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Название Analysis of friction surfaces of structural steels after their hardening by methods based on electrical technologies
Автор A. A. Malikov, E. V. Markova, N. B. Fomicheva, O. V. Chechuga
Информация об авторе

Tula State University (Tula, Russia):

A. A. Malikov, Dr. Eng., Prof., Dept. “Machinebuilding Technology”
E. V. Markova, Cand. Eng., Associate Prof., Dept. “Machinebuilding Technology”, e-mail: marta06@yandex.ru
N. B. Fomicheva, Cand. Eng., Associate Prof., Dept. “Metal Physics and Material Science”
O. V. Chechuga, Cand. Eng., Associate Prof., Dept. “Machinebuilding Technology”


This paper presents the results of studies of friction surfaces and the microstructure of the surface layer, after hardening by electrotechnologies to select the method of surface treatment of steel, providing a high hardening effect. The characteristic areas of the surface relief of structural steels hardened by different methods 30ХГСН2А and 30ХРA after wear under sliding friction without lubricant were analyzed. It is found that different types of hardening on the basis of electrical technologies, including electroerosion and electron beam treatment create a different hardening effect in steels and are characterized by different friction surfaces. Electroerosion treatment in the mode of productive removal is characterized by the greatest hardening effect for the studied steel grades. The surface after electron-beam hardening is characterized at the microscopic level by the appearance of contrasting friction tracks, as well as fragmentary reliefs with noticeable damage. The microstructural analysis showed the influence of the type of treatment on the structural characteristics of the material. During electroerosion treatment, a characteristic white layer with increased microhardness is formed on the surface. The combination of hardening on the basis of the scheme of electrical discharge machining reduces the microhardness of both steels and reduces the thickness of the white layer. Electron beam treatment generates three-zone structure as 30ХРA for steel and for steel 30ХГСН2А.

Ключевые слова Electroerosion treatment, electron beam treatment, microhardness, friction surface, electrotechnology, wear resistance, surface relief
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