PSI - Issue 30

S.P. Yakovleva et al. / Procedia Structural Integrity 30 (2020) 193–200 Yakovleva S. P. et al. / Structural Integrity Procedia 00 (2020) 000–000

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Kim, H.S., Yim, H.J., Kim, M., 2002. Computational durability of body structure in prototype vehicles. Int. J. Automotive Technol. 3 (4), 129– 136. Makhutov, N. A.,Lebedev, M. P., Bolshakov, A. M.,Gadenin, M. M., 2013. Scientific Basis for Analysis and Reduction of Disaster Risks in the Regions of Siberia and the North. The Arctic: ecology and economics 4 (12), 1–12. Matvienko,Y.G., 2014. Modeling and Fracture Criteria in Current Problems of Strength, Survivability and Machine Safety J. Mach. Manuf. Reliab. 3, 242–249. McEvily, A., 2002. Metal Failures: Mechanisms, Analysis, Prevention. John Wiley & Sons, New-York, pp. 336. Murakami Yu., 2002, Metals Fatigue: Effects of Small Defects and Nonmetallic inclusions. Elsevier Ltd, London, UK, pp. 298. Physical Mesomechanics of Heterogeneous Media and Computer-aided Design of Materials, 1998. Panin, V. E. (Ed). Cambridge Interscience Publishing, Cambridge, pp. 339. Romanov, A.N., 2006. Patterns of Fatigue Failure. Metal Science and Heat Treatment 9, 19–27. Romanov, A. N., 2014. Role of the structural state in the formation of deformation, strength, tribological, and technology properties of structural materials. J. Mach. Manuf. Reliab. 43 (3), 233-41. Saedi N., Ashrafizadeh F., Niroumand B. et. al., 2014. Damage Mechanism and Modeling of Void Nucleation Process in a Ferrite-Martensite Dual Phase Steel. Eng. Fracture Mechanics. 127, 97–103. Sakai T., Li W., Lian B, Oguma N., 2011. Review and new analysis on fatigue crack initiation mechanisms of interior inclusion-induced fracture of high strength steels in very high cycle regime, Berger, С ., Christ, H.-J. (Eds). Very High Cycle Fatigue, Proc. Fifth Intern. Conf. VHCF-5. Berlin, Germany, 19–26. Sangid, M.D., 2013. The physics of fatigue crack initiation. Int. J. of Fatigue 57, 58–72. Volegov, P.S., Gribov, D.S., Trusov, P.V., 2015. Damage and fracture: review of experimental studies. J. Phys. Mesomechanics. 18(3), 11–24. Yakovleva, S.P., Buslaeva, I.I., Makharova, S.N., Levin, A.I., 2017. Operational Damage to the Structure and Failure of the KAMAZ Truck Spring in the Temperature–Load Conditions of the North. J. Mach. Manuf. Reliab. 46(5), 488–493. Zorin, E.E., 2013. Development of rapid diagnostics and prediction of residual life based on detection of accumulated damage of metal structure during sustained loading. Izv. MGTU-MAMI 1(15), 142–148.