police, and the fire chief, have to be involved. When you become involved in emergency planning, remember that there are other people in the health care family. It is not just physicians who are important; the Red Cross, nurses, public health agencies, those in state radiation control programs, and many others also are important. And let us not forget the people with specialized training in nuclear medicine, as well as radiologists and radiation oncologists

  20. Gamification for data gathering in emergency response exercises

    NARCIS (Netherlands)

    Meesters, Kenny; Ruhe, Aaron; Soetanto, Marvin; Munkvold, R.; Kolås, L.

    2015-01-01

    Our paper describes how gamification can be implemented in an emergency response exercise. In particular, we focus on the potential of gamification to support self-evaluation processes through the automated gathering of data about the participants' performance. Disaster-exercises are typically

  1. Correlates of emergency response interval and mortality from ...

    African Journals Online (AJOL)

    A retrospective study to determine the influence of blood transfusion emergency response interval on Mortality from childhood severe anemia was carried out. An admission record of all children with severe anemia over a 5-year period was reviewed. Those who either died before transfusion or got discharged against ...

  2. RMP Guidance for Warehouses - Chapter 8: Emergency Response Program

    Science.gov (United States)

    Implementing an emergency response program along with your risk management plan may be required if you have at least one Program 2 or 3 process in place, and if your employees will respond to some releases involving regulated toxic or flammable substances.

  3. MMS: An electronic message management system for emergency response

    DEFF Research Database (Denmark)

    Andersen, H.B.; Garde, H.; Andersen, V.

    1998-01-01

    among messages can be viewed in a graphic tree-like display. By employing the extensive filtration facilities offered by the MMS. users are able to monitor the current status of messages. And, in general, filtration provides users with means of surveying a possibly large number of responses to messages...... contingency plan and procedures to be applied during predefined stages of an emergency....

  4. 47 CFR 0.192 - Emergency Response Interoperability Center.

    Science.gov (United States)

    2010-10-01

    ... 47 Telecommunication 1 2010-10-01 2010-10-01 false Emergency Response Interoperability Center. 0.192 Section 0.192 Telecommunication FEDERAL COMMUNICATIONS COMMISSION GENERAL COMMISSION ORGANIZATION..., industry representatives, and service providers. [75 FR 28207, May 20, 2010] ...

  5. The national radiological emergency preparedness and response plan in the Philippines

    International Nuclear Information System (INIS)

    Valdezco, Eulinia Mendoza

    2007-01-01

    The use of radiation sources of various types and activities is now widespread in the fields of industry, medicine, research and education in the Philippines. These radiation sources have been under the regulatory control of the Philippine Nuclear Research Institute (PNRI) to ensure that these materials are used in a safe manner and stored in a safe and secure location, and that those which have exceeded their useful life are appropriately disposed of. And while the safety record of the nuclear industry remains admirable compared to other industries, the occurrence of an accident affecting members of the public is always a possibility but with very low probability. In 2001, the National Disaster Coordinating Council (NDCC) approved the revised National Radiological Emergency Preparedness and Response Plan (RADPLAN). This plan outlines the activities and organizations necessary to mitigate the effects of nuclear emergencies or radiation related accidents. An important component of this plan is the education of the public as well as the emergency responders such as the police authorities fire emergency personnel, medical responders, community leaders and the general public. The threat of nuclear terrorism as an aftermath of the September 11 incident in the United States has also been considered in the latest revision of this document. (author)

  6. Training programmes and experiences of medical emergency preparedness for radiation accident in Japan

    Energy Technology Data Exchange (ETDEWEB)

    Suzuki-Yasumoto, M

    1982-01-01

    Our policy of training programmes for medical radiation emergency preparedness is described. We found it is necessary to have two approaches to the training of relevant personnel. The first approach was to conduct adequate basic training of nurses and health physics personnel in large nuclear installations for medical radiation emergency preparedness. We found it was necessary to have courses for basic knowledge of nuclear radiation and industrial activities, radiation monitoring procedures, radiation injuries, human counters and wound monitors, first aid practices, and radiation medical emergency procedures including practices. The second approach was to make a simple and introductory training program on the subject using lectures and visual presentations in the vicinity of big nuclear installations for personnel relating to the nuclear industrial activities and for concerned local personnel, including medical doctors and nurses. These two training courses and approaches were planned and have been conducted. 2 refs. (DT)

  7. Responses of populations of small mammals to ionizing radiation

    International Nuclear Information System (INIS)

    Kitchings, J.T.

    1978-01-01

    Studies on the responses of small mammals to ionizing radiation have, over the past 30 years, documented numerous effects on direct mortality, reproduction, the hemopoietic systems, and radionuclide metabolism. Three general findings have resulted from past efforts: (1) ionizing radiation is a factor in environmental stress, (2) the response of wild small mammals to ionizing radiation is a mosaic of varying radiosensitivities interacting with environmental variables, and (3) one of the most sensitive organismal processes to radiation is reproduction. While an excellent understanding of the biological effects resulting from high or intermediate-level radiation exposures has been developed, this is not the case for effects of low-level doses

  8. Using the Grade Approach to Support the Development of Recommendations for Public Health Interventions in Radiation Emergencies

    International Nuclear Information System (INIS)

    Carr, Z.; Clarke, M.; Akl, E.A.; Schneider, R.; Murith, C.; Li, C.; Parrish-Sprowl, J.; Stenke, L.; Cui-Ping, L.; Bertrand, S.; Miller, C.

    2016-01-01

    The World Health Organization (WHO) guideline development policy requires that WHO guidelines be developed in a manner that is transparent and based on all available evidences, which must be synthesised and formally assessed for quality. To fulfil this requirement, the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach of rating quality of evidence and grading strength of recommendations was applied when developing the WHO recommendations on public health interventions in radiation emergencies. The guideline development group (GDG) formulated 10 PICO (P: population; I: intervention; C: comparator; O: outcomes) questions to guide the development of recommendations on response interventions during the early/intermediate and late emergency phases and on risk communications for mitigating psycho-social impact of radiation emergencies. For each PICO question, an extensive evidence search and systematic review was conducted. The GDG then formulated the recommendations using the evidence to recommendation (E-2-R) decision-making matrix and evaluated the strength of each recommendation. (authors)

  9. Emergency response arrangements for the transport of radioactive materials

    International Nuclear Information System (INIS)

    Morgan-Warren, E.

    2004-01-01

    Response arrangements are required for the transport of radioactive materials, under both transport and health and safety legislation, to safeguard persons, property and the environment in the event of incidents and emergencies. Responsibilities fall on both government and industry: government is responsible for ensuring public safety and providing information and reassurance. This responsibility is discharged for each type of incident by a nominated ''lead department'', supported as appropriate by other government departments and agencies; for their part, operators are obliged to have arrangements in place for dealing with the practicalities of any reasonably foreseeable incident, including recovery and onward transport of a package, and any required clean-up or restoration of the environment. This paper outlines both the government and industry arrangements in Great Britain. The principles of response and intervention are discussed, together with the lead department concept, regulatory requirements, and the plans developed by the transport industry to ensure a nation-wide response capability

  10. Moments of disaster response in the emergency department (ED).

    Science.gov (United States)

    Hammad, Karen S; Arbon, Paul; Gebbie, Kristine; Hutton, Alison

    2017-11-01

    We experience our lives as a series of memorable moments, some good and some bad. Undoubtedly, the experience of participating in disaster response, is likely to stand out as a memorable moment in a nurses' career. This presentation will describe five distinct moments of nursing in the emergency department (ED) during a disaster response. A Hermeneutic Phenomenological approach informed by van Manen underpins the research process. Thirteen nurses from different countries around the world participated in interviews about their experience of working in the ED during a disaster. Thematic analysis resulted in five moments of disaster response which are common to the collective participant experience. The 5 themes emerge as Notification (as a nurse finds out that the ED will be receiving casualties), Waiting (waiting for the patients to arrive to the ED), Patient Arrival (the arrival of the first patients to the ED), Caring for patients (caring for people affected by the disaster) and Reflection (the moment the disaster response comes to an end). This paper provides an in-depth insight into the experience of nursing in the ED during a disaster response which can help generate awareness and inform future disaster preparedness of emergency nurses. Crown Copyright © 2017. Published by Elsevier Ltd. All rights reserved.

  11. Methodology for Estimating Ingestion Dose for Emergency Response at SRS

    CERN Document Server

    Simpkins, A A

    2002-01-01

    At the Savannah River Site (SRS), emergency response models estimate dose for inhalation and ground shine pathways. A methodology has been developed to incorporate ingestion doses into the emergency response models. The methodology follows a two-phase approach. The first phase estimates site-specific derived response levels (DRLs) which can be compared with predicted ground-level concentrations to determine if intervention is needed to protect the public. This phase uses accepted methods with little deviation from recommended guidance. The second phase uses site-specific data to estimate a 'best estimate' dose to offsite individuals from ingestion of foodstuffs. While this method deviates from recommended guidance, it is technically defensibly and more realistic. As guidance is updated, these methods also will need to be updated.

  12. Some Reliability Considerations of UGV for Remote-response in Nuclear Emergency Situation

    International Nuclear Information System (INIS)

    Eom, Heungseop; Cho, Jaiwan; Jeong, Kyungmin

    2013-01-01

    In Fukushima disaster, a number of different UGVs, such as Packbots, Warriors, Quince, and Survey Runner, are used for monitoring, collecting data, inspection, and cleaning up. In utilizing UGVs in a nuclear emergency situation, one of serious problems is reliability of UGVs which is not sufficient yet for required mission completion. In this paper we surveyed failures and reliability of field UGVs and draw some important reliability considerations of UGVs for remote-response in a nuclear emergency situation. We think that the findings in this study will be helpful for developers or researchers of UGVs for nuclear emergency situations. We studied failures and reliability of UGVs used in search/rescue, military, and nuclear field by literature survey. The results showed that a state of art field UGVs can't be expected to complete an entire mission without failures, which leads to needs of reliability improvement of them. Though part of failure data from the surveyed studies were not enough detailed to get reliability matrix, some meaningful insights were found through analysis. Based on these insights, we draw some important considerations for reliability improvement of UGVs for an NPP emergency situation, and those reliability considerations are classified according to life cycle of a UGV for developers and researchers. Finally, there were not reported failures related to radiation environments in surveyed literature, but radiation tolerant control boards and sensors are easily anticipated in a NPP emergency situation. Therefore studies about the radiation-tolerant design and the use of radiation-tolerant components also should be considered for high reliability of UGVs for a NPP application

  13. Design of radiation dose tumor response assays

    International Nuclear Information System (INIS)

    Suit, H.D.; Hwang, T.; Hsieh, C.; Thames, H.

    1985-01-01

    The efficient utilization of animals in a radiation dose response assay for tumor control requires a definition of the goal, e.g., TCD50 or slope. A series of computer modelled ''experiments'' have been performed for each of a number of allocations of dose levels (DL) and number of animals/DL. The authors stipulated that the assumed TCD50 was .85 of true value; assumed slope was correct. They stipulated a binominal distribution of observed tumor control results at each dose level. A pilot assay used 6 tumors at 7 DL (from TCD1-TCD97). The second assay used 30 tumors assigned to 2,3,5 or 9 DL and to selected tumor control probabilities (TCP derived from the pilot run. Results from 100 test runs were combined with the pilot run for each of the combination of DL and TCP values. Logit regression lines were fitted through these ''data'' and the 95% CL around the TCD50 and the TCD37 values and the variances of the slopes were computed. These experiments were repeated using the method suggested by Porter (1980). Results show that a different strategy is needed depending upon the goal, viz. TCD50 or TCD37 vs slope. The differences between the two approaches are discussed

  14. Antibody responses in allogeneic radiation chimeras

    International Nuclear Information System (INIS)

    Coico, R.F.

    1982-01-01

    The construction of long-lived allogeneic radiation chimeras, free of graft-versus-host disease, has been achieved using serologic elimination of Thy 1 + cells from donor bone marrow. Humoral immune function was not restored in these animals as evidenced by lack of primary antibody responses to a T cell-dependent antigen, namely, sheep erythrocytes (SRBC) both in vivo and in vitro. No evidence for a suppressor cell-mediated mechanism was found. Using separated chimera spleen cell populations and specific helper cell soluble mediators, the functional capabilities of chimera B cells, T cells, and macrophages were assessed. These findings suggested that the failure of chimeras to produce antibody is not the result of impaired B cell, T cell, or macrophage function, but rather, that it is due to ineffective cellular interactions. Physiologic cellular interactions depend upon the sharing of major histocompatibility complex (MHC) determinants between interacting cells. However, the self-recognition repertoire of developing T cells may be influenced by the environment which these cells differentiate such that they learn to recognize host MHC determinants as self. These findings support the interpretation that the immunologic hyporeactivity of allogeneic bone marrow chimeras reflects the role of the host environment in restricting the interactive capabilities of donor-derived cells

  15. Application and evaluation of training for response to emergency situations

    Energy Technology Data Exchange (ETDEWEB)

    Kidwell, M.D.

    1979-01-01

    At Washington Gas Light Co., a magnetic situation-simulation board has become an effective tool for training field personnel in emergency procedures and decisionmaking. Class participants use magnetic disks - symbolizing physical features and components of the distribution system and service equipment - to visually describe the step-by-step procedures applied to specific emergency scenarios. A manually operated clock keeps a running account of the time estimated for each step, emphasizing the need for quick response. Situation-board programs of typical problems, complete with script and drawings, are available to all training foremen to ensure uniform training throughout the department.

  16. Hazardous Materials Management and Emergency Response training Center needs assessment

    International Nuclear Information System (INIS)

    McGinnis, K.A.; Bolton, P.A.; Robinson, R.K.

    1993-09-01

    For the Hanford Site to provide high-quality training using simulated job-site situations to prepare the 4,000 Site workers and 500 emergency responders for known and unknown hazards a Hazardous Materials Management and Emergency Response Training Center is needed. The center will focus on providing classroom lecture as well as hands-on, realistic training. The establishment of the center will create a partnership among the US Department of Energy; its contractors; labor; local, state, and tribal governments; and Xavier and Tulane Universities of Louisiana. This report presents the background, history, need, benefits, and associated costs of the proposed center

  17. Emergency monitoring strategy and radiation measurements document of the NKS project emergency management and radiation monitoring in nuclear and radiological accidents (EMARAD)

    Energy Technology Data Exchange (ETDEWEB)

    Lahtinen, J. [Radiation and Nuclear Safety Authority (STUK) (Finland)

    2006-04-15

    This report is one of the deliverables of the NKS Project Emergency management and radiation monitoring in nuclear and radiological accidents (EMARAD) (20022005). The project and the overall results are briefly described in the NKS publication 'Emergency Management and Radiation Monitoring in Nuclear and Radiological Accidents. Summary Report on the NKS Project EMARAD' (NKS-137, April 2006). In a nuclear or radiological emergency, all radiation measurements must be performed efficiently and the results interpreted correctly in order to provide the decision-makers with adequate data needed in analysing the situation and carrying out countermeasures. Managing measurements in different situations in a proper way requires the existence of pre-prepared emergency monitoring strategies. Preparing a comprehensive yet versatile strategy is not an easy task to perform because there are lots of different factors that have to be taken into account. The primary objective of this study was to discuss the general problematics concerning emergency monitoring strategies and to describe a few important features of an efficient emergency monitoring system as well as factors affecting measurement activities in practise. Some information concerning the current situation in the Nordic countries has also been included. (au)

  18. Emergency monitoring strategy and radiation measurements. Working document of the NKS project emergency management and radiation monitoring in nuclear and radiological accidents (EMARAD)

    International Nuclear Information System (INIS)

    Lahtinen, J.

    2006-04-01

    This report is one of the deliverables of the NKS Project Emergency management and radiation monitoring in nuclear and radiological accidents (EMARAD) (20022005). The project and the overall results are briefly described in the NKS publication 'Emergency Management and Radiation Monitoring in Nuclear and Radiological Accidents. Summary Report on the NKS Project EMARAD' (NKS-137, April 2006). In a nuclear or radiological emergency, all radiation measurements must be performed efficiently and the results interpreted correctly in order to provide the decision-makers with adequate data needed in analysing the situation and carrying out countermeasures. Managing measurements in different situations in a proper way requires the existence of pre-prepared emergency monitoring strategies. Preparing a comprehensive yet versatile strategy is not an easy task to perform because there are lots of different factors that have to be taken into account. The primary objective of this study was to discuss the general problematics concerning emergency monitoring strategies and to describe a few important features of an efficient emergency monitoring system as well as factors affecting measurement activities in practise. Some information concerning the current situation in the Nordic countries has also been included. (au)

  19. Ionizing radiation induced biological response and its public health implication

    International Nuclear Information System (INIS)

    Koeteles, Gy.

    1994-01-01

    Several sources of ionizing radiation exist in natural and artificial environment of humanity. An overview of their biological effects and the biological response of man is present. Emphasize is given to the differences caused by high and low doses. The interrelation of radiology, radiation hygiene and public health is pointed out. Especially, the physical and biological effects of radiation on cells and their responses are discussed in more detail. (R.P.)

  20. Modification of Acute Radiation Response in Different Demographic Age Groups

    Science.gov (United States)

    2017-10-25

    greater radiosensitivity. Other studies provided further mechanistic insight into the observed age effect of radiation responses. For example ...DISTRIBUTION A. Approved for public release; distribution is unlimited. October 2017 HDTRA1-14-0003; 0005 Prepared by: Applied ... Research Associates, Inc. 801 N. Quincy Street Suite 700 Arlington, VA 22203 Modification of Acute Radiation Response in Different Demographic Age

  1. Considerations in Emergency Preparedness and Response for a State Embarking on a Nuclear Power Programme, Training Materials

    International Nuclear Information System (INIS)

    2013-01-01

    The aim of these training materials is to provide a practical tool for emergency planning for a State embarking on a nuclear power programme, and to fulfil, in part, functions assigned to the IAEA under the Convention on Assistance in the Case of a Nuclear Accident or Radiological Emergency (the Assistance Convention). Under Article 5.a(ii) of the Assistance Convention, one function of the IAEA is to collect and disseminate to States Parties and Member States information concerning methodologies, techniques and available results of research relating to such emergencies. One of the concerns associated with nuclear power is the possibility that a State embarking on a nuclear power programme might not have sufficient capabilities and therefore would not be adequately prepared to respond to a radiation emergency caused by severe accident conditions. Protecting the public, the environment and property in the event of a failure of any level of defence in depth is the most important safety objective. A robust framework for emergency preparedness and response to a radiation emergency forms the last level of defence in depth and, as such, must be developed and implemented by any State embarking on a nuclear power programme, using best international practices. The establishment of capabilities and arrangements for emergency preparedness and response to severe accident conditions is one of the principal tasks in the development of a national infrastructure for nuclear power. State of the art emergency preparedness and response is a key element in achieving overall plant safety. This training course complements the IAEA publication 'Considerations in Emergency Preparedness and Response for a State Embarking on a Nuclear Power Programme' (EPR-Embarking 2012). These materials are designed to help States apply the guidance in EPR-Embarking 2012, in order to develop the capability to adequately prepare for and respond to a radiation emergency after the commissioning and start of

  2. Introducing PCTRAN as an evaluation tool for nuclear power plant emergency responses

    International Nuclear Information System (INIS)

    Cheng, Yi-Hsiang; Shih, Chunkuan; Chiang, Show-Chyuan; Weng, Tung-Li

    2012-01-01

    Highlights: ► PCTRAN is integrated with an atmospheric dispersion algorithm. ► The improved PCTRAN acts as an accident/incident simulator and a data exchange system. ► The software helps the responsible organizations decide the rescue and protective actions. ► The evaluation results show the nuclear power plant accident and its off-site dose consequences. ► The software can be used for nuclear power plant emergency responses. - Abstract: Protecting the public from radiation exposure is important if a nuclear power plant (NPP) accident occurs. Deciding appropriate protective actions in a timely and effective manner can be fulfilled by using an effective accident evaluation tool. In our earlier work, we have integrated PCTRAN (Personal Computer Transient Analyzer) with the off-site dose calculation model. In this study, we introduce PCTRAN as an evaluation tool for nuclear power plant emergency responses. If abnormal conditions in the plant are monitored or observed, the plant staffs can distinguish accident/incident initiation events. Thus, the responsible personnel can immediately operate PCTRAN and set up those accident/incident initiation events to simulate the nuclear power plant transient or accident in conjunction with off-site dose distributions. The evaluation results consequently help the responsible organizations decide the rescue and protective actions. In this study, we explain and demonstrate the capabilities of PCTRAN for nuclear emergency responses, through applying it to simulate the postulated nuclear power plant accident scenarios.

  3. Community emergency response to nuclear power plant accidents: A selected and partially annotated bibliography

    International Nuclear Information System (INIS)

    Youngen, G.

    1988-10-01

    The role of responding to emergencies at nuclear power plants is often considered the responsibility of the personnel onsite. This is true for most, if not all, of the incidents that may happen during the course of the plant's operating lifetime. There is however, the possibility of a major accident occurring at anytime. Major nuclear accidents at Chernobyl and Three Mile Island have taught their respective countries and communities a significant lesson in local emergency preparedness and response. Through these accidents, the rest of the world can also learn a great deal about planning, preparing and responding to the emergencies unique to nuclear power. This bibliography contains books, journal articles, conference papers and government reports on emergency response to nuclear power plant accidents. It does not contain citations for ''onsite'' response or planning, nor does it cover the areas of radiation releases from transportation accidents. The compiler has attempted to bring together a sampling of the world's collective written experience on dealing with nuclear reactor accidents on the sate, local and community levels. Since the accidents at Three Mile Island and Chernobyl, that written experience has grown enormously

  4. Community emergency response to nuclear power plant accidents: A selected and partially annotated bibliography

    Energy Technology Data Exchange (ETDEWEB)

    Youngen, G.

    1988-10-01

    The role of responding to emergencies at nuclear power plants is often considered the responsibility of the personnel onsite. This is true for most, if not all, of the incidents that may happen during the course of the plant`s operating lifetime. There is however, the possibility of a major accident occurring at anytime. Major nuclear accidents at Chernobyl and Three Mile Island have taught their respective countries and communities a significant lesson in local emergency preparedness and response. Through these accidents, the rest of the world can also learn a great deal about planning, preparing and responding to the emergencies unique to nuclear power. This bibliography contains books, journal articles, conference papers and government reports on emergency response to nuclear power plant accidents. It does not contain citations for ``onsite`` response or planning, nor does it cover the areas of radiation releases from transportation accidents. The compiler has attempted to bring together a sampling of the world`s collective written experience on dealing with nuclear reactor accidents on the sate, local and community levels. Since the accidents at Three Mile Island and Chernobyl, that written experience has grown enormously.

  5. Design of a High Power Robotic Manipulator for Emergency Response to the Nuclear Accidents

    International Nuclear Information System (INIS)

    Park, Jongwon; Bae, Yeong-Geol; Kim, Myoung Ho; Choi, Young Soo

    2016-01-01

    An accident in a nuclear facility causes a great social cost. To prevent an unexpected nuclear accident from spreading to the catastrophic disaster, emergency response action in early stage is required. However, high radiation environment has been proved as a challenging obstacle for human workers to access to the accident site and take an action in previous accident cases. Therefore, emergency response robotic technology to be used in a nuclear accident site instead of human workers are actively conducted in domestically and internationally. Robots in an accident situation are required to carry out a variety of tasks depend on the types and patterns of accidents. An emergency response usually includes removing of debris, make an access road to a certain place and handling valves. These tasks normally involve high payload handling. A small sized high power robotic manipulator can be an appropriate candidate to deal with a wide spectrum of tasks in an emergency situation. In this paper, we discuss about the design of a high power robotic manipulator, which is capable of handling high payloads for an initial response action to the nuclear facility accident. In this paper, we presented a small sized high power robotic manipulator design. Actuator types of manipulator was selected and mechanical structure was discussed. In the future, the servo valve and hydraulic pump systems will be determined. Furthermore, control algorithms and test bed experiments will be also conducted

  6. Design of a High Power Robotic Manipulator for Emergency Response to the Nuclear Accidents

    Energy Technology Data Exchange (ETDEWEB)

    Park, Jongwon; Bae, Yeong-Geol; Kim, Myoung Ho; Choi, Young Soo [Korea Atomic Energy Research Institute, Daejeon (Korea, Republic of)

    2016-10-15

    An accident in a nuclear facility causes a great social cost. To prevent an unexpected nuclear accident from spreading to the catastrophic disaster, emergency response action in early stage is required. However, high radiation environment has been proved as a challenging obstacle for human workers to access to the accident site and take an action in previous accident cases. Therefore, emergency response robotic technology to be used in a nuclear accident site instead of human workers are actively conducted in domestically and internationally. Robots in an accident situation are required to carry out a variety of tasks depend on the types and patterns of accidents. An emergency response usually includes removing of debris, make an access road to a certain place and handling valves. These tasks normally involve high payload handling. A small sized high power robotic manipulator can be an appropriate candidate to deal with a wide spectrum of tasks in an emergency situation. In this paper, we discuss about the design of a high power robotic manipulator, which is capable of handling high payloads for an initial response action to the nuclear facility accident. In this paper, we presented a small sized high power robotic manipulator design. Actuator types of manipulator was selected and mechanical structure was discussed. In the future, the servo valve and hydraulic pump systems will be determined. Furthermore, control algorithms and test bed experiments will be also conducted.

  7. Training for the medical response in radiological emergency experiences and results

    International Nuclear Information System (INIS)

    Cardenas Herrera, J.; Lopez Forteza, Y.

    2003-01-01

    The use of the nuclear techniques int he social practice confers a special imporatnce to the relative aspects to the safety of the practices and radiationsources, for what the implementation of efficient programs of radiation protection constitutes a priority. However in spite of the will before expressed, regrettably radiological situations happen accidental assocaited to multiple causes taht suggest the creation of response capacities to intervention before these fortuitous facts. The experiences accumulated in the last decades related with accidental exposures have evidenced the convenience of having properly qualified human resources for the Medical Response in Radiological Emergencies. The training in the medical aspects of the radiological emergencies acquires a singular character. In such a sense when valuing the national situation put onof manifest deficiences as for the training in medical aspects of the radiological emergencies that advised the development of training programs in such aspects for the different response groups linked to the topic. After identified the training necessities and the scope of the same ones, the contents of the training program were elaborated. The program has as general purpose the invigoration of the capacity of the medical response in front of accidental radiological situations, by means of actions that they bear to prepare groups of medical response in the handling of people accident victims and to the identification of potentials,accidental scenarios, as well as of the necessary resources to confront them. The program content approaches theoretical and paractical aspects to the medical aspect to radiological emergencies. The program include the different topics about fundamental of physical biological to radiation protection, radiation protection during exposure of radiological accidents, medical care for overexposed or contaminated persons, drill, exercises and concludes with designation of a strategy as preparation and

  8. Emergency notification and assistance technical operations manual. Emergency preparedness and response. Date effective: 1 December 2000

    International Nuclear Information System (INIS)

    2000-11-01

    nuclear accident or radiological emergency even if there is no direct transboundary impact, primarily for the purposes of minimizing the consequences of the accident or emergency e.g. for trade and tourism and providing advice to their nationals living, working and travelling in the Accident State. The provision of such information would also help to avoid unnecessary international rumours and concerns. In order to be able to provide such information in an emergency, States need to be prepared in advance. Moreover, States are encouraged to provide warning messages and other relevant information within the ENATOM framework even in the event of a nuclear accident or radiological emergency that does not trigger the Early Notification Convention but is of international concern. Recent work on clarifying emergency classification schemes for nuclear facilities and on identifying the key information to be transmitted for technical assessment purposes, the development of emergency preparedness and response standards and improvements in communications technology (e-mail and Web servers) have been reflected in the arrangements described in this new edition of ENATOM. ENATOM addresses the issue of requesting and providing assistance in the event of a nuclear accident or radiological emergency. For the provision of assistance, the IAEA is establishing a global Emergency Response Network (ERNET) of teams suitably qualified to respond rapidly, on a regional basis, to nuclear accidents or radiological emergencies. ENATOM states the Secretariat's expectations rather than prescribing arrangements. Nevertheless, all States, including States which are neither Member States of the IAEA nor party to either Convention, and the relevant International Intergovernmental Organisations are invited to adopt the arrangements described in it for providing and receiving information about nuclear accidents and radiological emergencies. In the event of a nuclear accident or radiological emergency, the

  9. Preclinical diagnosis and emergency medical care in case of radiation accidents

    International Nuclear Information System (INIS)

    Ohlenschlaeger, L.

    1990-01-01

    Reference is made to preclinical diagnosis and emergency medical care at the site of a potential radiation accident. Possibilities and limits, respectively, of the medical measures are shown. Cooperation between the experts of the technical and medical rescue services is described. Exposition to radiation for the emergency medical staff resulting from the medical care of contaminated persons, is negligible if the personal precautions are observed. (orig.) [de

  10. Enhancing nuclear emergency response through international co-operation

    International Nuclear Information System (INIS)

    Ugletveit, F.; Aaltonen, H.

    2003-01-01

    Full text: A large number of different national plans and procedures have been established and substantial resources allocated world wide with varying comprehensiveness and quality depending an the national requirements and the possible threat scenarios considered. These national plans are only to a small degree harmonized. It is clear that it is the responsibility of the authorities in the respective countries or utilities under their jurisdiction, to decide upon and implement appropriate response actions to a nuclear emergency. The basic needs for responding properly are: infrastructure in terms of plans, procedures etc.; information regarding the accident, its development and consequences; resources in terms of expertise, man power and tools for acquiring and processing information, making assessments and decisions and carry out the actions. When a large number of countries are making assessments and decisions for their own country and providing the public with information, it is important that assessments, decisions and public information become correct, complete and consistent across boarders. In order to achieve this, they should all have access to the same information as basis for their actions. Lack of information or wrong information could easily lead to wrong assessments, wrong decisions and misleading information to the public. If there is a serious nuclear emergency somewhere that could potentially affect several or many States in one way or another, 'everyone' would like to know 'everything' that happens 'everywhere'. In this case, all States should have the obligation to share with the international community the relevant information they have available themselves and that could be of interest for other States responding to the situation. During a serious nuclear or radiological emergency, the demand for different kinds of resources is huge and could, in many countries, probably exceed national capabilities. Looking at the situation in a global

  11. Physiological responses of plants to ionizing radiation

    International Nuclear Information System (INIS)

    Gaur, B.K.

    1985-01-01

    Based on the parallelism between the effects of radiation and 2, 4-dinitrophenol on oxygen uptake, oxidative phosphorylation, mitochondrial swelling and contraction and ATPase activity, it is inferred that radiation acts as an uncoupling agent, probably through stimulated hydrolysis of the non-phosphorylated high energy intermediate I-X

  12. Computational radiation chemistry: the emergence of a new field

    International Nuclear Information System (INIS)

    Bartczak, W.M.; Kroh, J.

    1991-01-01

    The role of the computer experiment as an information source, which is complementary to the ''real'' experiment in radiation chemistry, is discussed. The discussion is followed by a brief review of some of the simulation techniques, which have been recently applied to the problems of radiation chemistry: ion recombination in spurs and tracks of ionization, electron tunnelling in low-temperature glasses, electron localization in disordered media. (author)

  13. A simulator-based nuclear reactor emergency response training exercise.

    Science.gov (United States)

    Waller, Edward; Bereznai, George; Shaw, John; Chaput, Joseph; Lafortune, Jean-Francois

    Training offsite emergency response personnel basic awareness of onsite control room operations during nuclear power plant emergency conditions was the primary objective of a week-long workshop conducted on a CANDU® virtual nuclear reactor simulator available at the University of Ontario Institute of Technology, Oshawa, Canada. The workshop was designed to examine both normal and abnormal reactor operating conditions, and to observe the conditions in the control room that may have impact on the subsequent offsite emergency response. The workshop was attended by participants from a number of countries encompassing diverse job functions related to nuclear emergency response. Objectives of the workshop were to provide opportunities for participants to act in the roles of control room personnel under different reactor operating scenarios, providing a unique experience for participants to interact with the simulator in real-time, and providing increased awareness of control room operations during accident conditions. The ability to "pause" the simulator during exercises allowed the instructors to evaluate and critique the performance of participants, and to provide context with respect to potential offsite emergency actions. Feedback from the participants highlighted (i) advantages of observing and participating "hands-on" with operational exercises, (ii) their general unfamiliarity with control room operational procedures and arrangements prior to the workshop, (iii) awareness of the vast quantity of detailed control room procedures for both normal and transient conditions, and (iv) appreciation of the increased workload for the operators in the control room during a transient from normal operations. Based upon participant feedback, it was determined that the objectives of the training had been met, and that future workshops should be conducted.

  14. Radiation watchdog

    International Nuclear Information System (INIS)

    Manning, R.

    1984-01-01

    Designated by WHO as a Collaborating Centre, the Radiation Emergency Assistance Center/Training Site (REAC/TS) in Oak Ridge, Tennessee provides assistance to all countries of the Americas in radiation accidents including human contamination or overexposure. It also conducts courses in radiation emergency response for health professionals from throughout the world

  15. Roles that numerical models can play in emergency response

    International Nuclear Information System (INIS)

    Dickerson, M.H.

    1982-03-01

    Four points are presented with regard to a perspective on modeling for emergency preparedness. First, and probably foremost, modeling should be considered a tool, along with measurements and experience when used for emergency preparedness. The second point is that the potential for large errors associated with knowing the source term during an accident should not be used as a guide for determining the level of the model development and application. There are many other uses for models than estimating consequences, given the source term. These uses range from estimating the source term to bracketing the problem at hand. The third point is that several levels of model complexity should be considered when addressing emergency response. These levels can vary from the simple Gaussian calculation to the more complex three-dimensional transport and diffusion calculations where terrain and vertical and horizontal shears in the wind fields can be modeled. Lastly, proper interaction and feedback between model results and measurements enhances the capabilities of each if they were applied independently for emergency response purposes

  16. Overview of radiation effects on emerging non-volatile memory technologies

    Directory of Open Access Journals (Sweden)

    Fetahović Irfan S.

    2017-01-01

    Full Text Available In this paper we give an overview of radiation effects in emergent, non-volatile memory technologies. Investigations into radiation hardness of resistive random access memory, ferroelectric random access memory, magneto-resistive random access memory, and phase change memory are presented in cases where these memory devices were subjected to different types of radiation. The obtained results proved high radiation tolerance of studied devices making them good candidates for application in radiation-intensive environments. [Project of the Serbian Ministry of Education, Science and Technological Development, Grant no. 171007

  17. Approach of combined cancer gene therapy and radiation: response of promoters to ionizing radiation

    International Nuclear Information System (INIS)

    Anstett, A.

    2005-09-01

    Gene therapy is an emerging cancer treatment modality. We are interested in developing a radiation-inducible gene therapy system to sensitize the tumor vasculature to the effects of ionizing radiation (IR) treatment. An expression system based on irradiation-inducible promoters will drive the expression of anti-tumor genes in the tumor vasculature. Solid tumors are dependent on angio genesis, a process in which new blood vessels are formed from the pre-existing vasculature. Vascular endothelial cells are un transformed and genetically stable, thus avoiding the problem of resistance to the treatments. Vascular endothelial cells may therefore represent a suitable target for this therapeutic gene therapy strategy.The identification of IR-inducible promoters native to endothelial cells was performed by gene expression profiling using cDNA micro array technology. We describe the genes modified by clinically relevant doses of IR. The extension to high doses aimed at studying the effects of total radiation delivery to the tumor. The radio-inductiveness of the genes selected for promoter study was confirmed by RT-PCR. Analysis of the activity of promoters in response to IR was also assessed in a reporter plasmid. We found that authentic promoters cloned onto a plasmid are not suitable for cancer gene therapy due to their low induction after IR. In contrast, synthetic promoters containing repeated sequence-specific binding sites for IR-activated transcription factors such as NF-κB are potential candidates for gene therapy. The activity of five tandemly repeated TGGGGACTTTCCGC elements for NF-κB binding in a luciferase reporter was increased in a dose-dependent manner. Interestingly, the response to fractionated low doses was improved in comparison to the total single dose. Thus, we put present evidence that a synthetic promoter for NF-κB specific binding may have application in the radio-therapeutic treatment of cancer. (author)

  18. Cytogenetic Dosimetry: Applications in Preparedness for and Response to Radiation Emergencies (Spanish Edition); Dosimetría citogenética: Aplicaciones en materia de preparación y respuesta a las emergencias radiológicas

    Energy Technology Data Exchange (ETDEWEB)

    NONE

    2014-10-15

    Cytogenetic dosimetry is recognized as a valuable dose assessment method which fills a gap in dosimetric technology, particularly when there are difficulties in interpreting the data, in cases where there is reason to believe that persons not wearing dosimeters have been exposed to radiation, in cases of claims for compensation for radiation injuries that are not supported by unequivocal dosimetric evidence, or in cases of exposure over an individual’s working lifetime. The IAEA has maintained a long standing involvement in biological dosimetry commencing in 1978. This association has been through a sequence of coordinated research programmes (CRPs), the running of regional and national training courses, the sponsorship of individual training fellowships, and the provision of equipment to laboratories in Member States, establishing capabilities in biological dosimetry. From this has arisen the provision to Member States of advice regarding the best focus for research and suggestions for the most suitable techniques for future practice in biological dosimetry. One CRP resulted in the publication in 1986 of a manual, entitled Biological Dosimetry: Chromosomal Aberration Analysis for Dose Assessment (Technical Reports Series No. 260). This was superseded in 2001 by a revised second edition, Technical Reports Series No. 405. This present publication constitutes a third edition, with extensive updating to reflect the considerable advances that have been made in cytogenetic biological dosimetry during the past decade.

  19. Ontario Hydro's transportation of radioactive material and emergency response plan

    International Nuclear Information System (INIS)

    Karmali, N.

    1993-01-01

    Ontario Hydro has been transporting radioactive material for almost 30 years without any exposure to the public or release to the environment. However, there have been three accidents involving Hydro's shipments of radioactive material. In addition to the quality packaging and shipping program, Ontario Hydro has an Emergency Response Plan and capability to deal with an accident involving a shipment of radioactive material. The Corporation's ability to respond, to effectively control and contain the situation, site remediation, and to provide emergency public information in the event of a road accident minimizes the risk to the public and the environment. This emphasizes their commitment to worker safety, public safety and impact to the environment. Response capability is mandated under various legislation and regulations in Canada

  20. Exercises for radiological and nuclear emergency response. Planing - performance - evaluation

    International Nuclear Information System (INIS)

    Bayer, A.; Faleschini, J.; Goelling, K.; Stapel, R.; Strobl, C.

    2010-01-01

    The report of the study group emergency response seminar covers the following topics: (A) purpose of exercises and exercise culture: fundamentals and appliances for planning, performance and evaluation; (B) exercises in nuclear facilities; (C) exercises of national authorities and aid organizations on nuclear scenarios; exercises of national authorities and aid organizations on other radiological scenarios; (D) exercises in industrial plants, universities, medical facilities and medical services, and research institutes; (E) transnational exercises, international exercises; (F): exercises on public information.

  1. Project SIMORAC: a wireless system for radiation monitoring in emergencies

    International Nuclear Information System (INIS)

    Gomez, D.; Serrano, J. L.; Cabrera, E.; Barbaran, J.; Llopis, L.; Diaz, M.

    2013-01-01

    The SIMORAC project includes a new system for Radiological monitoring using wireless sensor networks (RSIs), without infrastructure planning in emergency situations for a rapidly deployable by air or land, with the aim of providing a tool emergency teams capable of offering a real time x-ray map within the radius of action of an accident. Communication of quality at a great distance, resistance to weather, long autonomy and possibility of aerial deployment are some of the features of SIMORAC.

  2. Environmental and emergency response capabilities of Los Alamos Scientific Laboratory's radiological air sampling program

    International Nuclear Information System (INIS)

    Gunderson, T.C.

    1980-05-01

    Environmental and emergency response radiological air sampling capabilities of the Environmental Surveillance Group at Los Alamos Scientific Laboratory are described. The air sampling program provides a supplementary check on the adequacy of containment and effluent controls, determines compliance with applicable protection guides and standards, and assesses potential environmental impacts on site environs. It also allows evaluation of potential individual and total population doses from airborne radionuclides that may be inhaled or serve as a source of external radiation. The environmental program is sufficient in scope to detect fluctuations and long-term trends in atmospheric levels of radioactivity originating onsite. The emergency response capabilities are designed to respond to both onsite unplanned releases and atmospheric nuclear tests

  3. Emergency preparedness and response for the non-reactor countries

    International Nuclear Information System (INIS)

    Buglova, E.

    2000-01-01

    Preparedness and response for nuclear and radiological accidents in the countries without nuclear power plants (NPP) have some peculiarities. Accident at the Chernobyl NPP clearly showed the necessity of effective response for non-reactor countries in the case of transboundary release. Experience obtained in Belarus is providing evidence for the necessity of changing some aspects of emergency preparedness. The results of analysis made of some protective actions taken during the early stage of the accident form the basis for recommendations provided this paper. Real experience is supported by model predictions of the consequences for the hypothetical accident at a NPP close to the Belarus. (author)

  4. Combining internet technology and mobile phones for emergency response management

    International Nuclear Information System (INIS)

    Palsson, S.E.

    2002-12-01

    The report is intended for persons involved in radiological emergency response management. An introduction is given to the technical basis of the mobile Internet and ongoing development summarised. Examples are given describing how mobile Internet technology has been used to improve monitoring media coverage of incidents and events, and a test is described where web based information was selectively processed and made available to WAP enabled mobile phones. The report concludes with recommendations stressing the need for following mobile Internet developments and taking them into account when designing web applications for radiological response management. Doing so can make web based material accessible to mobile devices at minimal additional cost. (au)

  5. Radiative Forcing from Emissivity Response in Polar Regions

    Science.gov (United States)

    Kuo, C.; Feldman, D.; Huang, X.; Flanner, M.; Chen, X.; Yang, P.; Kuo, C.

    2016-12-01

    A detailed assessment of the radiative balance and its controlling factors in polar regions is a critical prerequisite for understanding and predicting the polar amplification of climate change. Accordingly, we investigate the role of infrared surface emissivity in polar regions as a potential feedback mechanism following Feldman et al, 2014. In this work, we investigate the climatic response of the Community Earth System Model (CESM) with spectral emissivity values that are implemented in a physically consistent manner for non-vegetated surfaces. In a control model run where 1850 CO2 volume mixing ratio (vmr) is fixed, the updated spectral emissivity values are imposed for modified surface boundary conditions in the atmospheric model component. Climatic stability in the emergent globally averaged surface temperature is observed on decadal scales for an unforced (control) run. Analytic kernels representing the change in top of the atmosphere OLR given changes in emissivity are calculated on-line during the model runs, incorporating spatially and temporally varied humidity profiles impactful to transmission. Globally averaged kernels of the sensitivity of OLR to surface emissivity calculated for control and ramped CO2 runs exhibit temporal evolution with statistically significant differences in shape. Additionally, kernel and spectrally-averaged emissivity differences between monthly-averaged maps of control and ramped runs demonstrate a seasonal cycle. Similar to the treatment of cryosphere radiative forcing in Flanner et al, 2011, we define emissivity response as the product of the emissivity kernel and the change in month-to-month emissivity. At the end of 20th century, the 10-year emissivity forcing averaged at latitudes > 60°, is found to be negative (positive) in January (July), due to increasing (decreasing) sea-ice. These findings indicate that differences in surface emissivity between frozen and unfrozen surfaces decrease wintertime and increase summertime

  6. Design of nuclear emergency decision-making support system based on the results of radiation monitoring

    International Nuclear Information System (INIS)

    Zheng Qiyan; Zhang Lijun; Huang Weiqi; Chen Lin

    2010-01-01

    For nuclear emergency decision-making support system based on the results of radiation monitoring, its main assignment is receiving radiation monitoring data and analyzing them, to accomplish some works such as environment influence evaluation, dose assessment for emergency responder, decision-making analyzing and effectiveness evaluation for emergency actions, etc.. This system is made up of server, communication terminal, data-analyzing terminal, GPRS modules, printer, and so on. The whole system make of a LAN. The system's software is made up of six subsystems: data-analyzing subsystem, reporting subsystem, GIS subsystem, communication subsystem, user-managing subsystem and data-base. (authors)

  7. Protective response to technological emergency: risk perception and behavioral intention

    International Nuclear Information System (INIS)

    Lindell, M.K.; Barnes, V.E.

    1986-01-01

    This article examines why, as suggested by the Three Mile Island Nuclear Station (TMI) event, the public is more inclined to evacuate in response to a radiation release than to a natural hazard. During the TMI incident, for example, did authorities present confusing or conflicting information or did the public have an exaggerated perception of radiation risk. Behavioral intention studies are combined with risk perception analyses to ascertain (1) the extent to which intentions to evacuate can be generalized from one sample to another and from one hazard to another, (2) the degree to which behavioral intentions are related to specific dimensions of risk perception, and (3) how public perceptions of risk compare with estimates of risk produced by reactor accident consequence analyses

  8. Preparedness and response for a nuclear or radiological emergency

    International Nuclear Information System (INIS)

    Mohammed, Samah Alzebair.

    2015-12-01

    This study was conducted to find out what is ionizing radiation and its users in various medical and industrial fields and extent of the risk resulting from it as a result of inappropriate use. Examples have been mentioned so (the Chernobyl accident and San Salvador) and caused problems. Due to the non-use of nuclear and ionizing radiation in industrial areas in Sudan. There are no radiological incidents remember. Current and universally agreed-upon court plants have been developed by the organization and the competent authorities at the regional and local level and global and who is responsible because of the dangers caused to humans and the environment and all around him. (Author)

  9. Innovations in emergency response plans : making the useful application of the 2007 CDA guidelines for emergency response plans

    Energy Technology Data Exchange (ETDEWEB)

    Stevenson, A.J. [Columbia Power Corp., Castlegar, BC (Canada)

    2008-07-01

    Columbia Power Corporation (CPC) changed its perspective and approach to emergency response plans (ERP) between 2002 and 2007 from one of administrative necessity to one of important functional reference. The new 2007 Canadian Dam Association Guidelines helped facilitate that transition for both CPC and all dam owners. As part of the licensing requirements for its new facility, CPC had an ERP commissioned and developed in 2002. A potential dam safety event occurred in 2004, which necessitated the need for the ERP to be put to use. However, at the time, it was found to be lacking in functionality for field personnel. As a result, CPC recognized the significance of having a functional ERP for field staff and undertook a substantial redraft between 2005 and 2007. This paper discussed the development of the ERP with particular reference to assessing the top potential emergency scenarios for the facility; development of response plans for the identified scenarios; a flow chart to guide personnel through the required actions; response checklist; detailed inspection checklists and any required forms, photos or specific information. It was concluded that the new ERP has been well received and has improved facility awareness and emergency preparedness. 1 ref., 2 figs.

  10. Optimization of emergency response to major nuclear accidents

    International Nuclear Information System (INIS)

    Papazoglou, I.A.; Christou, M.D.

    1991-01-01

    A methodology for the optimization of the short-term emergency response in the event of a nuclear accident has been developed. The method aims at an optimum combination of protective actions in the presence of a multitude of conflicting objectives and under uncertainty. Conflicting objectives arise when the minimization of the potential adverse effects of an accident and the simultaneous minimization of the associated socioeconomic impacts is attempted. Additional conflicting objectives appear whenever an emergency plan tends to decrease a particular health effect (e.g. acute deaths) while at the same time it increases another (e.g. latent deaths). The uncertainty is due to the multitude of the possible accident scenarios and their respective probability of occurrence, the stochastic variability in the weather conditions and in the variability and/or lack of knowledge in the parameters of the risk assessment models. A multiobjective optimization approach is adopted in a dynamic programming scheme. An emergency protective plan consists of defining a protective action (e.g. evacuation, sheltering) at each spatial cell around the plant. Three criteria (evaluators) are used as the objective functions of the problem, namely, acute fatalities, latent effects and socioeconomic cost. The optimization procedure defines the efficient frontier, i.e. all emergency plans that are not dominated by another in all three criteria. No value trade-offs are necessary up to this point

  11. Emergency response guide for Point Lepreau area residents

    International Nuclear Information System (INIS)

    1982-01-01

    The design, construction and operating procedures of CANDU nuclear generating stations ensure that an accident causing a significant risk to people living near these stations is extremely unlikely. However, despite the excellent safety record of nuclear stations, it is common practice to prepare an emergency plan for such facilities. In this regard, The New Brunswick Emergency Measures Organization is responsible for developing and implementing the Off-Site Emergency Plan for the Point Lepreau Generating Station. Work for the Off-Site Emergency Plan began in 1976 and, under the leadership of N.B.E.M.O., a number of government agencies co-operated in this project. The completed plan thus represents agreement among a number of Province of New Brunswick departments, various community groups, NB Power, and representatives of the Government of Canada. Also, information gathered in the annual door-to-door survey of the Lepreau area enabled government planners to make specialized arrangements such as an extensive warden service, a siren system, and evacuation assistance for the disabled

  12. The response to a worst-case scenario - the national emergency plan for nuclear accidents

    Energy Technology Data Exchange (ETDEWEB)

    Cunningham D, John [Radiological Protection Inst. of Ireland (Ireland)

    1996-10-01

    The Chernobyl accident in 1986 highlighted many deficiencies in the preparedness of countries to deal with a major accident. It demonstrated how vulnerable countries are to transboundary contamination. Ireland had no emergency plan at the time of the accident and only minimal facilities with which to assess the consequences of the accident. Nonetheless, the then Nuclear Energy Board with the assistance of Government Departments and the Civil Defence organisation reacted quickly to assess the situation despite the complete lack of information about the accident from the then USSR. Even countries with advanced nuclear technologies faced similar difficulties. It was quickly recognised by Government that the national laboratory facilities were totally inadequate. The Nuclear Energy Board was provided with additional resources to assist it to cope in the short term with the very large demand for monitoring. In the longer term a new national radiation laboratory was provided and the Board was formally replaced by the Radiological Protection Institute of Ireland. It was given statutory responsibility to monitor radiation levels, to advise measures to be taken for the protection of the public and to provide information for the public. An emergency plan based on the Chernobyl experience was drafted in 1987, amended and published in 1992. Certain features of this plan were implemented from 1987 onwards, notably the classification of responsibilities and the installation of a national continuous radiation monitoring system. The paper outlines the responsibilities of those who could be involved in a response to a nuclear incident, the procedures used to evaluate its consequences and the provision of information for the public. The plan provides an integrated management system which has sufficient flexibility to enable a rapid response to be made to a major or minor crisis, either foreseen or unforeseen and whatever its cause.

  13. Study of developing nuclear fabrication facility's integrated emergency response manual

    International Nuclear Information System (INIS)

    Kim, Taeh Yeong; Cho, Nam Chan; Han, Seung Hoon; Moon, Jong Han; Lee, Jin Hang; Min, Guem Young; Han, Ji Ah

    2016-01-01

    Public begin to pay attention to emergency management. Thus, public's consensus on having high level of emergency management system up to advanced country's is reached. In this social atmosphere, manual is considered as key factor to prevent accident or secure business continuity. Therefore, we first define possible crisis at KEPCO Nuclear Fuel (hereinafter KNF) and also make a 'Reaction List' for each crisis situation at the view of information-design. To achieve it, we analyze several country's crisis response manual and then derive component, indicate duties and roles at the information-design point of view. From this, we suggested guideline to make 'Integrated emergency response manual(IERM)'. The manual we used before have following few problems; difficult to applicate at the site, difficult to deliver information. To complement these problems, we searched manual elements from the view of information-design. As a result, we develop administrative manual. Although, this manual could be thought as fragmentary manual because it confined specific several agency/organization and disaster type

  14. Emergency Response Imagery Related to Hurricanes Harvey, Irma, and Maria

    Science.gov (United States)

    Worthem, A. V.; Madore, B.; Imahori, G.; Woolard, J.; Sellars, J.; Halbach, A.; Helmricks, D.; Quarrick, J.

    2017-12-01

    NOAA's National Geodetic Survey (NGS) and Remote Sensing Division acquired and rapidly disseminated emergency response imagery related to the three recent hurricanes Harvey, Irma, and Maria. Aerial imagery was collected using a Trimble Digital Sensor System, a high-resolution digital camera, by means of NOAA's King Air 350ER and DeHavilland Twin Otter (DHC-6) Aircraft. The emergency response images are used to assess the before and after effects of the hurricanes' damage. The imagery aids emergency responders, such as FEMA, Coast Guard, and other state and local governments, in developing recovery strategies and efforts by prioritizing areas most affected and distributing appropriate resources. Collected imagery is also used to provide damage assessment for use in long-term recovery and rebuilding efforts. Additionally, the imagery allows for those evacuated persons to see images of their homes and neighborhoods remotely. Each of the individual images are processed through ortho-rectification and merged into a uniform mosaic image. These remotely sensed datasets are publically available, and often used by web-based map servers as well as, federal, state, and local government agencies. This poster will show the imagery collected for these three hurricanes and the processes involved in getting data quickly into the hands of those that need it most.

  15. Emergency Preparedness and Disaster Response: There's An App for That.

    Science.gov (United States)

    Bachmann, Daniel J; Jamison, Nathan K; Martin, Andrew; Delgado, Jose; Kman, Nicholas E

    2015-10-01

    Smartphone applications (or apps) are becoming increasingly popular with emergency responders and health care providers, as well as the public as a whole. There are thousands of medical apps available for Smartphones and tablet computers, with more added each day. These include apps to view textbooks, guidelines, medication databases, medical calculators, and radiology images. Hypothesis/Problem With an ever expanding catalog of apps that relate to disaster medicine, it is hard for both the lay public and responders to know where to turn for effective Smartphone apps. A systematic review of these apps was conducted. A search of the Apple iTunes store (Version 12; Apple Inc.; Cupertino, California USA) was performed using the following terms obtained from the PubMed Medical Subject Headings Database: Emergency Preparedness, Emergency Responders, Disaster, Disaster Planning, Disaster Medicine, Bioterrorism, Chemical Terrorism, Hazardous Materials (HazMat), and the Federal Emergency Management Agency (FEMA). After excluding any unrelated apps, a working list of apps was formed and categorized based on topics. Apps were grouped based on applicability to responders, the lay public, or regional preparedness, and were then ranked based on iTunes user reviews, value, relevance to audience, and user interface. This search revealed 683 applications and was narrowed to 219 based on relevance to the field. After grouping the apps as described above, and subsequently ranking them, the highest quality apps were determined from each group. The Community Emergency Response Teams and FEMA had the best apps for National Disaster Medical System responders. The Centers for Disease Control and Prevention (CDC) had high-quality apps for emergency responders in a variety of fields. The National Library of Medicine's Wireless Information System for Emergency Responders (WISER) app was an excellent app for HazMat responders. The American Red Cross had the most useful apps for natural

  16. Tissue response after radiation exposure. Intestine

    International Nuclear Information System (INIS)

    Otsuka, Kensuke; Tomita, Masanori; Yamauchi, Motohiro; Iwasaki, Toshiyasu

    2014-01-01

    Gastrointestinal syndrome followed by 'gut death' is due to intestinal disorders. This syndrome is induced by high-dose (>10 Gy) of ionizing radiation. Recovery from the gastrointestinal syndrome would depend on the number of survived clonogens and regeneration capability of crypts. These tissue alterations can be observed by high-dose radiation, however, cellular dynamics in crypts can be affected by low-dose radiation. For example, Potten et al. found that low-dose radiation induce apoptosis of intestinal stem cells, which produce all differentiated function cells. Recently, intestinal stem cells are characterized by molecular markers such as Lgr5. Since intestinal adenomas can be induced by deletion of Apc gene in Lgr5 + stem cells, it is widely recognized that Lgr5 + stem cells are the cell-of-origin of cancer. Duodenal Lgr5 + stem cells are known as radioresistant cells, however, we found that ionizing radiation significantly induces the turnover of colonic Lgr5 + stem cells. Combined with the knowledge of other radioresistant markers, stem-cell dynamics in tissue after irradiation are becoming clear. The present review introduces the history of gastrointestinal syndrome and intestinal stem cells, and discusses those future perspectives. (author)

  17. Sigmoidal response model for radiation risk

    International Nuclear Information System (INIS)

    Kondo, Sohei

    1995-01-01

    From epidemiologic studies, we find no measurable increase in the incidences of birth defects and cancer after low-level exposure to radiation. Based on modern understanding of the molecular basis of teratogenesis and cancer, I attempt to explain thresholds observed in atomic bomb survivors, radium painters, uranium workers and patients injected with Thorotrast. Teratogenic injury induced by doses below threshold will be completely eliminated as a result of altruistic death (apoptosis) of injured cells. Various lines of evidence obtained show that oncomutations produced in cancerous cells after exposure to radiation are of spontaneous origin and that ionizing radiation acts not as an oncomutation inducer but as a tumor promoter by induction of chronic wound-healing activity. The tissue damage induced by radiation has to be repaired by cell growth and this creates opportunity for clonal expansion of a spontaneously occurring preneoplastic cell. If the wound-healing error model is correct, there must be a threshold dose range of radiation giving no increase in cancer risk. (author)

  18. Biological Bases for Radiation Adaptive Responses in the Lung

    Energy Technology Data Exchange (ETDEWEB)

    Scott, Bobby R. [Lovelace Biomedical and Environmental Research Inst., Albuquerque, NM (United States); Lin, Yong [Lovelace Biomedical and Environmental Research Inst., Albuquerque, NM (United States); Wilder, Julie [Lovelace Biomedical and Environmental Research Inst., Albuquerque, NM (United States); Belinsky, Steven [Lovelace Biomedical and Environmental Research Inst., Albuquerque, NM (United States)

    2015-03-01

    Our main research objective was to determine the biological bases for low-dose, radiation-induced adaptive responses in the lung, and use the knowledge gained to produce an improved risk model for radiation-induced lung cancer that accounts for activated natural protection, genetic influences, and the role of epigenetic regulation (epiregulation). Currently, low-dose radiation risk assessment is based on the linear-no-threshold hypothesis, which now is known to be unsupported by a large volume of data.

  19. MOSFET and MOS capacitor responses to ionizing radiation

    Science.gov (United States)

    Benedetto, J. M.; Boesch, H. E., Jr.

    1984-01-01

    The ionizing radiation responses of metal oxide semiconductor (MOS) field-effect transistors (FETs) and MOS capacitors are compared. It is shown that the radiation-induced threshold voltage shift correlates closely with the shift in the MOS capacitor inversion voltage. The radiation-induced interface-state density of the MOSFETs and MOS capacitors was determined by several techniques. It is shown that the presence of 'slow' states can interfere with the interface-state measurements.

  20. A Production-Rule Analysis System for Nuclear Plant monitoring and emergency response applications

    International Nuclear Information System (INIS)

    Ragheb, M.; Tsoukalas, L.; McDonough, T.; Parker, M.

    1987-01-01

    A Production-Rule Analysis System for Nuclear Power Plant Monitoring is presented. The signals generated by the Zion-1 Plant are considered for emergency Response applications. The integrity of the Plant Radiation, the Reactor Coolant, the Fuel Clad, and the Containment Systems, is monitored. Representation of the system is in the form of a goal-tree generating a Knowledge-Base searched by an Inference Engine functioning in the forward-chaining mode. The Gaol-tree is built from Fault-Trees based on plant operational information. The system is implemented on a VAX-8500 and is programmed in OPS-5

  1. Timing criteria for supplemental BWR emergency response equipment

    International Nuclear Information System (INIS)

    Bickel, John H.

    2015-01-01

    The Great Tohuku Earthquake and subsequent Tsunami represented a double failure event which destroyed offsite power connections to Fukushima-Daiichi site and then destroyed on-site electrical systems needed to run decay heat removal systems. The accident could have been mitigated had there been supplemental portable battery chargers, supplemental pumps, and in-place piping connections to provide alternate decay heat removal. In response to this event in the USA, two national response centers, one in Memphis, Tennessee, and another in Phoenix, Arizona, will begin operation. They will be able to dispatch supplemental emergency response equipment to any nuclear plant in the U.S. within 24 hours. In order to define requirements for supplemental nuclear power plant emergency response equipment maintained onsite vs. in a regional support center it is necessary to confirm: (a) the earliest time such equipment might be needed depending on the specific scenario, (b) the nominal time to move the equipment from a storage location either on-site or within the region of a nuclear power plant, and (c) the time required to connect in the supplemental equipment to use it. This paper describes an evaluation process for a BWR-4 with a Mark I Containment starting with: (a) severe accident simulation to define best estimate times available for recovery based on the specific scenario, (b) identify the key supplemental response equipment needed at specific times to accomplish recovery of key safety functions, and (c) evaluate what types of equipment should be warehoused on-site vs. in regional response centers. (authors)

  2. Study of radiation detectors response in standard X, gamma and beta radiation standard beams

    International Nuclear Information System (INIS)

    Nonato, Fernanda Beatrice Conceicao

    2010-01-01

    The response of 76 Geiger-Mueller detectors, 4 semiconductor detectors and 34 ionization chambers were studied. Many of them were calibrated with gamma radiation beams ( 37 Cs and 60 Co), and some of them were tested in beta radiation ( 90 Sr+ 9' 0Y e 204 Tl) and X radiation (N-60, N-80, N-100, N-150) beams. For all three types of radiation, the calibration factors of the instruments were obtained, and the energy and angular dependences were studied. For beta and gamma radiation, the angular dependence was studied for incident radiation angles of 0 deg and +- 45 deg. The curves of the response of the instruments were obtained over an angle interval of 0 deg to +- 90 deg, for gamma, beta and X radiations. The calibration factors obtained for beta radiation were compared to those obtained for gamma radiation. For gamma radiation, 24 of the 66 tested Geiger-Mueller detectors presented results for the energy dependence according to international recommendation of ISO 4037-2 and 56 were in accordance with the Brazilian ABNT 10011 recommendation. The ionization chambers and semiconductors were in accordance to national and international recommendations. All instruments showed angular dependence less than 40%. For beta radiation, the instruments showed unsatisfactory results for the energy dependence and angular dependence. For X radiation, the ionization chambers presented results for energy dependence according to the national recommendation, and the angular dependence was less than 40%. (author)

  3. Arctic shipping and risks: Emergency categories and response capacities

    DEFF Research Database (Denmark)

    Marchenko, Nataly A.; Andreassen, Natalia; Borch, Odd Jarl

    2018-01-01

    The sea ice in the Arctic has shrunk significantly in the last decades. The transport pattern has as a result partly changed with more traffic in remote areas. This change may influence the risk pattern. The critical factors are harsh weather, ice conditions, remoteness and vulnerability of natur...... are rare, there are limited statistics available for Arctic maritime accidents. Hence, this study offers a qualitative analysis and an expert-based risk assessment. Implications for the emergency preparedness system of the Arctic region are discussed........ In this paper, we look into the risk of accidents in Atlantic Arctic based on previous ship accidents and the changes in maritime activity. The risk has to be assessed to ensure a proper level of emergency response. The consequences of incidents depend on the incident type, scale and location. As accidents...

  4. Response of human populations to large-scale emergencies

    Science.gov (United States)

    Bagrow, James; Wang, Dashun; Barabási, Albert-László

    2010-03-01

    Until recently, little quantitative data regarding collective human behavior during dangerous events such as bombings and riots have been available, despite its importance for emergency management, safety and urban planning. Understanding how populations react to danger is critical for prediction, detection and intervention strategies. Using a large telecommunications dataset, we study for the first time the spatiotemporal, social and demographic response properties of people during several disasters, including a bombing, a city-wide power outage, and an earthquake. Call activity rapidly increases after an event and we find that, when faced with a truly life-threatening emergency, information rapidly propagates through a population's social network. Other events, such as sports games, do not exhibit this propagation.

  5. Two-Graph Building Interior Representation for Emergency Response Applications

    Science.gov (United States)

    Boguslawski, P.; Mahdjoubi, L.; Zverovich, V.; Fadli, F.

    2016-06-01

    Nowadays, in a rapidly developing urban environment with bigger and higher public buildings, disasters causing emergency situations and casualties are unavoidable. Preparedness and quick response are crucial issues saving human lives. Available information about an emergency scene, such as a building structure, helps for decision making and organizing rescue operations. Models supporting decision-making should be available in real, or near-real, time. Thus, good quality models that allow implementation of automated methods are highly desirable. This paper presents details of the recently developed method for automated generation of variable density navigable networks in a 3D indoor environment, including a full 3D topological model, which may be used not only for standard navigation but also for finding safe routes and simulating hazard and phenomena associated with disasters such as fire spread and heat transfer.

  6. TWO-GRAPH BUILDING INTERIOR REPRESENTATION FOR EMERGENCY RESPONSE APPLICATIONS

    Directory of Open Access Journals (Sweden)

    P. Boguslawski

    2016-06-01

    Full Text Available Nowadays, in a rapidly developing urban environment with bigger and higher public buildings, disasters causing emergency situations and casualties are unavoidable. Preparedness and quick response are crucial issues saving human lives. Available information about an emergency scene, such as a building structure, helps for decision making and organizing rescue operations. Models supporting decision-making should be available in real, or near-real, time. Thus, good quality models that allow implementation of automated methods are highly desirable. This paper presents details of the recently developed method for automated generation of variable density navigable networks in a 3D indoor environment, including a full 3D topological model, which may be used not only for standard navigation but also for finding safe routes and simulating hazard and phenomena associated with disasters such as fire spread and heat transfer.

  7. Intervention criteria in a nuclear or radiation emergency

    International Nuclear Information System (INIS)

    1994-01-01

    In September 1993, the IAEA convened a Technical Committee Meeting on intervention and accidents. This tech