ISSN 0021-3454 (print version)
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vol 67 / February, 2024
Article

DOI 10.17586/0021-3454-2018-61-2-95-99

UDC 620.179

FEATURES OF DESTRUCTION OF MATERIAL SURFACE, STRENGTHENED BY PARTICLES

Y. A. Fadin
Institute of Problems of Mechanical Engineering, Russian Academy of Sciences, St. Petersburg; Head of Laboratory


S. N. Perevislov
St. Petersburg State Technological Institute (Technical University), Department of Chemical Technology of Refractory Nonmetallic and Silicate Materials; Doctorant


D. P. Danilovich
St. Petersburg State Technological Institute (Technical University), Department of Chemical Technology of Refractory Non-metallic and Silicate Materials; Senior Lecturer


M. A. Markov
St. Petersburg State Technological Institute (Technical University), Department of Chemical Technology of Silicate Materials;; Post-Graduate Student


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Abstract. The process of wear of ceramic composites with polycrystalline matrix of silicon carbide with dry friction in tool steel is considered. Fragile particles of various sizes are used as fillers of the composite matrix. Wear as a process of multiple surface destruction occurs in the field of mechanical stresses created by the interaction of roughnesses of contacting bodies, each roughness plays the role of an indenter, as in the case of "Hertz contact". Variation of the load makes it possible to regulate both the depth of the layer of the maximum tangential stresses and the numerical value of the stresses. The wear resistance of composites hardened by particles of 1—1000 μm in size is shown to depend on the ratio of the depth of the layer of maximal tangential stresses and the size of the hardening particles.
Keywords: surface, wear, particle size, SiC ceramics

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