PSI - Issue 40

Vladlen Nazarov et al. / Procedia Structural Integrity 40 (2022) 325–333 Vladlen Nazarov / Structural Integrity Procedia 00 (2022) 000 – 000

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Nazarov, V., 2015a. Short Term Creep of Titanium Alloys VT5 and VT6 at High Temperature. Industrial Laboratory. Diagnostics of Materials 81(6), 57−60. Nazarov, V., 2015b. Description of Steady State Creep during Tension and Torsion of Tubular Specimens. Industrial Laboratory. Diagnostics of Materials 81(7), 60−61. Nazarov, V., Lepeshkin, A., 2016. Features of Forming and Fracture of the Rectangular Plate with a Circular Hole. News of Volgograd State Technical University: Problems of Materials Science 2, 75 – 78. Nazarov, V., 2017. Mechanical Characteristics of Creep for Titanium Alloy VT1−0 under Tension and Torsion of Tubular Specimen s. Industrial Laboratory. Diagnostics of Materials 83(2), 66−68. Nazarov, V., Lepeshkin, A., Guanghua, Z., 2020. A Mathematical Model of the Creep Process until the Beginning Time of the Shape Change. AIP Conference Proceedings 2315, 020028. Zamaraev, L., Smirnov, S., 2017. High Temperature Short Term Creep of the Grade 2 and Ti−5Al Titanium A lloys under Heating in Air and Helium. AIP Conference Proceedings, 1915, 040069. Zeng, L., Hong, Q., Yang, G., Zhao, Y.,Qi, Y., Guo, P., 2007. Tensile and Creep Properties of Ti – 600 Alloy. Trans Nonferrous Metals Soc China 17, 522 – 525. Zeng, L., Zhao, Y., Hong, Q., Yang, G., 2011. High Cycle Fatigue Property of Ti – 600 Alloy at Ambienttemperature. Journal of Alloys and Compounds 509, 2081 – 2085. Zeng, L., Zhao, Y., Mao, X., Hong, Q., Qi, Y., 2018. Creep Features of Ti – 600 Alloy at the Temperature of 650°C. Materials Science Forum 941, 995−1003.