PSI - Issue 28

L.R. Botvina et al. / Procedia Structural Integrity 28 (2020) 2118–2125 L.R. Botvina et al. / Structural Integrity Procedia 00 (2019) 000–000

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Botvina, L.R., M. R. Tyutin, T. B. Petersen, V. P. Levin, A. P. Soldatenkov, and D. V. Prosvirnin, 2018. Residual Strength, Microhardness, and Acoustic Properties of Cyclically Strained Low-Carbon Steel. Journal of Machinery Manufacture and Reliability 47(6), 513-520. L.R. Botvina, M.R. Tyutin, V.P. Levin, A.V. Ioffe, Y.S. Perminova, D.V. Prosvirnin, Mechanical and physical properties, fracture mechanisms and residual strength of 15Cr2MnMoV steel used for oil well sucker rods, Deform. Fract. Mater. (In Russian) (2020, in press). Ciuplys, A., J.Vilys, V.Сiuplys, and V.Kvedaras, 2006. Investigation of dislocation structure of low carbon steel during static loading. J Mechanika, 59-67. Dmitriev, A.A., V.V. Polyakov, and E.A. Kolubaev, 2017. Diagnostics of aluminum alloys with welded joints based on the analysis of acoustic emission signals. Fundamental problems of modern materials science 14(4), 458–463 (in Russian). Han K.S., and K.H. Oh, 2006. Acoustic emission as a tool of fatigue assessment. Key Eng. Mater. 306(308), 271–278. Murav’ev, T. V., and L. B. Zuev, 2008. Acoustic Emission during the Development of a Lüders Band in a Low-Carbon Steel. Technical Physics 53(8), 1094-1098. Skalsky, V. R., & Lyasota, I. M. 2014. Features of acoustic-emission signals during the initiation of a fatigue failure in a welded joint of an aluminum alloy of the Al-Cu-Mn system. Russian Journal of Nondestructive Testing, 50(2), 120-126.