Study of PWR hot leg creep rupture and RCS depressurization strategy during an SBO accident-Reference-Cited by-同舟云学术

Study of PWR hot leg creep rupture and RCS depressurization strategy during an SBO accident

Published:2021-06-01 Issue:3 Volume:86 Page:194-201
ISSN:2195-8580
Container-title:Kerntechnik
language:en
Short-container-title:

Author:

Wu L.¹²,Miao H.¹²,Yu P.¹²,Huang Z.¹²,Zheng J.¹²,Li J.¹²,Zhai Z.³,Jia T.³

Affiliation:

1. College of Energy Xiamen University No. 4221-104 Xiangan South Road Xiamen P. R. China

2. Fujian Research Center for Nuclear Engineering Xiamen City Fujian Province P. R. China

3. Science and Technology on Reactor System Design Technology Laboratory Nuclear Power Institute of China Chengdu Sichuan P.R. China

Abstract

Abstract Preventing the leakage of radioactive materials is important to nuclear safety. During a station blackout accident in pressurized water reactors, the hot leg creep rupture caused by hot leg countercurrent flow occurs before the reactor pressure vessel failure that caused by lower head rupture. The secondary fission products barrier is lost after hot leg creep rupture. An analysis for this phenomenon was done using the Modular Accident Analysis Program version 4.0.4 code. A station blackout accident for CPR1000 is simulated and the occurrence and influence of hot leg creep rupture phenomenon are analyzed in detail. After that, a sensitivity analysis of the opening of different pressurizer pilot-operated relief valves at five minutes after entering severe accident management guideline (before the hot leg creep rupture occurs) is studied. The results show that reactor pressure vessel failure time can be extended by at least 4 h if at least one pilot-operated relief valve is opened and direct containment heating phenomenon can be eliminated if at least two pilot-operated relief valves are opened.

Publisher

Walter de Gruyter GmbH

Subject

Safety, Risk, Reliability and Quality,General Materials Science,Nuclear Energy and Engineering,Nuclear and High Energy Physics,Radiation

Link

https://www.degruyter.com/document/doi/10.1515/kern-2021-0005/pdf

Reference10 articles.

1. Sarbes, A.; James, G.: Severe accident risks: an assessment for five U.S. nuclear power plants. NUREG-1150. Rep. North Bethesda Nuclear Regulatory Commission, 1990

2. Boeck, B.D.: Prevention and mitigation measures to ensure containment integrity. Nuclear Engineering and Design 209 (2001) 147, DOI:10.1016/S0029-5493(01)00397-1

3. Lee, S.; Ha, K. S.: Validation of RCS depressurization strategy and core coolability map for independent scenarios of SBLOCA, SBO, and TLOFW. Journal of Nuclear Science and Technology 51 (2014) 181, DOI:10.1080/00223131.2014.854713

4. Harris, B. L.; Shah, V. N.: Creep rupture failure of the reactor vessel hot leg nozzle during the TMLB’ accident. ASME pressure vessel and piping conference, United States, June 19, 1988

5. Rodhe, J. O.; Morris, B. W.: Status of Direct Containment Heating in CSNI Member Countries: report of task group on ex-vessel thermal-hydraulics. Tech. Rep. NEA/CSNI Report 153, OECD NEA, Paris, 1989

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