Abstract
Measurements have been made on the mass-transfer kinetics, structure, and properties of the surface layer in spark mass transfer of composite ceramics in the systems AlN-Ti(Zr)B2 and LaB6-ZrB2. A model is proposed for the formation of the wear-resistant coating on aluminum alloys, which is based on the screening action of the vapors and particles of the nonconducting phases in the electrode gap and involves the differing wettability of the alloying components by the substrate material.
Similar content being viewed by others
References
C. Meneau, P. Andreazza, C. Andreazza-Vignolle, et al., “Laser surface modification: Structural and tribological studies of AlN coatings,” Surface Coat. Technol., 100–101, No. 1–3, 12–16 (1998).
A. L. Thomann, E. Sicard, C. Boulmer-Leborghe, et al., “Surface nitriding of titanium and aluminium by laser-induced plasma,” Surface Coat. Technol., 97, No. 1–3, 448–452 (1997).
K. K. Hitachi Seisakuse and K. Ohata, Application 3-281774 Japan, A Method of Strengthening Metal Surfaces, Kokai Tokke Koho, Publ. December 2 (1991).
V. V. Mikhailov and A. P. Abramchuk, “Features of the spark alloying of aluminum and its alloys,” Elektron. Obrab. Materialov, No. 2, 36–41 (1986).
A. P. Abramchuk, G. A. Bovkun, V. V. Mikhailov, and Yu. G. Tkachenko, “Wear resistance of coatings on aluminum made by spark alloying with powder mixtures,” Elektron. Obrab. Materialov, No. 3, 25–29 (1987).
Yu. V. Naidich, “Interphase surface energies and edge wetting angles for solids with liquids in equilibrium and nonequilibrium systems,” in: Surface Phenomena in Liquids [in Russian], Nauk. Dumka, Kiev (1968), pp. 337–344.
A. D. Verkhoturov, Yu. I. Mulin, and A. N. Vishnevskii, “Reduction and strengthening of pressing matrices for aluminum profiles by spark alloying,” Fizika i Khimiya Obrab. Materialov, No. 4, 82–89 (2002).
Yu. G. Gogotsi, D. A. Kotyar, V. S. Kresanov, and V. V. Morozov, “High-temperature oxidation of lanthanum hexaboride,” Poroshk. Metall., No. 11, 56–59 (1987).
V. A. Lavrenko, S. S. Chuprov, A. A. Umanskii, et al., “High-temperature oxidation of composites based on TiB2,” Poroshk. Metall., No. 9, 84–86 (1987).
I. A. Podchernyaeva, A. D. Panasyuk, S. S. Zatulovskii, et al., “Structuring and mass transfer in wear-resistant coatings in the spark alloying of Al-Si alloys with LaB6-ZrB2 composite ceramic,” Sverkhtverdye Materialy, No. 6, 50–59 (2003).
M. A. Teplenko, Structuring in Composite Gradient Coatings with Elevated Wear and Corrosion Resistance in Spark Mass Transfer of Ceramic in the System Al-Ti(Zr)-N-B: PhD Thesis [in Ukrainian], Kiev (2003).
A. D. Panasyuk, V. S. Fomenko, and G. G. Glebova, Handbook on Resistance in Nonmetallic Materials in Melts [in Russian], Nauk. Dumka, Kiev (1986).
G. V. Samsonov, A. D. Panasyuk, V. A. Bespyatyi, et al., “Prospects for using SiC fibers to reinforce aluminum alloys,” Poroshk. Metall., No. 5, 93–96 (1975).
Author information
Authors and Affiliations
Additional information
__________
Translated from Poroshkovaya Metallurgiya, Nos. 1–2(447), pp. 51–58, January–February, 2006.
Rights and permissions
About this article
Cite this article
Yurechko, D.V., Podchernyaeva, I.A., Panasyuk, A.D. et al. A model for wear-resistant coating on aluminum alloy formed by spark mass transfer of a composite ceramic. Powder Metall Met Ceram 45, 40–46 (2006). https://doi.org/10.1007/s11106-006-0040-y
Received:
Issue Date:
DOI: https://doi.org/10.1007/s11106-006-0040-y