employee from 01.01.2007 until now
Volzhsky, Volgograd, Russian Federation
Volzhskiy, Volgograd, Russian Federation
Volzhsky, Volgograd, Russian Federation
Studies have been carried out when grinding alloys based on titanium, vanadium, chromium, iron, cobalt and nickel. According to the condition of the neat surface, the alloys are divided into groups. The regularities of changes in the roughness parameters of Ra and Rsm are investigated. The parameter of the average density of the peaks of the grains forming the elements of the surface roughness profile has been introduced, the relationship of the introduced parameter with Ra is shown. It is established that when grinding all alloys, the treated surface is impregnated by the wear products of the abrasive tool. Electronic photographs of objects are given. The possible sizes of embedded crystals are determined.
metal alloys, grinding, CBN, morphology, roughness, impregnation
1. Properties of elements, handbook, edited by M.E. Dritsa, M.: Metallurgy, 1985, 672 p.
2. Nosenko, V.A., Nosenko, S.V., Puzirkova, V.E. Grind-ing of Titanium Alloys // Key Engineering Materials, 2021, Vol. 887, P. 287-293.
3. Nosenko, V.A., Fetisov, A.V., Nosenko, S.V., Puzyrkova, V.E. Morphology and Chemical Composition of Silicon Carbide Surface in Interaction with Titanium Alloy under Micro-Scratching Conditions // MATEC Web of Conferences, 2020, Vol. 329, Article number 02010.
4. Zhao, T., Shi, Y., Sampsa, L., Zhou, J. Investigation of the Effect of Grinding Parameters on Surface Quality in Grinding of TC4 Titanium Alloy // Procedia Manufacturing, 2017, Vol. 11, P. 2131-2138.
5. Xu, X., Yu, Y., Huang, H. Mechanisms of abrasive wear in the grinding of titanium (TC4) and nickel (K417) alloys // Wear, 2003, Vol. 255, no. 7-12, P. 1421-1426.
6. Nosenko, V.A., Feyisov, A.V., Puzyrkova, V.Ye. Morphology and chemical composition of silicon carbide surfaces interacting with iron, cobalt, and nickel in microscratching // Solid State Phenomena, 2018, Vol. 284, P. 363-368.
7. Nosenko, V.A., Fetisov, A.V., Kuznetsov, S.P. Transfer of Cubic Boron Nitride Grinding Wheel Wear Products to the Nickel Alloy Surface // MATEC Web of Conferences, 2020, Vol. 329 (4), Article number 03050.
8. Effects of abrasive material and hardness of grinding wheel on rail grinding behaviors. / R.X. Wang, K. Zhou, J.Y. Yang, H. Ding, W. Wang, J. Guo, Q.Y. Liu // Wear, 2020, Vol. 454 455, Article number 203332.
9. Nosov, N.V. Investigation of impact of cutting oils on formation of surface defects during grinding // IOP Conference Series: Materials Science and Engineering, 2020, Vol. 709, Article number 022104.
10. Miao, Q., Ding, W., Gu, Y., Xu, J. Comparative inves-tigation on wear behavior of brown alumina and microcrystal-line alumina abrasive wheels during creep feed grinding of different nickel-based superalloys // Wear, 2019, Vol. 426-427, P. 1624-1634.
11. Nosenko, V.A., Larionov, N.F., Egorov, N.I., Volkov, M.P. The selection characteristics of the abrasive tool and the coolant for deep grinding // Vestnik mashinostroeniya, 1989, no. 5, pp. 17-21.
12. Spravochnik tehnologa / pod obsch. red. A.G. Suslova. M.: Innovacionnoe mashinostroenie, 2019. - 800 s.
13. Nosenko, V.A. Belukhin, R.A., Fetisov, A.V., Morozova, L.K. Test complex based on precision profile grinding machine with CNC CHEVALIER model SmartB1224 // Izvestia VolgogSTU. Ser. Progressivnie technologii v mashinostroenii, Volgograd, 2016, no. 5 (184), pp. 35 39.
14. Macerol, N., Franca, L.F.P., Krajnik, P. Effect of the grit shape on the performance of vitrified-bonded CBN grind-ing wheel // Journal of Materials Processing Technology. - 2020. - Vol. 277. - Article number 116453.
15. Technologist's handbook / under general editorship by A.D. Suslov, M.: Innovatsionnoye mashinostroenie, 2019, 800 p.