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HomeSolid State PhenomenaSolid State Phenomena Vol. 265Multi-Component Coatings Formation on Polycathode...

Multi-Component Coatings Formation on Polycathode Magnetron Sputtering Systems

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Abstract:

The results of experiments aimed at obtaining multi-component coatings, having a wider range of properties compared to single-component coatings, are provided. The process of formation of coating based on multi-component alloy Co (18...20%)-Cr (5...7%)-Al (0.3...0.4%)-Y(0.2...0.5) was studied. The chemical composition and thickness of the coating as well as the state of the transition layer were also studied. The results of electron probing and X-ray fluorescence microanalysis of obtained coatings are provided. This paper also demonstrates that the properties of surface microrelief are determined by the conditions of coating formation; that each sample of coating has similar sets of chemical elements, that their concentration depends on the precipitation conditions, chemical elements are equally distributed along the thickness of samples, and the diffusion zone of coating materials and substrate is almost non-existent. The low content of substrate material was found in obtained coatings. As the coating thickness increased, the content of substrate material decreased sharply.

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Materials Engineering and Technologies for Production and Processing III

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Periodical:

Solid State Phenomena (Volume 265)

Pages:

166-170

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.265.166

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Online since:

September 2017

Authors:

V.V. Kolesnik*, Yu.K. Rubanov, Yu.E. Tokach

Keywords:

Magnetron System, Multi-Component Coating, Substrate, Target Cathode, Transition Layer

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© 2017 Trans Tech Publications Ltd. All Rights Reserved

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[1] P.T. Kolomytsev, Heat-resistant diffusion coatings, Metallurgiya, Moscow, (1979).

[2] D. Loktev, Y. Yarmashkin, Methods and equipment for application of wearproof coatings, Nanoindustriya. 4 (2007) 18-24.

[3] A.A. Achimov, I.M. Tolmachev, S. Yu. Udovichenko, Study of heat-resistant diffusion coatings of gas-turbine engine blades made of heat-resistant nickel alloy, Tyumen State University newsletter. 7 (2014) 105-111.

[4] S.A. Muboyadzhan, S.A. Budinovsky, V.V. Terekhova, Ion-plasma aluminide diffusion coatings of gas-turbine engine blades, Science of metals and their heat treatment. 1 (2003) 14-21.

[5] A.N. Ramazanov, P.V. Beglikcheyev. Study of vacuum ion-plasma coating obtained using electric arc spraying of multi-component cathode containing TI-AL-ZR-MO, Machine-building, material science and heat treatment of metals, 10 (2008) 108-112.

[6] Yu.P. Tarasenko, Physical, mechanical and chemical properties of ion-plasma coatings of titanium nitride obtained at different partial pressure values of reaction gas, Physics and chemistry of materials processing. 4 (2006) 42–45.

[7] A.G. Illarionov, A.A. Popov, Technological and operating properties of titanium alloys. Izdatelstvo Uralskogo Universiteta, Yekaterinburg, (2014).

[8] V.M. Beresnev, M. Yu. Kopeikina, S.A. Klimenko, Multicomponent and multilayer vacuum-arc coating of cutting tools, Problems of atomic science and technology. 1 (2008) 152-158.

[9] V. Beletsky, V. Kireev, S. Knyazev, D. Chelapkin, Application of vacuum plasma technologies in electronics, Modern electronics. 2 (2002) 12-18.

[10] Y.V. Berlin, L.A. Seydman, Ion-plasma processes in thin layer technology, Tekhnosfera, (2006).

[11] V.S. Mukhin, R.M. Kireyev, S.R. Shekhtman, Technology of application of Ti-TiN vacuum ion-plasma nanostructured coatings, USATU newsletter, Ufa, 15 (2011) 212-214.

[12] R.M. Kireev, Synthesis of intermetallic coatings of Ti-Al systems by condensation of plasma fluxes generated by vacuum arc, USATU newsletter. 1 (2008) 96-99.

[13] V.V. Budilov, V.S. Mukhin, S.R. Shekhtman, Nanotechnologies of surface treatment based on vacuum ion-plasma coating, Basics of physics and technological solutions, Nauka, Moscow, (1991).

[14] Y.N. Kablov, S.A. Muboyadzhan, S.A. Budinovsky, A.N. Lutsenko, Ion-plasma protection coatings for gas-turbine engine blades.

[15] Kostyuk G.I., Xing Yuandong, Kurinny A.N. Methods of choice of layers and sublayers in multi-component coatings depending on temperature conditions. Scientific, technological and civil journal of Presidium of Ukrainian Academy of Engineering, 3(30) (2006).

[16] Information on http: /www. semiteq. ru.

[17] Dennis R. Hollars, Martin P. Rosenblum, Carl T. Petersen, U.S. Patent 6, 488, 824. (2002).

[18] Frank Papa, Roel Tietema, U.S. Patent 20130056348. (2013).

[19] V.Y. Beletsky, Patent of the Russian Federation No. 2490369 (2013).

[20] D.D. Slivakov, V.S. Mitin, Patent of the Russian Federation No. 2379378 (2011).

[21] Japanese Patent Application JP 61-54112, С23С 14/36, 1986. Method of application of coatings in devices with a magnetron cathode, placed on the disc, a mosaic target, and flat anode for fixing substrates.

[22] M.I. Guseva, M.V. Atamanov, Yu.V. Martynenko, Yu.V. Moskovkin, V.S. Mitin, A.V. Mitin, S.A. Shiryayev, Patent of the Russian Federation No. 2210620 (2005).

[23] V.P. Kolesnik, V.V. Kolesnik, Yu.K. Rubanov, Ye.I. Yevtushenko, D.S. Prokhorenkov, Patent of the Russian Federation No. 159075 (2015).

[24] V.V. Kolesnik, V.G. Padalka, I.V. Lunyov, Study of generation of ion fluxes in ionic magnetron, Aviation and space technology, Kharkiv Aviation Institute, Kharkiv, (1999) 58-61.

[25] G.V. Samsonov, A.P. Epik, Heat-resistant coatings, Metallurgiya, Moscow, (1973).