Journal of the Korean Society of Safety (한국안전학회지)

The Korean Society of Safety (한국안전학회)
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Effect of Stress Concentration Factors on the Fatigue Evaluation of the Direct Vessel Injection Nozzle

원자로 직접주입노즐의 피로평가에 미치는 응력집중계수의 영향

  • Kim, Tae-Soon (Nuclear Environment Technology Institute, Korea Hydro Nuclear Power Company Ltd.) ;
  • Lee, Jae-Gon (Nuclear Environment Technology Institute, Korea Hydro Nuclear Power Company Ltd.)
  • 김태순 (한국수력원자력(주) 원자력발전기술원) ;
  • 이재곤 (한국수력원자력(주) 원자력발전기술원)
  • Received : 2010.09.17
  • Accepted : 2010.12.10
  • Published : 2010.12.31
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Abstract

A fatigue damage caused by cyclic load is considered as one of the important failure mechanisms that threaten the integrity of structures and components in a nuclear power plant. In ASME code section III NB, the fatigue analysis procedure and standard S-N curves for the class 1 components are described and these criteria should be met at the design step of components. As the current ASME S-N curves are based on the very conservative assumptions such as a local stress concentration effect, immoderate transient frequencies and a constant Young's modulus, however, they can not precisely address the fatigue behavior of components. In order to find out the technical solution for these problems, a number of researches and discussion have been carried out continuously at home and abroad over the decades. In this study, detailed fatigue analyses for DVI nozzle with various mesh density of finite elements were performed to evaluate effect of stress concentration factors on the fatigue analysis procedure and the excessive conservatism of stress concentration factors are confirmed through the analysis results.

Keywords

References

  1. ASME B&PV Code Section III, "Rules for Construction of Nuclear Power Plant Component", 1998 Edition, 1998.
  2. A. C. Thadani, "Closeout of Generic Safety Issue 190 : Fatigue Evaluation of Metal Components for 60 Year Plant Life", USNRC Memorandum, 1999.
  3. S. Majumdar, O.K. Chopra and W.J. Shack, "Interim Fatigue Design Curves for Carbon, Low-alloy, and Austenitic Stainless Steel in LWR Environments", NUREG/CR-5999, 1993.
  4. A.G. Ware, D.K. Morton and M.E. Nitzel, "Application of NUREG/CR-5999 Interim Fatigue Curves to Selected Nuclear Power Plant Components", NUREG/CR-6260, 1995.
  5. J. Keisler, O.K. Chopra and W.J. Shack, "Fatigue Strain-Life Behavior of Carbon and Low-Alloy Steels, Austenitic Stainless Steels, and Alloy 600 in LWR Environments", NUREG/CR-6335, 1995.
  6. U.S. NRC, Regulatory Guide 1.207, "Guidelines for Evaluating Fatigue Analyses Incorporating the Life Reduction of Metal Components due to the Effects of the Light-Water Reactor Environment for New Reactors", March 2007.
  7. U.S. NRC, NUREG/CR-6909, ANL-06/08, "Effect of LWR Coolant Environments on the Fatigue Life of Reactor Materials", Final Report, February 2007.
  8. R.E. Peterson, "Stress Concentration Design Factors", John Willey and Sons Inc., 1974.
  9. J.P. Holman, "Heat Transfer", 6th Edition, McGrawHill Inc., 1986.