PSI - Issue 13

Yinghao Cui et al. / Procedia Structural Integrity 13 (2018) 1291–1296 Author name / StructuralIntegrity Procedia 00 (2018) 000 – 000

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Round Robin[M]. John Wiley & Sons, Inc. 2013. [4] He X, Shoji T. Quantitative Prediction of EAC Crack Growth Rate of Sensitized Type 304 Stainless Steel in Boiling Water Reactor Environments Based on EPFEM[J]. Journal of Pressure Vessel Technology, 2007, 129(3):460-467. [5] Xue H, Sato Y, Shoji T. Quantitative Estimation of the Growth of Environmentally Assisted Cracks at Flaws in Light Water Reactor Components[J]. Journal of Pressure Vessel Technology, 2009, 131(1). [6] M.M. Hall Jr. Crack tip strain rate equation with applications to crack tip embrittlement and active path dissolution models of stress corrosion cracking[M]. Environment-Induced Cracking of Materials. 2008:59 – 68. [7] Jr M M H. Interacting sensitivities of alloy 600 PWSCC to stress intensity factor, yield stress, temperature, carbon concentration, and crack growth orientation Alloy 600[J]. Corrosion Science, 2017. [8] Huang X, Zhang Y, Mei M, et al. A quantitative prediction model of SCC rate for nuclear structure materials in high temperature water based on crack tip creep strain rate[J]. Nuclear Engineering & Design, 2014, 278(8):686-692. [9] C. Jansson, and U. Morin, Assessment of crack growth rates in austenitic stainless steels in operating BWRs. In: proceedings of the eighth international symposium on environmental degradation of materials in nuclear systems-water reactors. Florida, August 10-14,1997. Illinois, USA: American Nuclear Society. Pp667-674.l. [10] P.L. Andresen, Environmentally assisted growth rate response of nonsensitized AISI 316 grade stainless steels in high temperature water, Corrosion, 1988, 44(7): 450-460. [11] P.L. Andresen, Fundamental quantification of crack advance for life prediction in energy systems. GE Corp. Research and Development Center, Schenectady, NY, 1996: 51-99. [12] Xue H, Sato Y, Shoji T. Quantitative Estimation of the Growth of Environmentally Assisted Cracks at Flaws in Light Water Reactor Components[J]. Journal of Pressure Vessel Technology, 2009, 131(1). [13] Ueda Y, Shi Y, Sun S. Effect of crack depth and strength mis-matching on the relation between J-integral and CTOD for welded tensile specimens(mechanics, strength & structure design) [J]. Transaction of JWRI, 1997, 26(1): 133-140. [14] Quintero H, Mehmanparast A. Prediction of creep crack initiation behavior in 316H stainless steel using stress dependent creep ductility[J]. International Journal of Solids & Structures, 2016, s 97 – 98:101-115. [15] He X, Li Y. Micro-mechanical State at Tip of Environmentally Assisted Cracking in Nickel-based Alloy[J]. Rare Metal Materials & Engineering, 2016, 45(3):537-541. [16] Han Ningning, Gu Jianfeng. Creep behavior of Inconel 600 alloy used for nuclear power[J]. Heat Treatment of Metals, 2016, 41(6):1-3. [17] Li J X, Gao K W, Su Y J. Study on stress corrosion of stainless steel caused by passivation film stress [J]. Science Sinica Technologica (Series E), 2003, 33(9): 796-803. [18] Li J X, Chu W Y, Wang Y B, et al. In situ TEM study of stress corrosion cracking of austenitic stainless steel[J]. Corrosion Science, 2003, 45(7):1355-1365.