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核技术 2014

核反应堆压力容器接管安全端堆焊修复结构的LBB分析

DOI: 10.11889/j.0253-3219.2014.hjs.37.010603, PP. 10603-10603

魏敏,王国珍,轩福贞,涂善东,刘长军

Keywords: 堆焊修复,LBB(Leak-before-break)曲线,韧带失稳线,核电安全端,焊接接头

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Abstract:

核反应堆压力容器接管安全端异种金属焊接接头在服役中通常会产生高温高压水环境中的应力腐蚀裂纹扩展。目前减轻和修复这种裂纹的技术是在安全端管接头外表面堆焊一层更抗腐蚀的镍基合金(Alloy52M)材料。本文通过三维结构的有限元断裂力学分析，计算得到了堆焊修复结构的“先漏后断”(Leak-before-break,LBB)曲线和韧带失稳线，并分析了堆焊层厚度对LBB安全边际的影响。结果表明，堆焊修复后结构的LBB曲线和韧带失稳线在没有堆焊层结构的曲线上方，且随堆焊层厚度的增加，LBB曲线和韧带失稳线上移，表明堆焊修复及堆焊层厚度的增加使安全端结构的LBB安全边际增大。

References

[1]	Zhang T，, Brust B， Wilkowski G. Weld Residual Stress Analysis and the Effects of Structural Overlay on Various Nuclear Power Plant Nozzles [C], Proceedings of the ASME 2010 Pressure Vessels & Piping Division, July18-22,2010,Bellevue,Washington,USA.
[2]	Tsai YL, Wang LH., Fan TW., Ranganath S, Wang CK., Chou CP.. Welding overlay analysis of dissimilar metal weld cracking of feedwater nozzle. International [J]. Journal of Pressure Vessels and Piping , 2009, 87(5): 26-32.
[3]	Marlette S, Treyer P. Simulation and Measurement of Through-wall Residual Stresses in a Structural Weld Overlaid Pressurizer Nozzle. [C]. Proceedings of the ASME 2010 Pressure Vessels & Piping Division. July 18-22,2010, Bellevue, Washington, USA.
[4]	Killian DE.. Design of a Weld Overlay for a Large Bore Pipe Nozzle to Optimize Residual Stress. [C].Proceedings of the ASME 2010 Pressure Vessels & Piping Division. July 18-22,2010, Bellevue, Washington, USA.
[5]	Liu R F, Huang C C. Welding residual stress analysis for weld overlay on a BWR feedwater nozzle[J]. Nuclear Engineering and Design, 2012.
[6]	Varfolomeev I, Ivanov D et al. Probabilistic leak-before-break assessment of a main coolant line [C]. PVP2010, July 18-22,2010, Bellevue, Washington, USA, PVP2010-25676.
[7]	Itatani M, Saito T, Hayashi T, et al. Evaluation of fracture characteristics of Ni-base weld metal for BWR components [C]. Proceedings of the ASME 2009 Pressure Vessels and Piping Divisions Conference, PVP2009, July 26-30, 2009, Prague, Czech Republic. (PVP2009-77720).
[8]	Tanguy B, Besson J, Piques R, et al. Ductile to brittle transition of an A508 steel characterized by Charpy impact test: Part I: experimental results[J]. Engineering fracture mechanics, 2005, 72(1): 413-434.
[9]	刘建章.核结构材料[M]. 北京：化学工业出版社，2007.
[10]	PWR Material Realiability Project, Interim Alloy 600 Safety Assessment for U.S. PWR Plants, Part 1: Alloy82/182 pipe butt welds. EPRI Report TP-1001491, 2001.
[11]	Celin R, Tehovnik F. Degradation of a Ni-Cr-Fe Alloy in a Pressurised-Water Nuclear Power Plant[J]. Materiali in tehnologije, 2011, 45(2): 151-157.
[12]	Jenssen A, Norrgard K, Lagerstron J. Assessment of cracking in dissimilar metal welds [C], Proc. of Tenth Int. Symp. on Envionmental Degradation of Materials in Nuclear Power Systems-Water Reactors. USA: NACE International. 2001: CD-ROM.
[13]	Farley S. An overview of non destructive inspection service in nuclear power plants [C]. International Conference on Nuclear Energy for New Europe. Portoraz, Slovenia, 2004.
[14]	ASME. Boiler and pressure vessel code, code case N-504-2. Alternative rules for repair of classes 1，2 and 3 austenitic stainless steel piping section XI，division 1;1995.
[15]	Wang H T, Wang G Z, Xuan F Z, et al. Numerical investigation of ductile crack growth behavior in a dissimilar metal welded joint[J]. Nuclear Engineering and Design, 2011, 241(8): 3234-3243.
[16]	Gong N, Wang G Z, Xuan F Z, et al. Leak-before-break analysis of a dissimilar metal welded joint for connecting pipe-nozzle in nuclear power plants[J]. Nuclear Engineering and Design, 2013, 255: 1-8.

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