The production of composite electrolytic coatings on a nickel substrate using binary titanium–chromium diboride obtained by mechanical synthesis was studied. The influence of heat treatment parameters on the phase composition and structure of the coatings was examined. It is shown that these coatings substantially increase the wear resistance of structural medium-carbon steel.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
I. M. Fedorchenko, V. A. Danilenko, and Yu. A. Guslienko, “Wear-resistant composite electrolytic coatings based on nickel and iron,” Powder Metall. Met. Ceram., 16, No. 5, 375–377 (1977).
I. M. Fedorchenko, “Coatings as protection against wear and recovery of worn parts,” Zashch. Pokr. Met., No. 17, 3–9 (1983).
L. I. Andropov, M. I. Bykova, and I. V. Shklianaya, “On some features of electrospark deposition of nickel-based coatings,” Zashch. Met., No. 4, 420–424 (1981).
I. I. Borodin, “Self-lubricating nickel coatings containing oxides, carbides, and borides,” Powder Metall. Met. Ceram., 18, No. 2, 112–116 (1979).
M. S. Kovalchenko, L. F. Ochkas, and V. B. Vinokurov, “Hot pressing of binary titanium–chromium diboride,” Powder Metall. Met. Ceram., 19, No. 5, 347–350 (1980).
V. L. Zhunkovsky, V. P. Tereshchenkova, and T. M. Evtushok, “Sintering kinetics and some properties of binary titanium–chromium boride,” Powder Metall. Met. Ceram., 18, No. 8, 541–543 (1979).
T. I. Serebryakova, V. A. Neronov, and P. D. Peshev, High-Temperature Borides [in Russian], Metallurgiya, Moscow (1991), p. 368.
M. S. Kovalchenko, L. F. Ochkas, and D. Z. Yurchenko, “Wear-resistant hard metals based on the binary titanium–chromium diboride,” Powder Metall. Met. Ceram., 21, No. 11, 876–879 (1982).
L. L. Sartinskaya, A. A. Pokryshko, E. M. Zavarach, et al., “Composite electrolytic nickel coatings on nanosized boron nitride,” in: Modern Problems of Physical Materials Science [in Russian], Inst. Probl. Materialoved., NAN Ukrainy, Kyiv (2007), pp. 98–101.
M. Ghorbani, M. Mazaheri, K. Khangholi, and Y. Kharazi, “Electrodeposition of graphite–brass composite coatings and characterization of the tribological properties,” Surf. Coat. Technol., 1, 71–76 (2001).
S. V. Fedorchuk, A. A. Kornienko, and V. V. Zhiginas, “Structure of composite electrolytic coatings with eutectic reinforcement developed for elevated-temperature applications,” in: Friction and Wear Problems (Collected Scientific Papers) [in Ukrainian], Nats. Aviat. Unit., Kyiv (2011), Issue 56, pp. 206–210.
A. S. Nechepurenko, “Studying the physicochemical properties of titanium–chromium diboride for developing cladding material,” in: Thermodynamic and Molecular Kinetic Studies of Metallic and Slag Melts (Collected Scientific Papers) [in Russian], UNTTs AN SSSR, Sverdlovsk (1985), pp. 49–53.
V. I. Dvoruk, V. V. Klimkin, V. O. Pasichnyk, and O. V. Tisov, “Upgraded 2070 SMT-1 tribotechnical machine,” in: Friction and Wear Problems (Collected Scientific Papers) [in Ukrainian], Kyiv (2009), Issue 51, pp. 34–38.
G. N. Makarenko, L. A. Krushinskaya, I. I. Timofeeva, et al., “Mechanical synthesis of double titanium–chromium diboride,” Nanostrukt. Materialoved., No. 2, 3–8 (2012).
N. I. Panina, A. M. Zakharov, V. G. Olenicheva, et al., Phase Diagrams of Metallic Systems [in Russian], VINITI, Moscow (1986), p. 742.
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Poroshkova Metallurgiya, Vol. 57, Nos. 3–4 (520), pp. 117–123, 2018.
Rights and permissions
About this article
Cite this article
Mediukh, V.K., Labunets, V.F., Mediukh, R.M. et al. Use of Binary Titanium–Chromium Diboride for Producing Protective Coatings on a Nickel Substrate. Powder Metall Met Ceram 57, 215–220 (2018). https://doi.org/10.1007/s11106-018-9971-3
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11106-018-9971-3