Nuclear Engineering and Technology

Korean Nuclear Society (한국원자력학회)
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ASSESSMENT OF POSSIBILITY OF PRIMARY WATER STRESS CORROSION CRACKING OCCURRENCE BASED ON RESIDUAL STRESS ANALYSIS IN PRESSURIZER SAFETY NOZZLE OF NUCLEAR POWER PLANT

  • Lee, Kyoung-Soo (System Engineering Laboratory, KHNP Central Research Institute) ;
  • Kim, W. (Nuclear Power Generation Laboratory, Korea Electric Power Research Institute) ;
  • Lee, Jeong-Geun (Nuclear Power Generation Laboratory, Korea Electric Power Research Institute)
  • Received : 2010.12.06
  • Accepted : 2011.07.26
  • Published : 2012.04.25
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Abstract

Primary water stress corrosion cracking (PWSCC) is a major safety concern in the nuclear power industry worldwide. PWSCC is known to initiate only in the condition in which sufficiently high tensile stress is applied to alloy 600 tube material or alloy 82/182 weld material in pressurized water reactor operating environments. However, it is still uncertain how much tensile stress is re-quired to generate PWSCC or what causes such high tensile stress. This study was performed to pre-dict the magnitude of weld residual stress and operating stress and compare it with previous experi-mental results for PWSCC initiation. For the study, a pressurizer safety nozzle was selected because it is reported to be vulnerable to PWSCC in overseas plants. The assessment was conducted by nu-merical analysis. Before performing stress analysis for plant conditions, a preliminary mock-up ana-lysis was done. The result of the preliminary analysis was validated by residual stress measurement in the mock-up. After verification of the analysis methodology, an analysis under plant conditions was conducted. The analysis results show that the stress level is not high enough to initiate PWSCC. If a plant is properly welded and operated, PWSCC is not likely to occur in the pressurizer safety nozzle.

Keywords

References

  1. K. Ahluwalia, C. King, Review of Stress Corrosion Cracking of Alloys 182 and 82 in PWR Primary Water Service (MRP-220), October 2007
  2. D. Rudland, Y. Chen, T. Zhang, G. Wilkowski, J. Broussard and G. White, Comparison of Welding Residual Stress Solutions for Control Rod Drive Mechanism Nozzle, 2007 ASME Pressure Vessels and Piping Division Conference, July 22-26, 2007, San Antonio, TX, USA.
  3. D. Rudland, T. Zhang, G. Wilkowski, and A. Csontos, Welding Residual Stress Solutions for Dissimilar Metal Surge Line Nozzles Welds, 2008 ASME Pressure Vessels and Piping Divi-sion Conference, July 27-31, 2008, Chicago, IL, USA.
  4. T. Zhang, G. Wilkowski, D. Rudland, F. Brust, H. S. Mehta and D. V. Sommerville, Weld-Overlay Analysis - An Investigation of the Effect of Weld Sequencing, 2008 ASME Pressure Vessel and Piping Division Conference, July 27-31, 2008, Chicago, IL, USA.
  5. T. Zhang, F. Brust, G. Wilkowski, D. Rudland and A. Csontos, Welding Residual Stress and Multiple Flaw Evaluation for Reactor Pressure Vessel Head Replacement Welds with Alloy 52, 2009 ASME Pressure Vessels and Piping Division Conference, July 26-30, 2009, Prague, Czech Republic.
  6. D. Rudland, A. Csontos, F. Brust and T. Zhang, Welding Residual Stress and Flaw Evaluation for Dissimilar Metal Welds with Alloy 52 Inlays, 2009 ASME Pressure Vessels and Piping Division Conference, July 26-30, 2009, Prague, Czech Republic.
  7. Dong, P and Burst, F.W., Welding Residual Stresses and Effects on Fracture in Pressure Vessel and Piping Components : A Millenium Review and Beyond, Journal of Pressure Vessel Technology, Vol. 122 (2000), 328-338
  8. I. Sattari-Far, Y. Javadi, Influence of welding sequence on welding distortion in pipes, IJPVP 85 (2008) 265-274
  9. R.H. Leggatt, Residual stresses in welded structures, IJPVP 85 (2008) 144-151
  10. ABAQUS 6.7, Dassault Systemes Inc., 2008
  11. M. Prager, MPC Material Properties Database for ASME Division II Rewrite, 2001-2003
  12. ASTM, Standard test method for determining residual stresses by the hole-drilling strain gage method, ASTM E837-01, 2001
  13. Jian Lu, Handbook of Measurement of Residual Stress, The Fairmont Press Inc. 1996
  14. K.S. Lee, T.R. Kim, J.H. Park, M.W. and Kim, S.Y. Cho, 3-D Characteristics of residual stress in the plate butt weld between SA508 and F316L SS, Journal of KSME Vol. A No.33 (2009), 401-408
  15. K.S. Lee, C.Y. Park, M.W. Kim, and J.H. Park, Distribution Characteristics of Weld Residual Stress on Butt Welded Dissimilar Metal Plate, Journal of KSME Vol. A No.34 (2010), 1317-1323
  16. Evaluation of Flaws in Austenitic Steel Piping, EPRI NP-4690-SR, July, 1986
  17. Evaluation of Flaws in Austenitic Stainless Steel Piping, Trans ASME, Journal of Pressure Vessel Technology, Vol 108, (1986) 352-366 https://doi.org/10.1115/1.3264797
  18. P. O'Regan, Welding Residual and Operating Stresses in PWR Alloy 82 Butt Welds (MRP-106), February, 2004

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