Prediction of fatigue crack initiation life in SA312 Type 304LN austenitic stainless steel straight pipes with notch |
Murthy, A. Ramachandra
(CSIR-Structural Engineering Research Centre)
Vishnuvardhan, S. (CSIR-Structural Engineering Research Centre) Anjusha, K.V. (Vimal Jyothi Engineering College) Gandhi, P. (CSIR-Structural Engineering Research Centre) Singh, P.K. (Bhabha Atomic Research Centre) |
1 | M. Weick, J. Aktaa, Microcrack propagation and fatigue lifetime under non-proportional multiaxial cyclic loading, Int. J. Fatig. 25 (2003) 1117-1124. DOI |
2 | M. Benachour, N. Benachour, M. Benguediab, Fatigue crack initiation and propagation through residual stress field, Int. Scholarly and Scientific Res. Innovation 6 (2012) 2470-2474. |
3 | P.J. Huffman, A strain energy based damage model for fatigue crack initiation and growth, Int. J. Fatig. 88 (2016) 197-204. DOI |
4 | H.U. Yang Dong, H.U. Zhi Zhong, C.A.O. Shu Zhen, Theoretical Study on Manson-Coffin Equation for Physically Short Cracks and Lifetime Prediction, Science China Technological Sciences, 2011, pp. 1-9. |
5 | ASTM A 312/A 312M - 09, Standard Specification for Seamless, Welded and Heavily Cold Worked Austenitic Stainless Steel Pipes, ASTM International, USA. |
6 | Bhavana Joy, S. Vishnuvardhan, G. Raghava, P, P. Gandhi, Mathews M. Paul, Low cycle fatigue characteristics of SS 304 LN stainless steel, in: Proceedings of the 2nd International Conference on Materials for the Future, Thrissur, India, February 23-25, 2011. |
7 | J.-D. Hong, C. Jang, T.S. Kim, Effects of mixed strain rates on low cycle fatigue behaviors of austenitic stainless steels in a simulated PWR environment, Int. J. Fatig. 82 (2016) 292-299. DOI |
8 | J. Colin, A. Fatemi, S. Taheri, Fatigue behaviour of stainless steel 304L including strain hardening, prestraining, and mean stress effects, J. Eng. Mater. Technol. 132 (2010) 1-13. |
9 | U. Zerbst, M. Madia, M. Vormwald, H.T. Beier, Fatigue strength and fracture mechanics - a general perspective, Eng. Fract. Mech. 198 (2018) 2-23. DOI |
10 | Masayuki Kamaya, Fatigue crack tolerance design for stainless steel by crack growth analysis, Eng. Fract. Mech. 177 (2017) 14-32. DOI |
11 | F.A. Kandil, M.W. Brown, K.J. Miller, Biaxial Low-Cycle Fatigue Fracture of 316 Stainless Steel at Elevated Temperature, 280, Metals Soci, London, 1982, pp. 203-210. |
12 | M.R. Mitchell, in: M. Meshii (Ed.), Fatigue and Microstructure, ASM, Metals Park, OH, 1978, pp. 385-437. |
13 | A.S. Cheng, C. Laird, Fatig. Fract. Eng. Mater. Struct. 4 (1981) 343-353. DOI |
14 | M.A. Jameel, P. Peralta, C. Laird, Initiation and propagation of stage-I cracks in copper single crystals under load control, Mater. Sci. Eng. A342 (2003) 279-286. |
15 | ASTM E 606/E 606M - 12, Standard Test Method for Strain-Controlled Fatigue Testing, ASTM International, USA. |
16 | M.A. Meggiolaro, J.T.P. Castro, Statistical evaluation of strain-life fatigue crack initiation predictions, Int. J. Fatig. 26 (2004) 463-476. DOI |
17 | C.K. Mukhopadhyay, T. Jayakumar, T.K. Haneef, S. Suresh Kumar, B.P.C. Rao, Sumit Goyal, Suneel K. Gupta, Vivek Bhasin, S. Vishnuvardhan, G. Raghava, P. Gandhi, Use of acoustic emission and ultrasonic techniques for monitoring, Int. J. Pres. Ves. Pip. 116 (2014) 27-36. DOI |
18 | ASTM E 8/E8M - 15, Standard Test Methods for Tension Testing of Metallic Materials [Metric], ASTM International, USA. |
19 | G. Raghava, P. Gandhi, K.K. Vaze, Cyclic fracture, FCG and ratcheting studies on Type 304LN stainless steel straight pipes and elbows, Procedia Engineering 55 (2013) 693-698. DOI |
20 | K. Tanaka, T. Mura, ASME J. Appl. Mech. 48 (1981) 97-103. DOI |
21 | L.F. Coffin Jr., Trans. ASME 76 (1954) 931-950. |
22 | Jaap Schijve, The significance of fatigue crack initiation for predictions of the fatigue limit of specimens and structures, Int. J. Fatig. 61 (2014) 39-45. DOI |
23 | Jianhui Liu, Yaobing Wei, Chagfeng Yan, Shanshan Lang, Method for predicting crack initiation life of notched specimen based on damage Mechanics, J. Shanghai Jiaot. Univ. 23 (2018) 286-290. DOI |
24 | S. Suresh, R. Ritchie, Propagation of short fatigue cracks, Int. Met. Rev. 29 (1) (1984) 445-475. DOI |
25 | A. Ramachandra Murthy, P. Gandhi, S. Vishnuvardhan, G. Sudharshan, Crack growth analysis and remaining life prediction of dissimilar metal pipe weld joint with circumferential crack under cyclic loading, Nuc. Eng. Techn. 52 (2020) 2949-2957. DOI |
26 | D. Radaj, C.M. Sonsino, W. Fricke, Fatigue Assessment of Welded Joints by Local Approaches, Woodhead Publishing, 2006. |
27 | S.S. Manson, M.H. Hirschberg, Fatigue: an Inter-disciplinary Approach, Syracuse University, Syracuse, NY, 1964, pp. 133-178. |
28 | P. Darcis P, T. Lassen T, N. Recho, Fatigue behavior of welded joints - Part 2: Physical modeling of the fatigue process, Weld. J. 85 (2006) 19.S-26.S. |
29 | N. Gao, M.W. Brown, K.J. Miller, An effective method to investigate short crack growth behaviour by reverse bending testing, Int. J. Fatig. 29 (2007) 565-574. DOI |
30 | M. Zheng, E. Niemi, X. Zheng, An approach to predict fatigue crack initiation life of LY12CZ aluminium and 16 Mn steel, Theor. Appl. Fract. Mech. 26 (1997) 23-28. DOI |
31 | Y.J. Xie, X.H. Wang, Crack initiation and direction for circumferential periodic cracks in pipe under tension and torsion, Theor. Appl. Fract. Mech. 40 (2003) 153-159. DOI |
32 | P.K. Singh, V. Bhasin, K.K. Vaze, A.K. Ghosh, H.S. Kushwaha, D.S.R. Murthy, P. Gandhi, S. Sivaprasad, Fatigue studies on carbon steel piping materials and components: Indian PHWRs, Nucl. Eng. Des. 238 (2008) 801-813. DOI |
33 | P.K. Singh, K.K. Vaze, V. Bhasin, H.S. Kushwaha, P. Gandhi, D.S. Ramachandra Murthy, Crack initiation and growth behaviour of circumferentially cracked pipes under cyclic and monotonic loading, Int. J. Pres. Ves. Pip. 80 (2003) 629-640. DOI |
34 | M. Zheng, J.H. Luo, X.W. Zhao, Z.Q. Bai, R. Whang, Effect of pre-deformation on the fatigue crack initiation life of X60 pipeline steel, Int. J. Pres. Ves. Pip. 82 (2005) 546-552. DOI |