PSI - Issue 60

Md Rakim et al. / Procedia Structural Integrity 60 (2024) 136–148

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Md Rakim et al. / Structural Integrity Procedia 00 (2023) 000 – 000

Chen, X., Yang, Z., Sokolov, M.A., Erdman III, D.L., Mo, K., Stubbins, J.F., 2014. Effect of creep and oxidation on reduced fatigue life of Ni-based alloy 617 at 850 °C. Journal of Nuclear Materials 444, 393-403. Dieter, G.E., 2013. Mechanical Metallurgy, McGraw-Hill Education, Third Edition. Guo, Y., Wang, B., Hou, S., 2013. Aging precipitation behavior and mechanical properties of Inconel 617 superalloy. Acta Metallurgica Sinica (English Letter) 26, 307-312. Karnati, A.K., Sarkar, A., Nagesha, A., Parameswaran, P., Sandhya, R., Narasaiah, N., 2019. Evaluation of high cycle fatigue behaviour of alloy 617M at 973 K: Haigh diagram and associated mechanisms. International Journal of Pressure Vessels and Piping 172, 304-312. Kim, S.J., Choi, P.H., Dewa, R.T., Kim, W.G., Kim, M.H., 2014. Low cycle fatigue properties of alloy 617 base metal and weld joint at room temperature. Procedia Materials Science 3, 2201 – 2206. Kim, W.G., Park, J.Y., Ekaputra, I.M.W., Hong, S.D., Kim, S.J., Kim, Y.W., 2013. Comparative study on the high-temperature tensile and creep properties of Alloy 617 base and weld metals. Journal of Mechanical Science and Technology 27, 2331-2340. Klower, J., Husemann, R.U., Bader, M., 2013. Development of nickel based on alloy 617 for components in 700°C power plants. 6 th International Conferences on Creep, Fatigue and Creep-Fatigue Interaction, Procedia Engineering 55, 226-231. Rahman, M.S., Priyadarshan, G., Raja, K.S., Nesbitt, C., Misra, M., 2009. Characterization of high-temperature deformation behaviour of INCONEL 617. Mechanics of Materials 41, 261-270. Rao, Ch.V., Srinivas, N.C.S., Sastry, G.V.S., Singh, V., 2019. Dynamic strain ageing, deformation and fracture behaviour of the nickel-base superalloy Inconel 617. Materials Science & Engineering A 742, 42-60. Rao, K.B.S., Schiffers, H., Schuster, H., Nickel, H., 1988. Influence of time and temperature dependent processes on strain controlled low cycle fatigue behaviour of alloy 617. Metallurgical Transactions A 19, 359-371. Sah, I., Park, J., Kim, E.S., 2023. Fatigue life curves of alloy 617 in the temperature range of 800 – 950 °C. Nuclear Engineering and Technology 55, 546-554. Sarkar, A., Ghosh, C., Nagesha, A., Mythili, R., 2020. Mechanisms of fatigue endurance in alloy 617M at different temperatures (300-1023 K). Journal of Materials Engineering and Performance 29, 5663 – 5671. Shankar, V., Kumar, A., Mariappan, K., Sandhya, R., Laha, K., Bhaduri, A.K., Narasaiah, N., 2017. Occurrence of dynamic strain ageing in Alloy 617M under low cycle fatigue loading. International Journal of Fatigue 100, 12 20. Singh, A.N., Moitra, A., Bhaskar, P., Sasikala, G., Dasgupta, A., Bhaduri, A.K., 2018. Effect of thermal ageing on microstructure, hardness, tensile and impact properties of Alloy 617. Materials Science & Engineering A 710, 47-56. Suresh, S., 1998. Fatigue of Materials. Cambridge University Press, Cambridge, United Kingdom. Totemeier, T.C., Tian, H., 2007. Creep-fatigue interactions in INCONEL 617. Materials Science and Engineering A 468-470, 81 – 87.

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