Corrosion Science and Technology

  • 제6권1호
  • /
  • Pages.29-32
  • /
  • 2007
  • /
  • 1598-6462(pISSN)
  • /
  • 2288-6524(eISSN)
한국부식방식학회 (The Corrosion Science Society of Korea)
권호 표지

A Study on the Evaluation Technology of Welds Integrity in Nuclear Power Plants

  • 발행 : 2007.02.01
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

The final goal of this study is to develop the core technologies applicable to the design, operation and maintenance of welds in nuclear structures. This study includes predicting microstructure changes and residual stress for welded parts of nuclear power plant components. Furthermore, researches are performed on evaluating fatigue, corrosion, and hydrogen induced cracking and finally constructs systematically integrated evaluation system for structural integrity of nuclear welded structures. In this study, metallurgical and mechanical approaches have been effectively coordinated considering real welding phenomena in the fields of welds properties such as microstructure, composition and residual stress, and in the fields of damage evaluations such as fatigue, corrosion, fatigue crack propagation, and stress corrosion cracking. Evaluation techniques tried in this study can be much economical and effective in that it uses theoretical/semi-empirical but includes many additional parameters that can be introduced in real phenomena such as phase transformation, strength mismatch and residual stress. It is clear that residual stress makes great contribution to fatigue and stress corrosion cracking. Therefore the mitigation techniques have been approached by reducing the residual stress of selected parts resulting in successful conclusions.

키워드

참고문헌

  1. J. A. Bannantine, Fundamentals of Metal Fatigue Analysis, Prentice-Hall, Inc. (1990)
  2. C. E. Jaske, Fatigue Strength Reduction and Stress Concentration Factors for Welds in Pressure Vessels and Piping, WRC Bulletin 432 (1998)
  3. P. Dong, Int. J. of Fatigue, 23, 865 (2001)
  4. H. Adib and G. Pluvinage, Int. J. of Fatigue, 25, 67 (2003)
  5. P. Dong, J. K. Hong, and Z. Cao, 'Mesh-insensitive structural stress procedure for fatigue evaluation of welded structures,' lnt. Institute of Welding, IIW Doc. XIII-1902-01/XV-I089-01, July (2001)
  6. P. Woollin, Fatigue Crack Propagation in C-Mn Steel HAZ Microstructures Tested in Air and Seawater,' IIW Document No.XIII-1713-98, IIW (1998)
  7. NRIM, Data Sheets on Fatigue Crack Propagation Properties for Butt Welded Joints of SB42 Carbon Steel Plate for Boilers and Other Pressure Vessels, IIWXIII- 1190-86, IIW (1984)
  8. P. Dong and lK. Hong, 'Analysis of vessel and piping weld fatigue data using the master S-N curve method,' Proceedings of ASME PVP Conference, PVP-Vol.479, pp.43-48 (2004)
  9. J C. Newman Jr., Progress in Aerospace Science, 34, 347 (1998)
  10. B. Theodore and A. Richard, J. of the Electrochemical Society, 126, 1662 (1979)
  11. J. W. Oldfield, Corrosion-Industrie, 56, 134 (1981)
  12. S. M. Sharland, Corros. Sci., 33, 183 (1992)
  13. A. Turnbull, British Corrosion Journal, 15, 162 (1980)
  14. H. P. Hack, Galvanic Corrosion, ASTM (1988)
  15. Y. M. Liou, J of Applied Electrochemistry, 29, 1377 (1999)
  16. D. A. Eden, Corrosion 86, Paper 274, NACE (1986)
  17. Dominion Engineering, Inc., PWSCC Prediction Guidelines, EPRI TR-104030 (1994)
  18. EPRI, Steam Generator Integrity Assessment Guidelines: Revision 1, EPRI TR-107621-Rl (2000)
  19. Dominion Engineering, Inc., PWSCC of Alloy 600 Materials in PWR Primary System Penetrations, EPRI TR-103696 (1994)
  20. Westinghouse, Crack Growth and Microstructural Chracterization of Alloy 600 PWR Vessel Head Penetration Meterials, EPRI TR-109136 (1997)
  21. R. B. Rebak and Z. Szklarska-Smialowska, 'The mechanism of stress corrosion cracking of alloy 600 in high temperature water,' Corrosion Science, 38, 971 (1996)
  22. T. Shoji, 'Modeling and quantative prediction of environmentally assisted cracking based upon a deformationoxidation mechanism,' Proceedings of ASME PVP Conference, PVP-Vol.479, pp.175-184, 2004
  23. R. Pargeter, 'Evaluation of necessary delay before inspection for hydrogen cracks,' Welding Journal, pp.321s-329s (2001)
  24. O.K, Chopra, 'Margins for ASME code fatigue design curve margins - effects of surface finish and material variability,' Proceedings of ASME PVP Conference, PVP-Vol.453 (2003)
  25. O.K. Chopra, 'Estimation of fatigue crack initiation in austenitic stainless steels in LWR environments,' Proceedings of ASME PVP Conference, PVP-Vol.439 (2002)
  26. M. Higuchi, 'Evaluation of fatigue damage on operating plant components in LWR water,' Proceedings of ASME PVP Conference, PVP-Vol.480 (2004)
  27. M. Higuchi, 'Evaluation of fatigue damage in LWR water with and without threshold and moderated factor,' Proceedings of ASME PVP Conference, PVP- Vol.453 (2003)
  28. P. Dong and J. K. Hong, 'A two stage crack growth model incorporating environmental fatigue,' Proceedings of ASME PVP Conference, PVP-Vol.482 (2004)