Results are provided for a study of the formation mechanism and conditions for high-temperature corrosion-resistant coatings, which are formed in air (>1500°C) with cyclic thermal changes under the action of concentrated energy sources. It is established that in composite materials of the systems (TiN–AlN)–(TiN–Cr3C2) and (TiN–AlN)–(Ni–Cr)–(TiN–Cr3C2) a complex oxide film forms that has good adhesion to a base and undergoes further composite oxidation, i.e., it promotes an increase in its scaling resistance.
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T. V. Mosina, A. D. Panasyuk, A. I. Yuga, et al., “Friction properties of composite TiN–AlN materials. Effect of structure and phase composition on friction and wear of materials of the system TiN–AlN,” Poroshk. Metall., No. 11/12, 104 – 108 (1999).
V. G. Kayuk, M. S. Koval’chenko, I. S. Martsenyuk, et al., “Effect of nickel-chromium binder on compaction kinetics for cermets based on a mixture of chromium carbide and titanium nitride with hot compaction,” Poroshk. Metall., No. 5/6, 29 – 37 (2007).
V. G. Kayuk and V. A. Maslyuk, “Structure formation fo alloys of the system Cr3C2–TiN and properties of materials based on them,” Poroshk. Metall., No. 1/2, 47 – 52 (2004).
V. A. Lavrenko, T. V. Mosina, A. D. Panasyuk, et al., “High-temperature oxidation of powers based on composite materials of the system TiN–AlN,” Dopovidi NAN Ukraini, No. 12, 139 – 143 (1997).
T. V. Mosina, A. D. Panasyuk, O. N. Grigor’ev, et al., “Structure and phase transitions in TiN–AlN and TiN–AlN–(Ni–Cr–Al) composites produced by focused solar radiation,” Refractories and Industrial Ceramics, 49, No. 5, 388 – 390 (2008).
Use of the Sun and Other Radiant Energy Sources in Materials Science, Coll. Sci. Work [in Russian], Naukova Dumka, Kiev (1983).
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Translated from Novye Ogneupory, No. 2, pp. 22 – 26, February 2011.
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Mosina, T.V. Structure and phase transformations in the surface layers of composite ceramic materials based on the systems (TiN–AlN)–(TiN–Cr3C2) and (TiN–AlN)–(Ni–Cr)–(TiN–Cr3C2) with high-temperature oxidation under conditions of concentrated solar radiation. Refract Ind Ceram 52, 48–51 (2011). https://doi.org/10.1007/s11148-011-9363-4
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DOI: https://doi.org/10.1007/s11148-011-9363-4