Issue 29

L. Zhao et alii, Frattura ed Integrità Strutturale, 29 (2014) 410-418; DOI: 10.3221/IGF-ESIS.29.36 418 A CKNOWLEDGEMENTS he supports from Natural Science Foundation of China (Grants Nos. 11072191 and 1201277), Scientific Research Program Funded by Shaanxi Provincial Education Commission (Program Nos. 12JK0851 and 2013JK0611) and Research Fund for the Doctoral Program of Higher Education of China (Grants Nos. 20136121110001) are appreciated. R EFERENCES [1] Bamford, W., Hall, J., A review of Alloy 600 cracking in operating nuclear plants including Alloy 82 and 182 weld behavior, ASME 12 th International Conference on Nuclear Engineering, (2004) 131–139. [2] Bamford, W., Newton, B., Seeger, D., Recent experience with weld overlay repair of indications in alloy 182 butt welds in two operating PWRs, ASME 2006 Pressure Vessels and Piping Conference, (2006) 427–434. [3] Li, G.F., Congleton, J., Stress corrosion cracking of a low alloy steel to stainless steel transition weld in PWR primary waters at 292 Ԩ , Corros. Sci., 42(6) (2000) 1005–1021. [4] Li, G.F., Li, G.J., Fang, K.W., Stress corrosion cracking behavior of dissimilar metal weld A508/52M/316L in high temperature water environment, Acta Metallurgica Sinica, 47(7) (2011) 797–803. [5] Andresen, P.L., Young, L.M., Emigh, P.W., et al., Stress corrosion crack growth rate behavior of Ni Alloys 182 and 600 in high temperature water, NACE Corrosion, (2002) 02510. [6] Deng, D., Kiyoshima, S., FEM prediction of welding residual stresses in a SUS304 girth-welded pipe with emphasis on stress distribution near weld start/end location, Comp. Mater. Sci., 50(2) (2010) 612–621. [7] Andresen, P.L., Environmentally assisted growth rate response of nonsensitized AISI 316 grade stainless steels in high temperature water, Corrosion, 44(7) (1988) 450–460. [8] Xue, H., Ogawa, K., Shoji, T, Effect of welded mechanical heterogeneity on local stress and strain in stationary and growing crack tips, Nucl. Eng. Des., 236(5) (2009) 628–640. [9] Xue, H., Shoji, T., Quantitative prediction of EAC crack growth rate of sensitized type 304 stainless steel in boiling water reactor environments based on EPFEM, J. Press. Vess.-T. ASME, 129(3) (2007) 460–467. [10] Ueda, Y., Shi, Y., Sun, S., et al., Effect of crack depth and strength mis-matching on the relation between J-integral and CTOD for welded tensile specimens (mechanics, strength & structure design), Trans. JWRI, 26(1) (1997) 133– 140. [11] Peng, Q.J., Xue, H., Hou, J., et al., Role of water chemistry and microstructure in stress corrosion cracking in the fusion boundary region of an Alloy 182-A533B low alloy steel dissimilar weld joint in high temperature water, Corros. Sci., 53(12) (2011) 4309–4317. [12] Hayashi, T., Hankinson, S.F., Saito, T., et al., Flaw evaluation for PWR and BWR component weld joints using advanced FEA modeling techniques, ASME 2009 Pressure Vessels and Piping Conference, (2009) 1125–1139. [13] Lu, Z.P., Shoji, T., Xue, H., et al., Deterministic formulation of the effect of stress intensity factor on PWSCC of Ni- base alloys and weld metals, J. Press. Vess.-T. ASME, 135(2) (2013) 021402. [14] ABAQUS v6.7, Hibbitt, Karlsson and Sorensen Inc, (2007). [15] Ford, P., Mechanisms of environmentally-assisted cracking, Int. J. Pres. Ves. Pip., 40(55) (1989) 343–362. [16] Shoji, T., Li, G., Kwon, J., et al., Quantification of yield strength effects on IGSCC of austenitic stainless steels in high temperature water, Proceedings of the 11th Conference of Environmental Degradation of Materials in Materials in Nuclear Systems, (2003) 834–844. [17] Kang, J.D., Wen, W.D., Zhang, Y.F., et al., Path dependence of J-integral in welded joint with an overmatching weld, Trans. of NUAA, 12(1) (1995) 1–8. [18] Xue, H., Sato, Y., Shoji, T., Quantitative estimation of the growth of environmentally assisted cracks at flaws in light water reactor components, J. Press. Vess.-T. ASME, 131(1) (2009) 011404. [19] Peng, Q.J., Kwon, J., Shoji, T., Development of a fundamental crack tip strain rate equation and its application to quantitative prediction of stress corrosion cracking of stainless steels in high temperature oxygenated water, J. Nucl. Mater., 324(1) (2004) 52–61. T