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Providing of Operational Properties for Gas-Turbine Engine Parts and Assemblies Using Electrospark Deposition

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Abstract:

Article explains manufacturing capability of titanium parts reliability enhancement and life cycle enhancement by electrospark deposition using low energy discharges. Carbon electrodes used to form functional properties of parts surface layer. Alloyed carbooxide zone consist of highly dispersed structure (with particles of titanium carbide, titanium oxide, graphite), with 3-10 micron thick, and high hardness antifrictionality. Alloyed layer contain ordered phase Ti8C5, TiC, and the structure of Ti6C3,75. Parts dimensions almost do not changed after electrospark deposition with carbon electrodes. Subsequent diamond burnishing decrease friction coefficient and surface roughness. Fatigue resistance increased after healing of defects and microcracks. Local carbooxidation and burnishing used to increase wear resistance of titanium alloys.

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Periodical:

Materials Science Forum (Volume 992)

Pages:

574-579

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.992.574

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Online since:

May 2020

Authors:

L.V. Denisov*, A.G. Boytsov, M.V. Siluyanova

Keywords:

Burnishing, Carbooxidation, Electrospark Deposition, Hardening, Titanium Alloys

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