We determine the principal regularities of the stressed state of the surface layer of Al2O3–TiC ground ceramics under the action of combined loads. It is discovered that the force load compensates the thermal elastic strains but, at the same time, complicates the stressed state as compared with the action of loads of the same type. We clarify the role of combinations of structural elements, which form the surface of Al2O3–TiC ceramics, in the formation of unfavorable microstructural stress concentrators.
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V. V. Kuzin, S. N. Grigor’ev, and M. A. Volosova, “Computer simulation of the stressed state of the surface layer of ground Al2O3–TiC ceramics. Force analysis,” Novye Ogreupory, No. 7, 67 – 71 (2020).
V. V. Kuzin, S. N. Grigor’ev, and M. A. Volosova, “Computational simulation of the stressed state of the surface layer of ground Al2O3–TiC ceramics. Thermal analysis,” Novye Ogreupory, No. 8, 53 – 58 (2020).
M. Cheng, H. Liu, B. Zhao, et al., “Mechanical properties of two types of Al2O3/TiC ceramic cutting tool material at room and elevated temperatures,” Ceram. Int., 43(16), 13869 – 13874 (2017).
V. V. Kuzin, S. N. Grigoriev, and M. A. Volosova, “The role of the therma1 factor in the wear mechanism of ceramic tools: Part 1. Macrolevel,” J. Friction Wear, 35(6), 505 – 510 (2014).
V. V. Kuzin, S. N. Grigoriev, and M. A. Volosova, “The role of the therma1 factor in the wear mechanism of ceramic tools. Part 2: Microlevel,” J. Friction Wear, 36(1), 40 – 44 (2015).
J. Zhao, X. Yuan, and Y. Zhou, “Cutting performance and failure mechanisms of an Al2O3/WC/TiC micro-nano-composite ceramic tool,” Int. J. Refr. Met. Hard Mater., 28(3), 330 – 337 (2010).
S. N. Grigoriev and V. V. Kuzin, “Prospects for tools with ceramic cutting plates in modern metal working,” Glass Ceram., 68(7/8), 253 – 257 (2011).
V. V. Kuzin, S. N. Grigor’ev, and V. N. Ermolin, “Stress inhomogeneity in a ceramic surface layer under action of an external load. Part 4. Combined effect of force and thermal loads,” Refract. Ind. Ceram., 55(1), 40 – 44 (2014).
M. A. Volosova, S. N. Grigor’ev, and V. V. Kuzin, “Effect of titanium nitride coating on stress structural inhomogeneity in oxide-carbide ceramic. Part 5. A combined load operates,” Refract. Ind. Ceram., 56(2), 197 – 200 (2015).
A. S. Ovchinskii, Fracture Processes in Composites. Computers Simulation of Micro- and Macromechanisms [in Russian], Nauka, Moscow (1988).
V. V. Kuzin, S. N. Grigor’ev, and M. A. Volosova, “Changes in ceramic object surface layer structure during operation. Part 1,” Refract. Ind. Ceram., 61(1), 94 – 99 (2020).
V. V. Kuzin, S. N. Grigor’ev, and M. A. Volosova, “Foundations of computer engineering of the surface layers of ground ceramics,” Novye Ogreupory, No. 6, 64 – 69 (2020).
V. Kuzin and S. Grigoriev, “Method for the investigation of the stress-strain state of surface layer of machine elements from a sintered nonuniform material,” Appl. Mech. Mater., 486, 32 – 35 (2014).
The present work was financially supported within the framework of the State Task of the Ministry of Science and Higher Education of Russian Federation, Project No. 0707-2020-0025.
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Translated from Novye Ogneupory, No. 9. pp. 67 – 72, September, 2020.
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Kuzin, V.V., Grigor’ev, S.N. & Volosova, M.A. Computer Engineering of the Surface Layer of Ground Al2O3–TiC Ceramics. Combined Analysis. Refract Ind Ceram 61, 547–552 (2021). https://doi.org/10.1007/s11148-021-00519-2
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DOI: https://doi.org/10.1007/s11148-021-00519-2