https://orcid.org/0000-0003-3035-0119
References
- J. A. Collins, Faillure of Materials in Mechanical Design: Analysis, Prediction, Prevention. New York: Wiley-Interscience Publication; 1981.
- K. Naumenko and H. Altenbach, Modeling of Creep for Structural Analysis. Berlin, Germany: Springer Science & Business Media; 2007.
- R. A. Dul’nev and P. I. Kotov, Termicheskaya Ustalost’ Metallov [Thermal Fatigue of Metals]. Moscow, Russia: Mashinostroenie Publishers; 1980 (In Russian).
- L. A. Igumnov, D. A. Kazakov, D. N. Shishulin, I. A. Modin and D. V. Zhegalov, “Experimental studies of high-temperature creep of titanium alloy VT6 under conditions of a complex stress state under the influence of an aggressive medium,” Vestnik Samarskogo Gosudarstvennogo Tekhnicheskogo Universiteta, Seriya Fiziko-Matematicheskie Nauki, vol. 25, no. 2, pp. 286–302, 2021. DOI: 10.14498/vsgtu1850.
- A. G. Kazantsev, Issledovanie vzaimodeystviya malotsiklovoy ustalosti i polzuchesti pri neizotermicheskom nagruzhenii [Investigation of the interaction of low-cycle fatigue and creep under non-isothermal loading]. Problemy prochnosti [Strength of Materials]; 1985, No 5., pp. 25–31 (In Russian).
- I. A. Volkov and Y. Korotkikh, Uravneniya sostoyaniya vyazkouprugoplasticheskikh sred s povrezhdeniyami [State Equations for Viscoelasticoplastic Media with Injuries]. Moscow, Russia: Fizmatlit Publishers, 2008 (In Russian).
- J. T. Boyle and J. Spence, Stress Analysis for Creep. London: Butterworths; 1980.
- V. P. Degtyarev, Plastichnost’ i polzuchest’ mashinostroitel’nykh konstruktsiy [Plasticity and Creep of Engineering Structures]. Moscow, Russia: Mashinostroenie Publisher; 1967 (In Ru s sian).
- D. A. Gokhfel’d and O. S. Sadakov, Plastichnost’ i Polzuchest’ Elementov Konstruktsiy Pri Povtornykh Nagruzheniyakh [Plasticity and Creep of Structural Elements under Repeated Loading]. Moscow, Russia: Mashinostroenie Publishers; 1984 (In Russian).
- A. M. Lokoshchenko, Polzuchest’ i Dlitel’naya Prochnost’ Metallov [Creep and Long Durability of Metals]. Moscow, Russia: Fizmatlit Publishers; 2016 (In Russian).
- N. N. Malinin, Prikladnaya Teoriya Plastichnosti i Polzuchesti [Applied Theory of Plasticity and Creep]. Moscow, Russia: Mashinostroenie Publishers; 1968 (In Russian).
- N. N. Malinin and G. M. Khadjinsky, “Theory of creep with anisotropic hardening,” Int. J. Mech. Sci., vol. 14, no. 4, pp. 235–246, 1972. DOI: 10.1016/0020-7403(72)90065-3.
- A. Miller, “Mathematical model for monotonous and cyclic variation of deformation and creep deformation,” ASME, Series D. Theoretical Foundations of Engineering Calculations, no. 2, pp. 1–20, 1976.
- N. Rabotnov Yu, Polzuchest’ Elementov Konstruktsiy [Creep of Structural Elements]. Moscow, Russia: Nauka Publishers; 1966 (In Russian).
- V. S. Bondar, Neuprugost’. Varianty Teorii [Inelasticity. Variants of the Theory]. Moscow, Russia: Fizmatlit Publishers; 2004 (In Russian).
- J. L. Chaboche, “Constitutive equation for cyclic plasticity and cyclic viscoplasticity,” Int. J. Plasticity, vol. 5, no. 3, pp. 247–302, 1989. DOI: 10.1016/0749-6419(89)90015-6.
- R. D. Krieg, J. C. Swearengen and R. W. Rohde, “A physically-based internal variable model for rate-dependent plasticity,” in Proceeding of the Conference “Inelastic Behavior of Pressure Vessel and Piping Components”, T. Y. Chang and E. Krempl , Eds. ASME; 1978, pp. 245–271
- I. A. Modin, A. V. Kochetkov, N. V. Leontev, I. A. Turigina and E. Y. Poverennov, “Numerical modeling of nonlinear dynamic and static compression of the metal mesh,” PNRPU Mech. Bull., vol. 4, pp. 106–113, 2019. DOI: 10.15593/perm.mech/2019.4.10.
- P. Perzyna, Osnovnye Voprosy Vyazkoplastichnosti [Fundamental Problems in Viscoplasticity]. Moscow, Russia: Mir Publishers; 1968 (In Russian).
- N. Shevchenko Yu and R. G. Terekhov, Fizicheskie uravneniya termovyazkoplastichnosti [Physical Equations of Thermoviscoplasticity]. Kiev, Ukraine: Naukova Dumka Publishers; 1982 (In Ru s sian).
- I. A. Volkov, L. A. Igumnov and G. Korotkikh Yu, Prikladnaya teoriya vyazkoplastichnosti [Applied Theory of Viscoplasticity]. Nizhni Novgorod, Russia: NNGU Publishers, 2015. (In Russian).
- V. V. Balandin, A. V. Kochetkov, S. V. Krylov and I. A. Modin, “Numerical and experimental study of the penetration of a package of woven metal grid by a steel ball,” J. Phys.: Conf. Ser., vol. 1214, no. 1, pp. 012004, 2019. DOI: 10.1088/1742-6596/1214/1/012004.
- I. A. Modin, A. V. Kochetkov and N. V. Leontiev, “Numerical simulation of quasistatic and dynamic compression of a granular layer,” AIP Conf. Proc., vol. 2116, p. 270003, 2019. DOI: 10.1063/1.5114277.
- Y. Ohashi, N. Ohno and M. Kawai, “Evaluation of creep constitutive equations for type 304 stainless steel under repeated multiaxial loading,” ASME J. Eng. Mater. Technol., vol. 104, pp. 159–164, 1982.
- D. A. Кazakov, S. A. Кapustin and G. Коrotkikh Yu, Modelirovanie processov deformirovaniya i razrusheniya materialov i konstrukcij [Modeling the processes of deformation and failure of materials and structures]. Izdatel’stvo Nizhegorodskogo Universiteta, N.Novgorod, Russia; 1994 (In Russian).
- I. A. Volkov, V., et al., “Model’ povrezhdennoj sredy dlya opisaniya dlitel’noj prochnosti konstrukcionnyh materialov (metallov i ih splavov) [Damaged medium model for describing the long-term strength of structural materials (metals and their alloys)],” PSP, vol. 79, no. 3, pp. 285–300, 2017 (In Russian). DOI: 10.32326/1814-9146-2017-79-3-285-300.
- A. V. Kochetkov, N. V. Leontev, I. A. Modin and A. O. Savikhin, Nizhny Novgorod, Russian Federation., “Study of the stress-strain and strength properties of the metal woven grids,” Tomsk State Univ. J. Math. Mech., vol. 52, no. 52, pp. 53–62, 2018. DOI: 10.17223/19988621/52/6.
- I. A. Volkov and L. A. Igumnov, Vvedenie v Kontinual’nuyu Mekhaniku Povrezhdennoj Sredy [Introduction to the Continuum Mechanics of Damaged Medium]. Moscow, Russia: Fizmatlit Publishers; 2017 (In Russian).
- I. A. Volkov, L. A. Igumnov, I. A. Modin and E. V. Boev, “A model of damaged media for describing a creep-induced damage accumulation process. 9th International Conference on Materials Structure and Micromechanics of Fracture,” Procedia Struct. Integrity, vol. 23, pp. 281–286, 2019. DOI: 10.1016/j.prostr.2020.01.100.