How to cite this paper
Tsvik, L., Zenkov, E., Elovenko, D & Malomige, D. (2025). Deformation of laboratory truncated disc samples with stress concentrators.Engineering Solid Mechanics, 13(1), 15-26.
Refrences
Bellett, D., Morel, F., Morel, A., & Lebrun, J. L. (2011). A biaxial fatigue specimen for uniaxial loading. Strain, 47(3), 227-240.
Berto, F., Campagnolo, A., & Lazzarin, P. (2015). Fatigue strength of severely notched specimens made of Ti–6Al–4V under multiaxial loading. Fatigue & Fracture of Engineering Materials & Structures, 38(5), 503-517.
Bondar, V.S., Temis, Yu.M., & Matvienko, Yu.G. (2024). Structural strength of materials. Resource life of structures with high parameters. St. Petersburg: Lanbook.
de Oliveira Miranda, A. C., Antunes, M. A., Alarcón, M. V. G., Meggiolaro, M. A., & de Castro, J. T. P. (2019). Use of the stress gradient factor to estimate fatigue stress concentration factors Kf. Engineering Fracture Mechanics, 206, 250-266.
Drucker, D. C., & Prager, W. (1952). Soil mechanics and plastic analysis or limit design. Q. Appl. Math, 10(2), 157-165.
GOST 1050-2013. (2014). Metal products from unalloyed structural high-quality and special steels. General technical conditions. Moscow: IKP Publishing house of standards.
GOST 1497-84. (2008). Metals. Tensile test methods. Moscow: IKP Publishing house of standards.
GOST 25.502-79. (1979). Calculation and strength testing in mechanical engineering. Methods of mechanical testing of metals. Fatigue test methods. Moscow: IKP Publishing house of standards.
GOST 25.504-82. (2004). Calculations and strength tests. Methods for calculating the characteristics of fatigue resistance. Moscow: IKP Publishing house of standards.
GOST 25.506-85. (1985). Calculations and strength tests. Methods of mechanical testing of metals. Determination of crack resistance characteristics (fracture toughness) under static loading. Moscow: IKP Publishing house of standards.
Kachanov, L. M. (2004). Fundamentals of the Theory of Plasticity. Courier Corporation.
Keller, I.E., & Petukhov, D.S. (2020). Criteria for strength and ductility. Perm: Perm national research polytechnic university.
Kogaev, V. P., Makhutov, N. A., & Gusenkov, A. P. (1985). Calculations of machine parts and structures for strength and durability. Mashinostroenie, Moscow.
Koutiri, I., Bellett, D., & Morel, F. (2018). The effect of mean stress and stress biaxiality in high‐cycle fatigue. Fatigue & Fracture of Engineering Materials & Structures, 41(2), 440-455.
Krotov, S.V., & Kononov, D.P. (2022). Analysis of the contact zone of the railway wheel and rail. News of the St. Petersburg University of Railway Transport, 19, 221-231.
Lebedev, A.A., & Kovalchuk, B.I. (2003). Mechanical properties of structural materials in a complex stress state. Kiev: In Yure.
Leevers, P. S., Radon, J. C., & Culver, L. E. (1976). Crack growth in plastic panels under biaxial stress. Polymer, 17(7), 627-632.
Lurie, A. I. (2012). Non-linear theory of elasticity. Elsevier.
Makhutov, N. A. (1981). Deformation criteria and structural elements strength calculation. Moscow: Mashinostroyeniye.
Makhutov, N.A. (2005). Structural strength, service life and technogenic safety. Novosibirsk: Science.
Matake, T. (1977). An explanation on fatigue limit under combined stress. Bulletin of JSME, 20(141), 257-263.
Mathiak, F., Krawietz, A., Nowack, H., & Trautmann, K. H. (1992). U.S. Patent No. 5,144,844. Washington, DC: U.S. Patent and Trademark Office.
Neuber, G. (1947). Stress concentration. Leningrad: Gostehizdat.
Oden, J. (1976). Finite elements in nonlinear continuum mechanics. M.: Mir.
Peterson, R.E. (1977). Stress concentration factors. Moscow: Mir.
Pisarenko, G. S., Yakovlev, A. P., & Matveev, V. V. (2008). Materials resistance handbook. Delta, Kiev, 816.
Rychkov, S.P. (2013). Modeling of structures in the Femap with NX Nastran environment. M.: DMK Press.
Sines, G., Waisman, J. L., & Dolan, T. J. (1959). Metal Fatigue [by] Thomas J. Dolan [and Others] Edited by George Sines and JL Waisman. McGraw-Hill.
Smirnov-Alyaev, G. A. (1968). Mechanical foundations of plastic processing of metals. Engineering methods. Mechanical engineering, Leningrad.
Tsvik, L. B. (1993). Strengthening holes and static strength of axially symmetric choke assemblies. Problems of machine building and machine reliability, 1, 58-65.
Tsvik, L. B., Pimshtein, P. G., & Borsuk, E. G. (1978). Experimental study of the stress-strain state of a multilayer cylinder with a monolithic insert. Strength of Materials, 10(4), 448-452.
Tsvik, L., & Zenkov, E. (2022). A comparative analysis of the stress-strain state of disc specimens in assessing the structural strength of materials. Engineering Solid Mechanics, 10(1), 25-34.
Tsvik, L.B. (2017). Specimens for mechanical testing of structural steels under cyclic loading. Transport infrastructure of the Siberian region, 2, 834-839.
Tsvik, L.B., Mukhomedzyanov, N.S., Zenkov, E.V., & Eremeev, V.K. (2017). Discrete modeling of deformations and stresses of wheels of railway cars based on their preliminary fragmentation. Transport infrastructure of the Siberian region, 2, 786–791.
Tsvik, L.B., Tarmaev, A.A., & Bocharov, I.S. (2019). Smoothness of the contours of rolling elements of bearings with cylindrical rollers and the resource of their cyclic operatio. Transport of the Urals, 3(62), 20-27.
Tsvik, L.B., Zenkov, E.V., Bocharov, I..S., & Elovenko, D.A. (2020). Patent R.F. No.2734276. Moscow: R.F. Patent and Trademark Office.
Vilimok, Y. A., Nazarov, K. A., & Evdokimov, A. K. (2013). Stress state of flat specimens under the uniaxial and biaxial tension. News of TSTU. Technical science, 11, 388-39.
Yosri, A., Zayed, A., Saad-Eldeen, S., & Leheta, H. (2021). Influence of stress concentration on fatigue life of corroded specimens under uniaxial cyclic loading. Alexandria Engineering Journal, 60(6), 5205-5216.
Zenkov, E. V., & Tsvik, L. B. (2015). Formation of divergent testing efforts and experimental evaluation of material strength under biaxial stretching. PNRPU Mechanics Bulletin, (4), 110-120.
Zenkov, E. V., & Tsvik, L. B. (2017). Refinement of the equations of the limiting state of the structure material taking into account the real type of their deformation. Systems. Methods. Technology, 2(34), 28-34.
Zenkov, E. V., & Tsvik, L. B. (2018). Accuracy improvement for combined static strength criterion for structures under complex loading. Materials Physics & Mechanics, 40(1), 124-132.
Zenkov, E. V., Aistov, I. P., & Vansovich, K. A. (2019, August). Modeling stress state stiffening of the nozzle zone of pressure vessel by finite element method. In AIP Conference Proceedings (Vol. 2141, No. 1). AIP Publishing.
Zenkov, E. V., Tsvik, L. B., & Pykhalov, A. A. (2011). Discrete modeling of the stress-strain state of flat-cylindrical specimens with grooves as stress concentrators. Bulletin of Irkutsk State Technical University, 7(54), 6-11.
Zenkov, E., & Tsvik, L. (2022, March). Modeling the Structural Strength of Materials on Disk Laboratory Specimens. In Materials Science Forum (Vol. 1052, pp. 104-109). Trans Tech Publications Ltd.
Berto, F., Campagnolo, A., & Lazzarin, P. (2015). Fatigue strength of severely notched specimens made of Ti–6Al–4V under multiaxial loading. Fatigue & Fracture of Engineering Materials & Structures, 38(5), 503-517.
Bondar, V.S., Temis, Yu.M., & Matvienko, Yu.G. (2024). Structural strength of materials. Resource life of structures with high parameters. St. Petersburg: Lanbook.
de Oliveira Miranda, A. C., Antunes, M. A., Alarcón, M. V. G., Meggiolaro, M. A., & de Castro, J. T. P. (2019). Use of the stress gradient factor to estimate fatigue stress concentration factors Kf. Engineering Fracture Mechanics, 206, 250-266.
Drucker, D. C., & Prager, W. (1952). Soil mechanics and plastic analysis or limit design. Q. Appl. Math, 10(2), 157-165.
GOST 1050-2013. (2014). Metal products from unalloyed structural high-quality and special steels. General technical conditions. Moscow: IKP Publishing house of standards.
GOST 1497-84. (2008). Metals. Tensile test methods. Moscow: IKP Publishing house of standards.
GOST 25.502-79. (1979). Calculation and strength testing in mechanical engineering. Methods of mechanical testing of metals. Fatigue test methods. Moscow: IKP Publishing house of standards.
GOST 25.504-82. (2004). Calculations and strength tests. Methods for calculating the characteristics of fatigue resistance. Moscow: IKP Publishing house of standards.
GOST 25.506-85. (1985). Calculations and strength tests. Methods of mechanical testing of metals. Determination of crack resistance characteristics (fracture toughness) under static loading. Moscow: IKP Publishing house of standards.
Kachanov, L. M. (2004). Fundamentals of the Theory of Plasticity. Courier Corporation.
Keller, I.E., & Petukhov, D.S. (2020). Criteria for strength and ductility. Perm: Perm national research polytechnic university.
Kogaev, V. P., Makhutov, N. A., & Gusenkov, A. P. (1985). Calculations of machine parts and structures for strength and durability. Mashinostroenie, Moscow.
Koutiri, I., Bellett, D., & Morel, F. (2018). The effect of mean stress and stress biaxiality in high‐cycle fatigue. Fatigue & Fracture of Engineering Materials & Structures, 41(2), 440-455.
Krotov, S.V., & Kononov, D.P. (2022). Analysis of the contact zone of the railway wheel and rail. News of the St. Petersburg University of Railway Transport, 19, 221-231.
Lebedev, A.A., & Kovalchuk, B.I. (2003). Mechanical properties of structural materials in a complex stress state. Kiev: In Yure.
Leevers, P. S., Radon, J. C., & Culver, L. E. (1976). Crack growth in plastic panels under biaxial stress. Polymer, 17(7), 627-632.
Lurie, A. I. (2012). Non-linear theory of elasticity. Elsevier.
Makhutov, N. A. (1981). Deformation criteria and structural elements strength calculation. Moscow: Mashinostroyeniye.
Makhutov, N.A. (2005). Structural strength, service life and technogenic safety. Novosibirsk: Science.
Matake, T. (1977). An explanation on fatigue limit under combined stress. Bulletin of JSME, 20(141), 257-263.
Mathiak, F., Krawietz, A., Nowack, H., & Trautmann, K. H. (1992). U.S. Patent No. 5,144,844. Washington, DC: U.S. Patent and Trademark Office.
Neuber, G. (1947). Stress concentration. Leningrad: Gostehizdat.
Oden, J. (1976). Finite elements in nonlinear continuum mechanics. M.: Mir.
Peterson, R.E. (1977). Stress concentration factors. Moscow: Mir.
Pisarenko, G. S., Yakovlev, A. P., & Matveev, V. V. (2008). Materials resistance handbook. Delta, Kiev, 816.
Rychkov, S.P. (2013). Modeling of structures in the Femap with NX Nastran environment. M.: DMK Press.
Sines, G., Waisman, J. L., & Dolan, T. J. (1959). Metal Fatigue [by] Thomas J. Dolan [and Others] Edited by George Sines and JL Waisman. McGraw-Hill.
Smirnov-Alyaev, G. A. (1968). Mechanical foundations of plastic processing of metals. Engineering methods. Mechanical engineering, Leningrad.
Tsvik, L. B. (1993). Strengthening holes and static strength of axially symmetric choke assemblies. Problems of machine building and machine reliability, 1, 58-65.
Tsvik, L. B., Pimshtein, P. G., & Borsuk, E. G. (1978). Experimental study of the stress-strain state of a multilayer cylinder with a monolithic insert. Strength of Materials, 10(4), 448-452.
Tsvik, L., & Zenkov, E. (2022). A comparative analysis of the stress-strain state of disc specimens in assessing the structural strength of materials. Engineering Solid Mechanics, 10(1), 25-34.
Tsvik, L.B. (2017). Specimens for mechanical testing of structural steels under cyclic loading. Transport infrastructure of the Siberian region, 2, 834-839.
Tsvik, L.B., Mukhomedzyanov, N.S., Zenkov, E.V., & Eremeev, V.K. (2017). Discrete modeling of deformations and stresses of wheels of railway cars based on their preliminary fragmentation. Transport infrastructure of the Siberian region, 2, 786–791.
Tsvik, L.B., Tarmaev, A.A., & Bocharov, I.S. (2019). Smoothness of the contours of rolling elements of bearings with cylindrical rollers and the resource of their cyclic operatio. Transport of the Urals, 3(62), 20-27.
Tsvik, L.B., Zenkov, E.V., Bocharov, I..S., & Elovenko, D.A. (2020). Patent R.F. No.2734276. Moscow: R.F. Patent and Trademark Office.
Vilimok, Y. A., Nazarov, K. A., & Evdokimov, A. K. (2013). Stress state of flat specimens under the uniaxial and biaxial tension. News of TSTU. Technical science, 11, 388-39.
Yosri, A., Zayed, A., Saad-Eldeen, S., & Leheta, H. (2021). Influence of stress concentration on fatigue life of corroded specimens under uniaxial cyclic loading. Alexandria Engineering Journal, 60(6), 5205-5216.
Zenkov, E. V., & Tsvik, L. B. (2015). Formation of divergent testing efforts and experimental evaluation of material strength under biaxial stretching. PNRPU Mechanics Bulletin, (4), 110-120.
Zenkov, E. V., & Tsvik, L. B. (2017). Refinement of the equations of the limiting state of the structure material taking into account the real type of their deformation. Systems. Methods. Technology, 2(34), 28-34.
Zenkov, E. V., & Tsvik, L. B. (2018). Accuracy improvement for combined static strength criterion for structures under complex loading. Materials Physics & Mechanics, 40(1), 124-132.
Zenkov, E. V., Aistov, I. P., & Vansovich, K. A. (2019, August). Modeling stress state stiffening of the nozzle zone of pressure vessel by finite element method. In AIP Conference Proceedings (Vol. 2141, No. 1). AIP Publishing.
Zenkov, E. V., Tsvik, L. B., & Pykhalov, A. A. (2011). Discrete modeling of the stress-strain state of flat-cylindrical specimens with grooves as stress concentrators. Bulletin of Irkutsk State Technical University, 7(54), 6-11.
Zenkov, E., & Tsvik, L. (2022, March). Modeling the Structural Strength of Materials on Disk Laboratory Specimens. In Materials Science Forum (Vol. 1052, pp. 104-109). Trans Tech Publications Ltd.