PSI - Issue 46

W. Li et al. / Procedia Structural Integrity 46 (2023) 119–124 Wei Li et al. / Structural Integrity Procedia 00 (2021) 000–000

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Grbović, A., Sedmak, A., Kastratović, G., Petrašinović, D., Vidanović, N., Sghayer, A., 2019. Effect of laser beam welded reinforcement on integral skin panel fatigue life, Engineering Failure Analysis 101, 383-393. Li, X., Zhang, Y., Li, W., Zhou, S., Sun, R., Li, C., Wang, P., Sakai, T., 2021. Very high cycle fatigue of a nickel-based superalloy at room and elevated temperatures: Interior failure behavior and life prediction. Int. J. Fatigue 151, 106349. Mlikota, M., Schmauder, S., Božić, Ž., Hummel, M., 2017. Modelling of Overload Effects on Fatigue Crack Initiation in Case of Carbon Steel. Fatigue and Fracture of Engineering Materials and Structures 40(8), 1182–1190. Mlikota, M., Schmauder, S., Božić, Ž., 2018. Calculation of the Wöhler (S-N) Curve using a Two-scale Model. International Journal of Fatigue 114, 289–297. Mlikota, M., Dogahe, K., Schmauder, S., Božić, Ž., 2021. Influence of the Grain Size on the Fatigue Initiation Life Curve, International Journal of Fatigue, 106562. Mlikota, M., Schmauder, S., Dogahe, K., Božić, Ž., 2021. Influence of local residual stresses on fatigue crack initiation, Procedia Structural Integrity 31, 3-7. Murakami, Y., 2002, Metal Fatigue - Effects of Small Defects and Nonmetallic Inclusion, Amsterdam Boston: Elsevier Science. Li, W., Sun, R., Wang, P., Li, X., Zhang, Y., Hu, T., Li, C., Sakai, T., 2021. Subsurface faceted cracking behavior of selective laser melting Ni-based superalloy under very high cycle fatigue. Scripta Materialia 194, 113613. Petrova, V., Schmauder, S, Ordyan, M., Shashkin, A., 2019. Revisit of antiplane shear problems for an interface crack: Does the stress intensity factor for the interface Mode III crack depend on the bimaterial modulus? Engineering Fracture Mechanics 216, 106524. Popovich, V.A., Borisov, E.V., Heurtebise, V., Riemslag, T., Popovich, A.A., Sufiiarov, V.S., 2018. Creep and thermomechanical fatigue of functionally graded Inconel 718 produced by additive manufacturing, 147th Annual Meeting and Exhibition, Phoenix, Arizona, March 11–15, pp. 85–97. Rezaei, A., Rezaeian, A., Kermanpur, A., Badrossamay, M., Foroozmehr, E., Marashi, M., Foroozmehr, A., 2020. Han, J., Microstructural and mechanical anisotropy of selective laser melted IN718 superalloy at room and high temperatures using small punch test, Mater. Charact. 162, 110200. Sakai, A. Nakagawa T., Oguma, N., Nakamura, Y., Ueno, A., Kikuchi, S., Sakaida, A., 2016. A review on fatigue fracture modes of structural metallic materials in very high cycle regime, Int. J. Fatigue 93, 339-351. Stinville, J.C., Martin, E., Karadge, M., Ismonov, S., Soare, M., Hanlon, T., Sundaram, S., Echlin, M.P., Callahan, P.G., Lenthe, W.C., Miller, V.M., Miao, J., Wessman, E, A., Finlay, R., Loghin, A., Marte, J., Pollock, T. M., 2018. Fatigue deformation in a polycrystalline nickel base superalloy at intermediate and high temperature: Competing failure modes, 152, 16-33. Sujata, M., Madan, M., Raghavendra, K., Venkataswamy, M. A., Bhaumik, S. K., 2010. Identification of failure mechanisms in nickel base superalloy turbine blades through microstructural study. Engineering Failure Analysis, 17(6), 1436-1446. Watring, D.S., Benzing, J.T., Hrabe, N., Spear, A.D., 2020. Effects of laser-energy density and build orientation on the structure–property relationships in as-built Inconel 718 manufactured by laser powder bed fusion, Addit. Manuf. 36, 101425. Witkin, D.B., Patel, D.N., Bean, G.E., 2019. Notched fatigue testing of inconel 718 prepared by selective laser melting, Fatigue Fract. Eng. Mater. Struct. 42 (1), 166–177. Xu, Z., Hyde, C.J., Tuck, C., Clare, A.T., 2018. Creep behaviour of inconel 718 processed bylaser powder bed fusion, J. Mater. Process. Technol. 256, 13–24. Zhu, M., Jin, L., Xuan, F., 2018. Fatigue life and mechanistic modeling of interior micro-defect induced cracking in high cycle and very high cycle regimes, Acta Materialia, 157, 259–275.