Abstract
The surface of the WC/Co carbide tool was modified by an electron beam with the magnetron sputtering of Nb + Hf + Ti alloy to obtain a gradient interlayer before hardfacing with (Ti + Al)N. The results of investigations of the composite using a scanning electron microscope equipped with a device for X-ray energy dispersion spectroscopy are given. The results of the comparative mechanical tests show reduced wear rate.
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Grigor’ev, S.N., Metel’, A.S., and Fedorov, S.V., Modification of the Structure and Properties of High-Speed Steel by Combined Vacuum-Plasma Treatment, Metal Sci. Heat Treat., 2012, vol. 54, nos. 1–2, pp. 8–12.
Andreev, A.A., Sablev, L.P., and Grigor’ev, S.N., Vakuumno-dugovye pokrytiya (Vacuum-Arc Coatings), Kharkov: NNTs KhFTI, 2010.
Fadeev, V.S., Scientific Foundations of Development and Production of Layered Composition Materials on Solid Alloy and Oxide Ceramics Surface for Increasing of Availability of Cutting Tool, Doctor Sci. (Tech.) Dissertation, Khabarovsk, 2005.
Paladin, N.M., Belov, E.I., Rusin, E.N., and Guzanov, D.S., RF Patent 2044107, 1995.
Poleshchenko, K.N., Voloshina, I.G., Povoroznyuk, S.N., Remnev, G.E., and Grinberg, P.B., RF Patent 2167216, Byull. Uzobr., no. 14, 2001.
Ivanov, Yu.F., Kolubaeva, Yu.A., and Ovcharenko, V.E., Mechanisms of Hardening of TiC-NiCrAl Solid Alloy Surface Layer upon Electron-Beam Radiation, Izv. Tomsk. Politekhn. Univ., 2008, vol. 313, no. 3, pp. 93–95.
Rotshtein, V.P., Proskurovsky, D.I., Ozur, G.E., Ivanov, Yu.F., and Markov, A.B., Surface Modification and Alloying of Metallic Materials with Low-Energy High-Current Electron Beams, Surface Coatings Tech., 2004, nos. 180–181, pp. 377–381.
Proskurovsky, I., Rotshtein, V.P., Ozur, G.E., Ivanov, Yu.F., and Markov, A.B., Physical Foundations for Surface Treatment of Materials with Low Energy, High Current Electron Beams, Surface Coatings Tech., 2000, vol. 125, nos. 1–3, pp. 49–56.
Ozur, G.E., Popov, S.A., and Fedushchak, V.F., Formation of Narrow Low-Energy High-Intensity Electron Beams, Russ. J. Appl. Phys., 2008, vol. 53, no. 7, pp. 919–926.
Solonenko, O.P. and Golovin, A.A., Computer Simulation of Heat Transfer and Phase State under High Energy Flux Impact on Solid Body Surface, Proc. ITSC-05, Bazel, 2005, pp. 6–10.
Ivanov, Y.F., Rotshtein, V.P., Proskurovsky, D.I., Orlov, P.V., Polestchenko, K.N., Ozur, G.E., and Goncharenko, I.M., Pulsed Electron-Beam Treatment of WC-TiC-Co Hard-Alloy Cutting Tools: Wear Resistance and Microstructure Evolution, Surface Coatings Tech., 2000, vol. 125, nos. 1–3, pp. 251–256.
Baohai, Yu., Ovcharenko, V.E., Psakhie, S.G., and Lapshin, O.V., Electron-Beam Treatment of Tungsten-Free TiC/NiCr. Cermet II: Structural Transformation in the Subsurface Layer, J. Mater. Sci. Tech., 2006, vol. 22, no. 4, pp. 511–513.
Ovcharenko, V.E. and Ivanov, Yu.F., Regularities of Heating, Nanostructure Modification and Hardening of Metal-Ceramic Alloy Surface Layer upon Pulsed Electron-Beam Radiation, Izv. Tomsk. Politekhn. Univ., 2008, vol. 313, no. 3, pp. 88–92.
Pischasov, N.I. and Nikolaev, A.V., Modification of Structure and Properties of Solid Alloys in WC-Co System by Strong-Current Beams of Charged Particles, Vestn. Omsk. Univ., 1996, no. 2, pp. 39–43.
Vakhnii, E.V., Simulation of Mass Transfer in Metal Materials upon Ionic Beam Radiation, Candidate Sci. (Tech.) Dissertation, Omsk, 2007.
Markov, A.B., Mikov, A.V., Ozur, G.E., and Padei, A.G., A RITM-SP Facility for the Surface Alloying, Instrum. Exp. Tech., 2011, vol. 54, no. 6, pp. 862–866.
Grigoriev, S. and Metel, A., Plasma and Beam-Assisted Deposition Methods. Nanostructured Thin Films and Nanodispersion Strengthened Coatings, NATO Science Series, Series II: Mathematics, Physics and Chemistry, 2004, vol. 155, pp. 147–154.
Sobol’, O.V., Andreev, A.A., Grigor’ev, S.N., Volosova, M.A., and Gorban’, V.F., Vacuum-Arc Multilayer Nanostructured TiN/Ti Coatings: Structure, Stress State, Properties, Metal Sci. Heat Treat., 2012, vol. 54, nos. 1–2, pp. 28–33.
Grigor’ev, S.N., Kurando, E.A., Filatov, P.N., and Temnikov, V.A., Peculiarities of Technological Process and Equipment for Combined Vacuum-Plasma Strengthening of Broaching Tool, Uprochnyayushchie Tekhnologii i Pokrytiya, 2007, no. 12, pp. 44–48.
Grigor’ev, S.N. and Kutergina, T.V., Estimation of Efficiency of Coating Laying Technology on Cutting Tool, Vestnik Mashinostroeniya, 2005, no. 2, pp. 68–72.
Turin, V.D., Grigor’ev, S.N., and Sinopal’nikov, V.A., Peculiarities of Contact Effects on the Front Surface of Tool with Wear-Resistant Coating at Interrupted Cutting, Uprochnyayushchie Tekhnologii i Pokrytiya, 2007, no. 7, pp. 45–51.
Uglov, V.V., Koval’, N.N., Kuleshov, A.K., Ivanov, Yu.F., Teresov, A.D., and Soldatenko, E.A., Structure-Phase Transformation in Surface Layers of Hard Alloy as a Result of Action of High-Current Electron Beams, J. Surf. Invest.: X-ray, Synchr. Neutr. Tech., 2011, vol. 5, no. 2, pp. 350–357.
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Original Russian Text © S.N. Grigor’ev, S.V. Fedorov, M.D. Pavlov, A.A. Okun’kova, Ye Min So, 2013, published in Trenie i Iznos, 2013, Vol. 34, No. 1, pp. 21–27.
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Grigor’ev, S.N., Fedorov, S.V., Pavlov, M.D. et al. Complex surface modification of carbide tool by Nb + Hf + Ti alloying followed by hardfacing (Ti + Al)N. J. Frict. Wear 34, 14–18 (2013). https://doi.org/10.3103/S1068366613010054
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DOI: https://doi.org/10.3103/S1068366613010054