Numerical Investigation on Residual Stresses of the Safe-End/Nozzle Dissimilar Metal Welded Joint in CAP1400 Nuclear Power Plants
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The residual stress evolution in a safe-end/nozzle dissimilar metal welded joint of CAP1400 nuclear power plants was investigated in the manufacturing process by finite element simulation. A finite element model, including cladding, buttering, post-weld heat treatment (PWHT) and dissimilar metal multi-pass welding, is developed based on SYSWELD software to investigate the evolution of residual stress in the aforementioned manufacturing process. The results reveal a large tensile axial residual stress, which exists at the weld zone on the inner surface, leads to a high sensitivity to stress corrosion cracking (SCC). PWHT process before dissimilar metal multi-pass welding process has a great influence on the magnitude and distribution of final axial residual stress. The risk of SCC on the inner surface of the pipe will increase if PWHT process is not taken into account. Therefore, such crucial thermal manufacturing process such as cladding, buttering and post-weld heat treatment, besides the multi-pass welding process, should be considered in the numerical model in order to accurately predict the distribution and the magnitude of the residual stress.
KeywordsCAP1400 nuclear power plants Nozzle Safe-end Dissimilar metal welding Residual stress
This work was supported by the Open-ended Fund of the CAS Key Laboratory of Nuclear Materials and Safety Assessment (Grant No. 2015NMSAKF02).
- E.H. Han, Acta Metall. Sin. 47, 769 (2011). (in Chinese) Google Scholar
- H.L. Ming, Z.M. Zhang, J.Q. Wang, E.H. Han, M.X. Su, Acta Metall. Sin. 53, 57 (2017). (in Chinese) Google Scholar
- J. Katsuyama, M. Udagawa, H. Nishikawa, M. Nakamura, K. Onizawa, E-J Adv. Maint. 2, 50 (2010)Google Scholar
- S. Courtin, X. Ficquet, T.T.T. Le, P. Gilles, M. Yescas, in Proceedings of the ASME 2012 Pressure Vessels and Piping Conference, Toronto, Ontario, Canada, 15–19 July 2012 Google Scholar
- O. Doyen, D. Ayrault, A. Bonaventure, Weld. World 7, 1 (2015)Google Scholar
- J. Katsuyama, H. Nishikawa, M. Udagawa, M. Nakmura, K. Onizawa, J. Press. Vessel Technol. 135, 051402-1 (2013)Google Scholar
- ESI Group, Material Database for SYSWELD 2010 (ESI France, Paris, 2009)Google Scholar