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HomeKey Engineering MaterialsKey Engineering Materials Vol. 839Structural and Phase Changes in Tin Coatings...

Structural and Phase Changes in Tin Coatings Subjected to Thermal Treatment

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Abstract:

This work presents the experimental results of the study of the effect of heat treatment on the structural-phase state of TiN coatings on the surface of 67KH5B alloy. It is determined that thermal annealing leads to structural phase transformations at the interface between the coating and the substrate. It was established that after annealing at Т=800 ^°С, due to the redistribution of the coating elements and the substrate, a modified coating is formed consisting of the TiN, Ti2N and NiTi phases.

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Periodical:

Key Engineering Materials (Volume 839)

Pages:

131-136

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.839.131

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Online since:

April 2020

Authors:

Aidar Kenesbekov*, Bauyrzhan Rakhadilov, Rauan Kozhanova, Olga Stepanova

Keywords:

Coating, Hardness, Heat Treatment, Structure, Titanium Nitride

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© 2020 Trans Tech Publications Ltd. All Rights Reserved

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[1] Vakuumnyye dugi: Per. s angl. / Pod red. Dzh. Lafferti. – M.: Mir, 1982, p.432.

[2] A.A. Andreyev, L.P. Sablev, V.M. Shulayev, S.N. Grigor'yev., Vakuumno-dugovyye ustroystva i pokrytiya, Kharkov, 2005, p.236.

[3] V.A. Barvinok, V.I. Bogdanovich.Fizicheskiye osnovy i matematicheskoye modelirovaniye protsessov vakuumnogo ionno-plazmennogo napyleniya, – M.: Mashinostroyeniye, 1999, p.309.

[4] I.A. Kurzina, E.V. Kozlov, Yu.P. Sharkeev, S.V. Fortuna, N.A. Koneva, I.A. Bojko, Nanocrystalline intermetallic and nitride structures formed during ion-beam exposure, (2008) 324.

[5] B.K. Rakhadilov, M.K. Skakov, G.S. Karipbaeva, Structure and properties of sic coated R6M5 high speed steel Key engineering materials, 594-595 (2014) 730-734.

DOI: 10.4028/www.scientific.net/kem.594-595.730

[6] D.A. Duartea, M. Massi, Incorporation of N in the TiO2 Lattice Versus Oxidation of TiN: Influence of the Deposition Method on the Energy Gap of N-Doped TiO2 Deposited by Reactive Magnetron Sputtering Materials Research, 20(2) (2017) 549-554.

DOI: 10.1590/1980-5373-mr-2016-0303

[7] G. Kaliaraj, A. Ramadoss, M. Sundaram, S. Balasubramanian, J. Muthirulandi, Studies of calcium-precipitating oral bacterial adhesion on TiN,TiO2 single layer, and TiN/TiO2 multilayercoated 316L SS Journal of Materials Science 49 (2014) 7172-7180.

DOI: 10.1007/s10853-014-8425-7

[8] K. Weigel, M. Keunecke, K. Bewilogua, G. Bräuer, G. Grumbt, R. Zenker, H. Biermann Investigations of electron beam hardening on TiAlN coated heat-treatable steel, Materials Performance and Characterization 6(5) (2017) 850-859.

DOI: 10.1520/mpc20170025

[9] J. Lin, R. Wei, A comparative study of thick TiSiCN nanocomposite coatings deposited by dcMS and HiPIMS with and without PEMS assistance Surface and Coatings Technology, 338 (2018) 84-95.

DOI: 10.1016/j.surfcoat.2018.01.082

[10] Kunchenko YU.V., Kunchenko V.V., Kartmazov G.P., Neklyudov I.M. O formirovaniye mikro-nanosloynykh pokrytiy metodom vakuumno-dugovogo osazhdeniya, Fizicheskaya inzheneriya poverkhnosti, 2004, pp.102-108.

[11] Kunchenko V.V., Kunchenko Yu.V., Kartmazov G.P., Neklyudov I.M., Migal A.A., Romanov A.A., Gladkikh N.T., Kryshtal A.P. , Kazarinov Yu.T. Nanostructured superhard nc-TiN / a-Si3N4 coatings obtained by vacuum-arc deposition, Question of atomic science and technology, ser. Physics of radiation damage and radiation materials science. 2006, pp.185-190.

[12] Kunchenko Yu.V., Kunchenko VV, Neklyudov I.M., Kartmazov G.P., Andreev A.A. Layered Ti-Cr N coatings obtained by vacuum-arc deposition, Question of atomic science and technology, ser. Physics of radiation damage and radiation materials science, 2007, pp.203-214.

[13] Beresnev V.M., Tolok V.T., Gritsenko V.I., Chunadra A.G. Obtaining composite coatings from plasma flows of a vacuum arc using RF voltage, Materials scientific. conf. New and unconventional technologies and resources and energy conservation, Kiev, 2004, pp.11-15.

[14] Beresnev V.M., Shvets O.M., Belyaeva T.N. Features of the input of high-frequency energy and the flow of metal plasma, Physiological surface engineering, 2005, pp.37-39.

[15] I.V. Blinkov, A.O. Volkhonsky, D.S. Belov, V.I. Blinkov, R.L. Shatalov, V.A. Andreev, Properties of TiN – Ni nanostructured ceramic-metal coatings obtained by the ion-plasma vacuum-arc method, University proceedings, Non-ferrous metallurgy, 2014, p.52.

DOI: 10.3103/s1067821214050058

[16] Arbuzov M.P., Golub S.YA., Khayenko V.F., Izv. AN USSR Neorganicheskiye materialy, 1977, pp.1779-1789.

[17] Z. Sagdoldina, O. Stepanova, B. Tuyakbayev, D. Buitkenov, The effect of heat treatment on the structural-phase states of Ti-Al coatings synthesized by the method of mechanical alloying, METAL 2018 27th International Conference on Metallurgy and Materials, Conference Proceedings Czech Republic, (2018) 1229-1234.

[18] A.A. Andreev, V.A. Stolbovoy, I.V. Serdyuk, Vacuum-arc superhard tin coatings and usage of them for tool hardening, 2, 5, 50. (2011).