10.22190/FUME190330023K

161

168

The article probes into a relationship of the shear strain intensity and the shear strain rate in the surface layer and the sliding velocity of a spherical indentor and its loading repetition factor. It brings forward an experimental procedure to evaluate the shear strain intensity and rate by analyzing the geometrical parameters of the bulge of plastically edged metal and the thickness of the shifted layer relative to different sliding velocities and feed rates.

Surface Layer, Nanostructuring Burnishing, Spherical Indentor, Severe Plastic Shear Deformation, Sliding Velocity, Loading Repetition Factor

Papsev, D.D., 1978, Finishing & hardening with cold working, Mechanical Engineering, pp 10–15.

Korzynski, M., Pacana, A., 2010, Centreless burnishing and influence of its parameters on machining effects, Journal of Materials Processing Technology, 210(9), pp. 1217–1223.

Maximov, J.T., Anchev, A.P., Duncheva, G.V., Ganev, N., Selimov, K.F., 2016, Influence of the process parameters on the surface roughness, micro-hardness, and residual stresses in the slide burnishing of high-strength aluminium alloys, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 39(8), pp. 3067–3078.

Hamadache, H., Laouar, L., Zeghib, N.E., Chaoui, K., 2006 Characteristics of Rb40steel superficial layer under ball and roller burnishing, Journal of Materials Processing Technology, 180(1), pp. 130–136.

Shiou, F.J., Cheng, C.H., 2008, Ultra-precision surface finish of NAK80 mould tool steel using sequential ball burnishing and ball polishing processes, Journal of Materials Processing Technology, 201(1–3), pp. 554–559.

Shiou, F.J., Chuang, C.H., 2010, Precision surface finish of the mold steel PDS5 using an innovative ball burnishing tool embedded with a loading cell, Precision Engineering, 34, pp. 76–84.

Przybylski, W., 1987, Burnishing Technology, Science Publishing Home, Warszawa (in Polish).

Kuznetsov, V.P., Smolin, I.Yu., Dmitriev, A.I., Konovalov, D.A., Makarov, A.V., Kiryakov, A.E., Yurovskikh, A.S., 2013, Finite element simulation of nanostructuring burnishing, Physical Mesomechanics, 16(1), pp. 62–72.

Kuznetsov, V.P., Makarov, A.V., Psakhie, S.G., Savrai, R.A., Malygina, I.Yu., Davydova, N.A., 2014, Tribological aspects in Nanostructuring burnishing of structural steels, Physical Mesomechanics, 17(4), pp. 250–264.

Selliger, G., Stephan, J., Lange, S., 2000, Hydroadhesive gripping by using Peltier effect, ASME International Mechanical Engineering Congress & Exposition (IMECE), pp. 3–8.

Kuznetsov, V.P., Tarasov, S.Yu., Dmitriev, A.I., 2015, Nanostructuring burnishing and subsurface shear instability, Journal of Materials Processing Technology, 217, pp. 327–335.

Dmitriev, A.I., Kuznetsov, V.P., Nikonov, A.Yu., Smolin, I.Yu., 2014, Modelling of nanostructuring burnishing on different scales, Physical Mesomechanics, 17(4), pp. 6–13.

Kuznetsov, V.P., Tarasov, S.Yu., Dmitriev, A.I., 2014, Identification of conditions for nanostructuring burnishing and subsurface shear instability, International Conference on Physical Mesomechanics of Multilevel Systems 2014, 3–5 September 2014, Tomsk, Russia – AIP Conf.Proc, 1623, pp. 331–334.

Kuznetsov, V.P., Smolin, I.Yu., Dmitriev, A.I., Tarasov, S.Yu., Gorgots,. V.G., 2016, Toward control of subsurface strain accumulation in nanostructuring burnishing on thermostrengthened steel, Surface and Coatings Technology, 285, pp. 171–178.

Kuznetsov, V.P., Skorobogatov, A.S., Gorgots, V.G., Yurovskikh, A.S., 2016, The Analysis of speed increase perspectives of nanostructuring burnishing with heat removal from the tool, IOP Conf. Series: Materials Science and Engineering, 124, 012127.

Kuznetsov, V.P., Skorobogatov, A.S., Gorgots, V.G., 2015, Mathematical model of thermal physics of the dual-cycle cooling system of the tool for pieces nanostructuring burnishing, Applied Mechanics and Materials, 770, pp. 449–455.

Zhao, J., Xia, W., Li, N., Li, F., 2014, A gradient nano/micro-structured surface layer on copper induced by severe plasticity roller burnishing, Transactions of Nonferrous Metals Society of China, 24, pp. 441–448.

Roland, T., Retraint, D., Lu, K., Lu, J., 2006, Fatigue life improvement through surface nanostructuring of stainless steel by means of surface mechanical attriction treatment, Scripta Materiala, 54, pp. 1949–1954.

Huang, B., Kayank, Y., sun, Y., Jawahir, I.S., 2015, Surface layer modification by cryogenic burnishing of al 7075-t7451 alloy and validation woth fem-based burnishing model, Procedia CIRP, 31, pp. 1–6.

Azushima, A., Kopp, R., Korhonen, A., Yang, D.Y., Micari, F., Lahoti, G.D., Groche, P., Yanagimoto, J., Tsuji, N., Rosochowski, A., Yanagida, A., 2008, Severe plastic deformation (SPD) processes for metals, CIRP Annals – Manufacturing Technology, 57, pp. 716–735.

Gleiter, H., 1991, Nanocrystalline Materials, Advanced Structural and Functional Materials, pp. 1–37.

Heilmann, I., Clark, W.A., Rigney, D.A., 1983, Orientation determination of subsurface cells generated by sliding, Acta Metallurgica, 31(8), pp. 1293–1305.

Segal, V.M., 2011, Fundamentals and Engineering of Severe Plastic Deformation, Nova Science Pub Inc, 542 p.

Zhao, X., Yang, X., Jing, T., 2012, Effect of initial microstructure on warm deformation behavior of 45 steel, Journal of Iron and Steel Research International, 19, pp. 75–78.

Farghadany, E., Zarei-Hanzaki, A., Abedi, H.R., Dietrich, D., Lampke, T., 2014, The strain accommodation in Ti–28Nb–12Ta–5Zr alloy during warm deformation, Materials Science and Engineering: A, 592, pp. 57–63.

Valiev, R., Islamgaliev, R., Alexandrov, I., 2000, Bulk nanostructured materials from severe plastic deformation, Progress in Materials Science, 45, pp. 103–189.