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==Roadmap References== | ==Roadmap References== | ||
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! Reference !! Title !! Publishing Agency | |||
|- | |||
| [1] || Reactor Safety Study: An Assessment of Accident Risks in U.S. Nuclear Power Plants (WASH 1400 / NUREG-75/014); US Nuclear Regulatory Commission: Washington DC (October 1975) || NRC | |||
|- | |||
| [2] || United States Code of Federal Regulations 10CFR52 - Licenses, Certifications, and Approvals for Nuclear Power Plants || NRC | |||
|- | |||
| [3] || Standard for Level 1 / Large Early Release Frequency Probabilistic Risk Assessment for Nuclear Power Plant Applications; ASME/ANS RA-Sa-2009; American Society of Mechanical Engineers; New York, NY (2009) || ASME | |||
|- | |||
| [4] || Insights on Risk Margins and Nuclear Power Plants: A Technical Evaluation of Margins in Relation to Quantitative Health Objectives and Subsidiary Risk Goals in the United States; 3002012967; Electric Power Research Institute; Palo Alto, CA (May 2018) || EPRI | |||
|- | |||
| [5] || The Nexus Between Safety and Operational Performance in the U.S. Nuclear Industry; Nuclear Energy Institute; Washington, DC (March 2020)|| NEI | |||
|- | |||
| [6] || Probabilistic Risk Assessment Standard for Advanced Non-Light Water Reactor Nuclear Power Plants; ASME/ANS RA-S-1.4-2001; American Society of Mechanical Engineers; New York, NY (2021) || ASME | |||
|- | |||
| [7] || Acceptability of Probabilistic Risk Assessment Results for Non-Light-Water Reactor Risk-Informed Activities; Regulatory Guide 1.247 (For Trial Use); US Nuclear Regulatory Commission; Washington, DC, (March 2022) || NRC | |||
|- | |||
| [8] || Risk-Informed Performance-Based Technology Inclusive Guidance for Non-Light Water Reactor Licensing Basis Development; NEI 18-04 (Revision 1); Nuclear Energy Institute; Washington, DC (August 2021) || NEI | |||
|- | |||
| [9] || Guidance for a Technology-Inclusive, Risk-Informed, and Performance-Based Methodology to Inform the Licensing Basis and Content of Applications for Licenses, Certifications and Approvals for Non-Light-Water Reactors; Regulatory Guide 1.233; US Nuclear Regulatory Commission; Washington, DC, (June 2020) || NRC | |||
|- | |||
| [10] || Advances in Small Modular Reactor Technology Developments A Supplement to: IAEA Advanced Reactors Information System (ARIS) 2020 Edition; International Atomic Energy Agency; Vienna, Austria (September 2022) || IAEA | |||
|- | |||
| [11] || United States Code of Federal Regulations 10CFR50 Appendix A: General Design Criteria for Nuclear Power Plants || NRC | |||
|- | |||
| [12] || Guidance for Developing Principal Design Criteria for Non-Light Water Reactors; Regulatory Guide 1.232 Revision 0; US Nuclear Regulatory Commission; Washington, DC, (2018) || NRC | |||
|- | |||
| [13] || The Canadian Nuclear Safety Commission’s Strategy Readiness to Regulate Advanced Reactor Technologies; Canadian Nuclear Safety Commission; Ottawa, Ontario (December 2019) || CNSC | |||
|- | |||
| [14] || IAEA Safety Standards Series No. SSR-2/1 Rev 1; Safety of Nuclear Power Plants: Design; IAEA Safety Standards; International Atomic Energy Agency; Vienna, Austria (2016) || IAEA | |||
|- | |||
| [15] || IAEA-TECDOC-1366; Considerations in the Development of Safety Requirements for Innovative Reactors: Application to Modular High Temperature Gas Cooled Reactors, International Atomic Energy Agency; Vienna, Austria (2003) || IAEA | |||
|- | |||
| [16] || IAEA-TECDOC-1570; Proposal for a Technology-Neutral Safety Approach for New Reactor Designs; International Atomic Energy Agency; Vienna, Austria (2003) || IAEA | |||
|- | |||
| [17] || IAEA-TECDOC-2010; Approach and Methodology for the Development of Regulatory Safety Requirements for the Design of Advanced Nuclear Power Reactors, Case Study on Small Modular Reactors; International Atomic Energy Agency; Vienna, Austria (2022) || IAEA | |||
|- | |||
| [18] || CNSC REGDOC-3.5.3, Regulatory Fundamentals, version 2.0, Canadian Nuclear Safety Commission; Ottawa, Ontario (February 2020) || CNSC | |||
|- | |||
| [19] || Memorandum of Cooperation on Advanced Reactor and Small Modular Reactor Technologies between the United States Nuclear Regulatory Commission and the Canadian Nuclear Safety Commission (August 2019) || NRC & CNSC | |||
|- | |||
| [20] || Technology Inclusive and Risk-Informed Reviews for Advanced Reactors: Comparing the US Licensing Modernization Project with the Canadian Regulatory Approach || NRC & CNSC | |||
|- | |||
| [21] || Guidance for Developing Principal Design Criteria for Advanced (Non-Light Water) Reactors, Rep. INL/EXT-14-31179, Revision 1; Idaho National Laboratory; Idaho Falls, ID (December 2014) || INL | |||
|- | |||
| [22] || IAEA-TECDOC-1909; Consideration on Performing Integrated Risk Informed Decision Making; IAEA, Vienna, Austria (2020) || IAEA | |||
|- | |||
| [23] || Generation IV International Forum (GIF), 2002. A Technology Roadmap for Generation IV Nuclear Energy Systems. GIF-002-00 || DOE | |||
|- | |||
| [24] || Brandon Chisholm, Steve Krahn, Amir Afzali, and Eric Harvey; Application of a Method to Estimate Risk in Advanced Nuclear Reactors: A Case Study on the Molten Salt Reactor Experiment; Probabilistic Safety Assessment and Management PSAM 14; September 2018; Los Angeles, CA || PSAM | |||
|- | |||
| [25] || OECD/NEA, “A Joint Report on PSA for New and Advanced Reactors"; Nuclear Safety NEA/CSNI/R(2012)17; 2012; Organisation for Economic Cooperation and Development - Nuclear Energy Agency; Paris, France || OECD/NEA | |||
|- | |||
| [26] || Brandon Chisholm, Steve Krahn, Andrew Sowder, Amir Afzali, Development of a Methodology for Early Integration of Safety Analysis into Advanced Reactor Design, American Nuclear Society PSA 2019, Charleston, SC, April 28 - May 3, 2019 || ANS | |||
|- | |||
| [27] || Brandon M. Chisholm, Steven L. Krahn, Karl N. Fleming, "A systematic approach to identify initiating events and its relationship to Probabilistic Risk Assessment: Demonstrated on the Molten Salt Reactor Experiment", Progress in Nuclear Energy 129 (2020) 103507 || Vanderbilt | |||
|- | |||
| [28] || Program on Technology Innovation: Early Integration of Safety Assessment into Advanced Reactor Design - Project Capstone Report: EPRI, Palo Alto, CA: 2019. 3002015752. || EPRI | |||
|- | |||
| [29] || Compilation of Molten Salt Reactor Experiment (MSRE) Technical, Hazard, and Risk Analyses: A Retrospective Application of Safety-in-Design Methods. EPRI, Palo Alto, CA: 2020. 3002018340. || EPRI | |||
|- | |||
| [30] || Mostafa Hamza and Mihai A. Diaconeasa, "A framework to implement human reliability analysis during early design stages of advanced reactors"; Progress in Nuclear Energy; 146 (2022); 104171 || NC State | |||
|- | |||
| [31] || Program on Technology Innovation: Probabilistic Risk Assessment Requirements for Passive Safety Systems. EPRI, Palo Alto, CA: 2007. 1015101. || EPRI | |||
|- | |||
| [32] || Program on Technology Innovation: Comprehensive Risk Assessment Requirements for Passive Safety Systems. EPRI, Palo Alto, CA; 2008. 1016747. || EPRI | |||
|- | |||
| [33] || Samuel Abiodun Olatubosun and Carol Smidts; "Reliability analysis of passive systems: An overview, status and research expectations"; Progress in Nuclear Energy; 143 (2022); 104057 || Ohio State | |||
|- | |||
| [34] || Zhi'ao Huang, Huifang Miao, Morten Lind, Xinxin Zhang, and Jing Wu; "Probabilistic safety margin characterization of an integrated small modular reactor using MFM and adaptive polynomial chaos"; Annals of Nuclear Energy; 171 (2022); 109016 || Xiamen University | |||
|- | |||
| [35] || Kyungho Jin, Hyeonmin Kim, Seunghyoung Ryu, Seunggeun Kim, and Jinkyun Park; "An approach to constructing effective training data for a classification model to evaluate the reliability of a passive safety system"; Reliability Engineering and System Safety; 222 (2022); 108446 || KAERI | |||
|- | |||
| [36] || R.B. Solanki, Harshavardhan D. Kulkarni, Suneet Singh, P.V. Varde, and A.K. Verma; "Reliability assessment of passive systems using artificial neural network based response surface methodology"; Annals of Nuclear Energy; 144 (2020); 107487 || Multi | |||
|- | |||
| [37] || Jalil Jafari, Francesco D'Auria, Hossein Kazeminejad, Hadi Davilu, "Reliability evaluation of a natural circulation system"; Nuclear Engineering and Design, Volume 224, Issue 1, September 2003, Pages 79-104 || Multi | |||
|- | |||
| [38] || Marques, M., Pignatel, J. F., Saignes, P., D'Auria, P., Burgazzi, L., Müller, C. "Methodology for the reliability evaluation of a passive system and its integration into a probabilistic safety assessment"; Nucl. Eng. Des. 235, 2612-2631. Doi:10.1016/j.nucengdes.2005.06.008 (2005) || Multi | |||
|- | |||
| [39] || Nayak, A. K., and Vijayan, P. K. (2008). "Flow instabilities in boiling two-phase natural circulation systems a review"; Sci. Technol. Nucl. Install. (2008), 15. Doi:10.1155/2008/573192 || Multi | |||
|- | |||
| [40] || Arun Kumar Nayak, Amit Chandrakar and Gopika Vinod, "A review: passive system reliability analysis - accomplishments and unresolved issues"; Front. Energy Res., 10 October 2014, Sec. Nuclear Energy, Volume 2 - 2014 || Multi | |||
|- | |||
| [41] || United Kingdom National Nuclear Regulator Position Paper, “Considerations of External Events for New Nuclear Installations”; PP-0014, Rev 0 || NNR | |||
|- | |||
| [42] || TECDOC-1487, “Advanced Nuclear Power Plant Design Options to Cope with External Events”, IAEA-TECDOC-1487 ¦ 92-0-100506-7, 2006 || IAEA | |||
|- | |||
| [43] || IAEA, Technical Approach to Probabilistic Safety Assessment for Multiple Reactor Units, Safety Report Series To Be Published, IAEA, Vienna (2019) || IAEA | |||
|- | |||
| [44] || 1st International Conference on Generation IV and Small Modular Reactors, Whole-Site Risk Considerations for Small Modular Reactors, J. Vecchiarelly, C. Lorencez and G. Archinoff, Ottawa (2018) || N/A | |||
|- | |||
| [45] || U.S. NRC, Exploring the Need for Standard Approaches to Addressing Risk Associated with Multi-Module Operation in Plants Using Small Modular Reactors, M. A. Caruso, US NRC, Washington DC || NRC | |||
|- | |||
| [46] || Small Modular Reactors Regulators' Forum: Design and Safety Analysis Working Group Report on Multi-unit/Multi-module aspects specific to SMRs, INTERIM REPORT, 15 December 2019 || SMRRF | |||
|- | |||
| [47] || Framework for Assessing Multi-Unit Risk to Support Risk-Informed Decision-Making: General Framework and Application-Specific Requirements. EPRI, Palo Alto, CA: 2001. 3002020765. || EPRI | |||
|- | |||
| [48] || Nicholas W. Touran, John Gilleland, Graham T. Malmgren, Charles Whitmer, William H. Gates III, “Computational Tools for the Integrated Design of Advanced Nuclear Reactors”; Engineering 3 (2017) 518–526 || TerraPower | |||
|- | |||
| [49] || HAZCADS: Hazards and Consequences Analysis for Digital Systems (Revision 1). EPRI, Palo Alto, CA: 2021. 3002016698. || EPRI | |||
|- | |||
| [50] || Ibrahim A. Alrammah, “Analysis of nuclear accident scenarios and emergency planning zones for a proposed Advanced Power Reactor 1400 (APR1400)”; Nuclear Engineering and Design, Volume 407, June 2023, 112275 || KACST | |||
|- | |||
| [51] || Federica C.V. Mancini, Eduardo Gallego, Marco E. Ricotti, "Revising the Emergency Management Requirements for new generation reactors"; Progress in Nuclear Energy, Volume 71, March 2014, Pages 160-171 || Multi | |||
|- | |||
| [52] || H.D. Gougar, D.A. Petti,, P.A. Demkowicz,, W.E. Windes, G. Strydom, J.C. Kinsey, J. Ortensi, M. Plummer, W. Skerjanc, R.L. Williamson, R.N. Wright, D. Li, A. Caponiti, M.A. Feltus, and T.J. O'Connor, "The US Department of Energy's high temperature reactor research and development program - Progress as of 2019"; Nuclear Engineering and Design; Volume 358, March 2020; 110397 || INL | |||
|- | |||
| [53] || Enterprise Risk Management and Risk-Informed Decision-Making. EPRI, Palo Alto, CA: 2022. 3002023855. || EPRI | |||
|- | |||
| [54] || Acceptability of Probabilistic Risk Assessment Results for Risk-Informed Activities; Regulatory Guide 1.200 Revision 3; December 2020; United States Nuclear Regulatory Commission; Washington, DC || NRC | |||
|- | |||
| [55] || F. Bianchi, et al.; "The REPAS Approach to the Evaluation of Passive Safety Systems Reliabilit"; Passive System Reliability - A Challenge to Reliability Engineering and Licensing of Advanced Nuclear Power Plants: Proceedings of an International Workshop Hosted by the Commissariat à l'Energie Atomique (CEA); NEA/CSNI/R(2002)10; Cadarache, France (26 June 2002) || OECD/NEA | |||
|- | |||
| [56] || M. E. Ricotti, et al.; "Reliability Methods for Passive Systems (RMPS) Study-Strategy and Results," Passive System Reliability - A Challenge to Reliability Engineering and Licensing of Advanced Nuclear Power Plants; Proceedings of an International Workshop Hosted by the Commissariat à l'Energie Atomique (CEA); NEA/CSNI/R(2002)10; Cadarache, France (26 June 2002) || OECD/NEA | |||
|- | |||
| [57] || Systems Engineering Process: Methods and Tools for Digital Instrumentation and Control Projects. EPRI, Palo Alto, CA: 2016. 3002008018. || EPRI | |||
|- | |||
| [58] || HFAM - Human Factors Analysis Methodology for Digital Systems: A Risk-Informed Approach to Human Factors Engineering. EPRI, Palo Alto, CA: 2021. 3002018392. || EPRI | |||
|- | |||
| [59] || Advanced Reactor Roadmap – Phase 1: North America. EPRI, Palo Alto, CA: 2023. 3002027504. || EPRI | |||
|} |
Latest revision as of 16:06, 10 July 2024
Roadmap References
Reference | Title | Publishing Agency |
---|---|---|
[1] | Reactor Safety Study: An Assessment of Accident Risks in U.S. Nuclear Power Plants (WASH 1400 / NUREG-75/014); US Nuclear Regulatory Commission: Washington DC (October 1975) | NRC |
[2] | United States Code of Federal Regulations 10CFR52 - Licenses, Certifications, and Approvals for Nuclear Power Plants | NRC |
[3] | Standard for Level 1 / Large Early Release Frequency Probabilistic Risk Assessment for Nuclear Power Plant Applications; ASME/ANS RA-Sa-2009; American Society of Mechanical Engineers; New York, NY (2009) | ASME |
[4] | Insights on Risk Margins and Nuclear Power Plants: A Technical Evaluation of Margins in Relation to Quantitative Health Objectives and Subsidiary Risk Goals in the United States; 3002012967; Electric Power Research Institute; Palo Alto, CA (May 2018) | EPRI |
[5] | The Nexus Between Safety and Operational Performance in the U.S. Nuclear Industry; Nuclear Energy Institute; Washington, DC (March 2020) | NEI |
[6] | Probabilistic Risk Assessment Standard for Advanced Non-Light Water Reactor Nuclear Power Plants; ASME/ANS RA-S-1.4-2001; American Society of Mechanical Engineers; New York, NY (2021) | ASME |
[7] | Acceptability of Probabilistic Risk Assessment Results for Non-Light-Water Reactor Risk-Informed Activities; Regulatory Guide 1.247 (For Trial Use); US Nuclear Regulatory Commission; Washington, DC, (March 2022) | NRC |
[8] | Risk-Informed Performance-Based Technology Inclusive Guidance for Non-Light Water Reactor Licensing Basis Development; NEI 18-04 (Revision 1); Nuclear Energy Institute; Washington, DC (August 2021) | NEI |
[9] | Guidance for a Technology-Inclusive, Risk-Informed, and Performance-Based Methodology to Inform the Licensing Basis and Content of Applications for Licenses, Certifications and Approvals for Non-Light-Water Reactors; Regulatory Guide 1.233; US Nuclear Regulatory Commission; Washington, DC, (June 2020) | NRC |
[10] | Advances in Small Modular Reactor Technology Developments A Supplement to: IAEA Advanced Reactors Information System (ARIS) 2020 Edition; International Atomic Energy Agency; Vienna, Austria (September 2022) | IAEA |
[11] | United States Code of Federal Regulations 10CFR50 Appendix A: General Design Criteria for Nuclear Power Plants | NRC |
[12] | Guidance for Developing Principal Design Criteria for Non-Light Water Reactors; Regulatory Guide 1.232 Revision 0; US Nuclear Regulatory Commission; Washington, DC, (2018) | NRC |
[13] | The Canadian Nuclear Safety Commission’s Strategy Readiness to Regulate Advanced Reactor Technologies; Canadian Nuclear Safety Commission; Ottawa, Ontario (December 2019) | CNSC |
[14] | IAEA Safety Standards Series No. SSR-2/1 Rev 1; Safety of Nuclear Power Plants: Design; IAEA Safety Standards; International Atomic Energy Agency; Vienna, Austria (2016) | IAEA |
[15] | IAEA-TECDOC-1366; Considerations in the Development of Safety Requirements for Innovative Reactors: Application to Modular High Temperature Gas Cooled Reactors, International Atomic Energy Agency; Vienna, Austria (2003) | IAEA |
[16] | IAEA-TECDOC-1570; Proposal for a Technology-Neutral Safety Approach for New Reactor Designs; International Atomic Energy Agency; Vienna, Austria (2003) | IAEA |
[17] | IAEA-TECDOC-2010; Approach and Methodology for the Development of Regulatory Safety Requirements for the Design of Advanced Nuclear Power Reactors, Case Study on Small Modular Reactors; International Atomic Energy Agency; Vienna, Austria (2022) | IAEA |
[18] | CNSC REGDOC-3.5.3, Regulatory Fundamentals, version 2.0, Canadian Nuclear Safety Commission; Ottawa, Ontario (February 2020) | CNSC |
[19] | Memorandum of Cooperation on Advanced Reactor and Small Modular Reactor Technologies between the United States Nuclear Regulatory Commission and the Canadian Nuclear Safety Commission (August 2019) | NRC & CNSC |
[20] | Technology Inclusive and Risk-Informed Reviews for Advanced Reactors: Comparing the US Licensing Modernization Project with the Canadian Regulatory Approach | NRC & CNSC |
[21] | Guidance for Developing Principal Design Criteria for Advanced (Non-Light Water) Reactors, Rep. INL/EXT-14-31179, Revision 1; Idaho National Laboratory; Idaho Falls, ID (December 2014) | INL |
[22] | IAEA-TECDOC-1909; Consideration on Performing Integrated Risk Informed Decision Making; IAEA, Vienna, Austria (2020) | IAEA |
[23] | Generation IV International Forum (GIF), 2002. A Technology Roadmap for Generation IV Nuclear Energy Systems. GIF-002-00 | DOE |
[24] | Brandon Chisholm, Steve Krahn, Amir Afzali, and Eric Harvey; Application of a Method to Estimate Risk in Advanced Nuclear Reactors: A Case Study on the Molten Salt Reactor Experiment; Probabilistic Safety Assessment and Management PSAM 14; September 2018; Los Angeles, CA | PSAM |
[25] | OECD/NEA, “A Joint Report on PSA for New and Advanced Reactors"; Nuclear Safety NEA/CSNI/R(2012)17; 2012; Organisation for Economic Cooperation and Development - Nuclear Energy Agency; Paris, France | OECD/NEA |
[26] | Brandon Chisholm, Steve Krahn, Andrew Sowder, Amir Afzali, Development of a Methodology for Early Integration of Safety Analysis into Advanced Reactor Design, American Nuclear Society PSA 2019, Charleston, SC, April 28 - May 3, 2019 | ANS |
[27] | Brandon M. Chisholm, Steven L. Krahn, Karl N. Fleming, "A systematic approach to identify initiating events and its relationship to Probabilistic Risk Assessment: Demonstrated on the Molten Salt Reactor Experiment", Progress in Nuclear Energy 129 (2020) 103507 | Vanderbilt |
[28] | Program on Technology Innovation: Early Integration of Safety Assessment into Advanced Reactor Design - Project Capstone Report: EPRI, Palo Alto, CA: 2019. 3002015752. | EPRI |
[29] | Compilation of Molten Salt Reactor Experiment (MSRE) Technical, Hazard, and Risk Analyses: A Retrospective Application of Safety-in-Design Methods. EPRI, Palo Alto, CA: 2020. 3002018340. | EPRI |
[30] | Mostafa Hamza and Mihai A. Diaconeasa, "A framework to implement human reliability analysis during early design stages of advanced reactors"; Progress in Nuclear Energy; 146 (2022); 104171 | NC State |
[31] | Program on Technology Innovation: Probabilistic Risk Assessment Requirements for Passive Safety Systems. EPRI, Palo Alto, CA: 2007. 1015101. | EPRI |
[32] | Program on Technology Innovation: Comprehensive Risk Assessment Requirements for Passive Safety Systems. EPRI, Palo Alto, CA; 2008. 1016747. | EPRI |
[33] | Samuel Abiodun Olatubosun and Carol Smidts; "Reliability analysis of passive systems: An overview, status and research expectations"; Progress in Nuclear Energy; 143 (2022); 104057 | Ohio State |
[34] | Zhi'ao Huang, Huifang Miao, Morten Lind, Xinxin Zhang, and Jing Wu; "Probabilistic safety margin characterization of an integrated small modular reactor using MFM and adaptive polynomial chaos"; Annals of Nuclear Energy; 171 (2022); 109016 | Xiamen University |
[35] | Kyungho Jin, Hyeonmin Kim, Seunghyoung Ryu, Seunggeun Kim, and Jinkyun Park; "An approach to constructing effective training data for a classification model to evaluate the reliability of a passive safety system"; Reliability Engineering and System Safety; 222 (2022); 108446 | KAERI |
[36] | R.B. Solanki, Harshavardhan D. Kulkarni, Suneet Singh, P.V. Varde, and A.K. Verma; "Reliability assessment of passive systems using artificial neural network based response surface methodology"; Annals of Nuclear Energy; 144 (2020); 107487 | Multi |
[37] | Jalil Jafari, Francesco D'Auria, Hossein Kazeminejad, Hadi Davilu, "Reliability evaluation of a natural circulation system"; Nuclear Engineering and Design, Volume 224, Issue 1, September 2003, Pages 79-104 | Multi |
[38] | Marques, M., Pignatel, J. F., Saignes, P., D'Auria, P., Burgazzi, L., Müller, C. "Methodology for the reliability evaluation of a passive system and its integration into a probabilistic safety assessment"; Nucl. Eng. Des. 235, 2612-2631. Doi:10.1016/j.nucengdes.2005.06.008 (2005) | Multi |
[39] | Nayak, A. K., and Vijayan, P. K. (2008). "Flow instabilities in boiling two-phase natural circulation systems a review"; Sci. Technol. Nucl. Install. (2008), 15. Doi:10.1155/2008/573192 | Multi |
[40] | Arun Kumar Nayak, Amit Chandrakar and Gopika Vinod, "A review: passive system reliability analysis - accomplishments and unresolved issues"; Front. Energy Res., 10 October 2014, Sec. Nuclear Energy, Volume 2 - 2014 | Multi |
[41] | United Kingdom National Nuclear Regulator Position Paper, “Considerations of External Events for New Nuclear Installations”; PP-0014, Rev 0 | NNR |
[42] | TECDOC-1487, “Advanced Nuclear Power Plant Design Options to Cope with External Events”, IAEA-TECDOC-1487 ¦ 92-0-100506-7, 2006 | IAEA |
[43] | IAEA, Technical Approach to Probabilistic Safety Assessment for Multiple Reactor Units, Safety Report Series To Be Published, IAEA, Vienna (2019) | IAEA |
[44] | 1st International Conference on Generation IV and Small Modular Reactors, Whole-Site Risk Considerations for Small Modular Reactors, J. Vecchiarelly, C. Lorencez and G. Archinoff, Ottawa (2018) | N/A |
[45] | U.S. NRC, Exploring the Need for Standard Approaches to Addressing Risk Associated with Multi-Module Operation in Plants Using Small Modular Reactors, M. A. Caruso, US NRC, Washington DC | NRC |
[46] | Small Modular Reactors Regulators' Forum: Design and Safety Analysis Working Group Report on Multi-unit/Multi-module aspects specific to SMRs, INTERIM REPORT, 15 December 2019 | SMRRF |
[47] | Framework for Assessing Multi-Unit Risk to Support Risk-Informed Decision-Making: General Framework and Application-Specific Requirements. EPRI, Palo Alto, CA: 2001. 3002020765. | EPRI |
[48] | Nicholas W. Touran, John Gilleland, Graham T. Malmgren, Charles Whitmer, William H. Gates III, “Computational Tools for the Integrated Design of Advanced Nuclear Reactors”; Engineering 3 (2017) 518–526 | TerraPower |
[49] | HAZCADS: Hazards and Consequences Analysis for Digital Systems (Revision 1). EPRI, Palo Alto, CA: 2021. 3002016698. | EPRI |
[50] | Ibrahim A. Alrammah, “Analysis of nuclear accident scenarios and emergency planning zones for a proposed Advanced Power Reactor 1400 (APR1400)”; Nuclear Engineering and Design, Volume 407, June 2023, 112275 | KACST |
[51] | Federica C.V. Mancini, Eduardo Gallego, Marco E. Ricotti, "Revising the Emergency Management Requirements for new generation reactors"; Progress in Nuclear Energy, Volume 71, March 2014, Pages 160-171 | Multi |
[52] | H.D. Gougar, D.A. Petti,, P.A. Demkowicz,, W.E. Windes, G. Strydom, J.C. Kinsey, J. Ortensi, M. Plummer, W. Skerjanc, R.L. Williamson, R.N. Wright, D. Li, A. Caponiti, M.A. Feltus, and T.J. O'Connor, "The US Department of Energy's high temperature reactor research and development program - Progress as of 2019"; Nuclear Engineering and Design; Volume 358, March 2020; 110397 | INL |
[53] | Enterprise Risk Management and Risk-Informed Decision-Making. EPRI, Palo Alto, CA: 2022. 3002023855. | EPRI |
[54] | Acceptability of Probabilistic Risk Assessment Results for Risk-Informed Activities; Regulatory Guide 1.200 Revision 3; December 2020; United States Nuclear Regulatory Commission; Washington, DC | NRC |
[55] | F. Bianchi, et al.; "The REPAS Approach to the Evaluation of Passive Safety Systems Reliabilit"; Passive System Reliability - A Challenge to Reliability Engineering and Licensing of Advanced Nuclear Power Plants: Proceedings of an International Workshop Hosted by the Commissariat à l'Energie Atomique (CEA); NEA/CSNI/R(2002)10; Cadarache, France (26 June 2002) | OECD/NEA |
[56] | M. E. Ricotti, et al.; "Reliability Methods for Passive Systems (RMPS) Study-Strategy and Results," Passive System Reliability - A Challenge to Reliability Engineering and Licensing of Advanced Nuclear Power Plants; Proceedings of an International Workshop Hosted by the Commissariat à l'Energie Atomique (CEA); NEA/CSNI/R(2002)10; Cadarache, France (26 June 2002) | OECD/NEA |
[57] | Systems Engineering Process: Methods and Tools for Digital Instrumentation and Control Projects. EPRI, Palo Alto, CA: 2016. 3002008018. | EPRI |
[58] | HFAM - Human Factors Analysis Methodology for Digital Systems: A Risk-Informed Approach to Human Factors Engineering. EPRI, Palo Alto, CA: 2021. 3002018392. | EPRI |
[59] | Advanced Reactor Roadmap – Phase 1: North America. EPRI, Palo Alto, CA: 2023. 3002027504. | EPRI |