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非能动安全壳冷却机制安全壳大气净化分析 被引量:2

Analysis of Containment Aerosol Removal Induced by Passive Containment Cooling Mechanism
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摘要 采用一体化严重事故分析工具,建立包括主冷却剂系统、专设安全设施、非能动安全壳冷却系统的事故分析模型,该模型耦合了核电厂热工水力、安全壳响应及裂变产物行为分析。研究了小破口失水事故(SB-LOCA)、大破口失水事故(LB-LOCA)以及主给水丧失事故(LOFW)始发严重事故序列下非能动安全壳冷却机制对安全壳大气的净化作用,对非能动安全壳空冷和水冷工况下对安全壳内气溶胶的去除行为进行了分析。通过无冷却、空冷有效、空冷和水冷同时有效的三种工况下气溶胶行为的比对分析,研究了冷却机制对扩散电泳和热电泳引起的气溶胶沉积。分析结果表明,非能动安全壳冷却机制可以增强气溶胶扩散电泳和热电泳的去除效应,相关分析可为严重事故管理导则的制定提供技术支持。 Based on an integrated severe accident analysis code, a severe accident analysis model is established to include the Reactor Coolant System (RCS), the Engineered Safeguard Facility (ESF) and the containment system, coupled with a thermo-hydraulic analysis, the containment response and the fission products behavior. A passive containment cooling system model is also built with consideration of the air convection cooling and the liquid film heat transfer. Three typical severe accidents induced by small break loss of the coolant accident (SB-LOCA), large break loss of the coolant accident (LB-LOCA) and loss of the feed water accident (LOFW) are considered with the containment atmosphere decontamination as a result of the passive containment cooling mechanism. ]%r every sequence, three different cases are considered, which are the case without cooling, the case with air convection, and the case with air convection and liquid film. The aerosol behaviors for different cases are studied focusing on the volatile fission products and non-volatile fission products. The results show that the passive containment cooling mechanism can enhance the removal effect of diffusion phoresis and thermo-phoresis.
作者 佟立丽 曹学武
机构地区 上海交通大学机械与动力工程学院
出处 《科技导报》 CAS CSCD 北大核心 2012年第20期29-32,共4页 Science & Technology Review
基金 国家重点基础研究发展计划(973计划)项目(2009CB724301) 国际热核聚变实验堆(ITER)计划专项(2010GB109004)
关键词 非能动安全壳冷却机制 气溶胶 扩散电泳 热电泳 passive containment cooling mechanism aerosol removal diffusionphoresis thermophoresis
分类号 TL364.3 [核科学技术—核技术及应用]
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参考文献13

  • 1Herceg J E, Ritzman R L, Oehiberg R N. Source term experiments program (STEP)[C]//Proceeding of an International Conference on Source Term Evaluation for Accident Conditions. Vienna: International Atomic Energy Agency, 1986.
  • 2Martinson Z R, Gasparini M, Hobbins R R, et O1. PBF (Power Burst Facility) severe fuel damage testl: 3 results report[R]. NUGEG/CR-5354 (EGG-2565), Washington, DC: Nuclear Regulatory Commission, 1989.
  • 3Makynen J M, Jokiniemi J K, Ahonen P P, et ol. AHMED experiments on hydroscopic and inert aerosol behavior in LWR containment conditions: Experimental results [J]. Nuclear Engineering and Design, 1997, 178(1): 45-59.
  • 4Castelo A de los R, Capitao J A, De Santi G. International standard problem 40: Aerosol deposition and resuspension [R]. Issy-les- Moulineaux, Cedex: OECD Nuclear Euclear Agency, Joint Research Centre, European Commission, 1999.
  • 5Ammirabile L, Bielauskas A, Bujan A. Progress of ASTEC validation on fission product release and transport in circuit and containment [C]. The 3rd European Review Meeting on Severe Accident Research (ERMSAR- 2008) Nesseber, Bulgaria, September 23-25, 2008.
  • 6Powers D A, Burson S B. A simplified model of aerosol removal by containment spray [R]. NUREG/CR-5966, Washington, DC: Nuclear Regulatory Commission, 1993.
  • 7Softer L, Burson S B, Fen'ell C M. Accident source terms for light-water nuclear power plants [R]. NUREG-1465, Washington, DC: Nuclear Regulatory Commission, 1995.
  • 8Michael E, Phillip G. Correlations of the rates of removal of coagulation and depositing aerosols for application to nuclear reactor safety problems [J]. Nuclear Engineering and Design, 1988, 107(3): 324-344.
  • 9Epstein M, Hauser G M, Henry R E. Thermophoretic deposition of particles in natural convection flow from a vertical plate [J]. Transaction of the ASME, 1985, 107: 272-276.
  • 10Luis E, Herranz B. In-containment source term key insights gained from a comparison between the PHEBUS-FP programme and the US- NRC NUREG-1465 revised source term[J]. Progress in Nuclear Energy, 2010, 52(5): 481-486.

二级参考文献8

  • 1SUMMERS R M.MELCOR 1.8.1 computer code manual volume 1:Primer and package users'guides,MELCOR primer[R].Albuquerque,USA:Sandia National Laboratories,1991.
  • 2张应超,季松涛,陈彭,等.MELCOR 300 MWe核电厂计算模型说明[R].北京:中国原子能科学研究院反应堆工程研究设计所,1996.
  • 3EDWARD A B,RANDALL K C,STEPHEN W W,et al.MELCOR computer code manual volume 1:Primer and package users' guides,radionuclide package users' guide[R].Albuquerque,USA:Sandia National Laboratories,1991.
  • 4FRUTOS R,GIDO D,HENNEGES G,et al.Calculation of fission product behavior in an advanced containment in case of a severe accident[J].Nuclear Engineering and Design,2000,200:173-178.
  • 5CROFF A G.ORIGEN2:A versatile computer code for calculating the nuclide compositions and characteristics of nuclear materials[J].Nuclear Technology,1983,62:335-352.
  • 6JOW H N,SPRUMG J L,ROLLSTIN J A,et al.MELCOR accident consequence code system (MACCS),volume 2,model description:NUREG/CR-4691[R].Albuquerque,USA:Sandia National Laboratories,1990.
  • 7J.P.Van Dorsselaere,B.Schwinges.Overview of the integral code[]..
  • 8J.P.Van Dorsselaere,J.C.Micaelli. .

共引文献12

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二级引证文献9

科技导报
2012年 第20期

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