PSI - Issue 54

Nikolai Kashaev et al. / Procedia Structural Integrity 54 (2024) 361–368 Kashaev et al. / Structural Integrity Procedia 00 (2023) 000 – 000

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Acknowledgements The authors would like to thank Prof. Xiang Zhang and Dr. Abdul Khadar Syed from Coventry University for providing the experimental data regarding the FCG behavior of the WAAM-fabricated specimens. References Ahmed, T., Rack, H.J., 1998. Phase transformations during cooling in α + β titanium alloys. Materials Science and Engineering, A243(1-2), 206 211. Akgun, E., Zhang, X., Biswal, R., Zhang, Y., Doré, M., 2021. Fatigue of wire+arc additive manufactured Ti-6Al-4V in presence of process-induced porosity defects. International Journal of Fatigue 150, 106315. Bagehorn, S., Wehr, J., Maier, H.J., 2017. Application of mechanical surface finishing processes for roughness reduction and fatigue improvement of additively manufactured Ti-6Al-4V parts. International Journal of Fatigue 102, 135-142. Biswal, R., Zhang, X., Syed, A.K., Awd, M., Ding, J., Walther, F., Williams, S., 2019. Criticality of porosity defects on the fatigue performance of wire + arc additive manufactured titanium alloy . International Journal of Fatigue 122, 208-217. Cao, F., Zhang, T., Ryder, M.A., Lados, D.A., 2018. A review of the fatigue properties of additively manufactured Ti-6Al-4V. JOM 70, 349-357. Fomin, F., Horstmann, M., Huber, N., Kashaev, N., 2018a. Probabilistic fatigue-life assessment model for laser-welded Ti-6Al-4V butt joints in the high-cycle fatigue regime. International Journal of Fatigue 116, 22-35. Fomin, F., Klusemann, B., Kashaev, N., 2018b. Surface modification methods for fatigue properties improvement of laser-beam-welded Ti-6Al 4V butt joints. Procedia Structural Integrity 13, 273-278. Fomin, F., Kashaev, N., 2020. Probabilistic reliability assessment of a component in the presence of internal defects , in “ Lecture Notes in Mechanical Engineering, Proceedings of the 30th Symposium of the International Committee on Aeronautical Fatigue ”. In: Niepokolczycki, A., Komorowski, J. (Eds.). Springer, Cham, pp. 488. Gong, H., Rafi, K., Gu, H., Janaki Ram, G.D., Starr, T., Stucker, B., 2015. Influence of defects on mechanical properties of Ti – 6Al – 4 V components produced by selective laser melting and electron beam melting. Materials and Design 86, 545-554. El Haddad, M.H., Topper, T.H., Smith, K.N., 1979, Prediction of non propagating cracks. Engineering Fracture Mechanics 11, 573-584. Kashaev, N., Ushmaev, D., Ventzke, V., Klusemann, B., Fomin, F., 2020. On the application of laser shock peening for retardation of surface fatigue cracks in laser beam-welded AA6056. Fatigue and Fracture of Engineering Materials and Structures 43, 1500-1513. Kitagawa, H., Takahashi, S., 1976. Applicability of fracture mechanics to very small cracks or the cracks in the early stage, in “ Proceedings of the 2nd International Conference on Mechanical Behaviour of Materials ”. American Society for Metals, Boston, pp. 627. Léopold, G., Nadot, Y., Mendez, J., Billaudeau, T., 2014. Influence of casting defects on fatigue strength of an investment cast Ti-6Al-4V alloy. MATEC Web of Conferences 12, 04004. Li, P., Warner, D.H., Fatemi, A., Phan, N., 2016. Critical assessment of the fatigue performance of additively manufactured Ti – 6Al – 4V and perspective for future research. International Journal of Fatigue 85, 130-143. Murakami Y., 2002. Metal Fatigue: Effects of Small Defects and Nonmetallic Inclusions, 1st ed. Elsevier Science. NASA, 2001, Fatigue Crack Growth Computer Program NASGRO® Version 3.0. User Manual. JSC-22267B. NASA. Lyndon B. Johnson Space Center, Houston. Newman Jr., J.C., 1984. A crack opening stress equation for fatigue crack growth. International Journal of Fracture 24(4), R131-R135. Persenot, T., Burr, A., Dendievel, R., Buffière, J.Y., Maire, E., Lachambre, J., Martin, G., 2020. Fatigue performances of chemically etched thin struts built by selective electron beam melting: Experiments and predictions. Materialia 9, 100589. Srivastava, M., Rathee, S., Patel, V., Kumar, A., Koppad, P.G., 2022. A review of various materials for additive manufacturing: Recent trends and processing issues. Journal of Materials Research and Technology 21, 2612-2641. Syed, A.K, Zhang, X., Caballero, A., Shamir, M., Williams, S., 2021a. Influence of deposition strategies on tensile and fatigue properties in a wire + arc additive manufactured Ti-6Al-4V. International Journal of Fatigue 149, 106268. Syed, A.K, Zhang, X., Davis, A.E., Kennedy, J.R., Martina, F., Ding, J., Williams, S., Prangnell, P.B., 2021b. Effect of deposition strategies on fatigue crack growth behaviour of wire + arc additive manufactured titanium alloy Ti – 6Al – 4V. Materials Science and Engineering A814, 141194. Tanaka, K., Akiniwa, Y., 1988. Resistance curve method for predicting propagation threshold of the short fatigue cracks at notches. Engineering Fracture Mechanics 30(6), 863-876. Vazquez, L., Rodriguez, M.N., Rodriguez, I., Alvarez, P., 2021. Influence of post ‐ † eposition heat treatments on the microstructure and tensile properties of Ti ‐ 6Al ‐ 4V parts manufactured by CMT ‐ WAAM. Metals, 11, 1161. Wang, F., Williams, S.W., Colegrove, P.A., Antonysamy, A.A., 2013. Microstructure and mechanical properties of wire and arc additive manufactured Ti-6Al-4V. Metallurgical and Materials Transactions, A44, 968 – 977. Zerbst, U., Vormwald, M., Pippan, R., Gaenser, H., Sarrazin-Baudoux, C., Madia, M., 2016. About the fatigue crack propagation threshold of metals as a design criterion - A review. Engineering Fracture Mechanics 153, 190 – 243. Zerbst, U., Bruno, G., Buffière, J.Y., Wegener, T., Niendorf, T., Wu, T., Zhang, X., Kashaev, N., Meneghetti, G., Hrabe, N., Madia, M., Werner, T., Hilgenberg, K., Koukolíková, M., Procházka, R., D ž ugan, J., Möller, B., Beretta, S., Evans, A., Wagener, R., Schnabel, K., 2021. Damage tolerant design of additively manufactured metallic components subjected to cyclic loading: State of the art and challenges. Progress in Materials Science 121, 100786.