Detonation Spraying of Composite Targets Based on Ni, Cr and B4C for Magnetron Multi-Functional Coating

Viacheslav V. Sirota; Sergey Zaitsev; Dmitriy Prokhorenkov; Michael Limarenko; Andrey Skiba; Marina G. Kovaleva

doi:10.4028/p-74w31h

Paper Titles

Features of the Structure Formation of the Machine Parts’ Surface Layer in the Conditions of Hybrid Processing
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Determining the Residual Stresses in High-Chromium Cast Iron Plasma Coatings
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Protection against Atmospheric Corrosion by Means of Coatings Based on a Fluorine-Containing Surfactant
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Surface Modification Techniques for Steel Components Working in Wear and Corrosion Conditions
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Detonation Spraying of Composite Targets Based on Ni, Cr and B₄C for Magnetron Multi-Functional Coating
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Ferromagnetic Lubricants in a Bearing with a Porous Coating of a Base Ring
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Friction Impact on the Accuracy of the Dependence of Micro-Hardness on Plastic Deformation in Testing Metals under Uniaxial Compression
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Tribological Properties of Coating Obtained by Magnetron Sputtering of the Composite Target Ni-Cr-B₄C
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Electrophysical Properties of N-Cuinse Based Heterostructures
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 909Detonation Spraying of Composite Targets Based on...

Detonation Spraying of Composite Targets Based on Ni, Cr and B₄C for Magnetron Multi-Functional Coating

Abstract:

The paper presents a method of producing a ceramic metal composite target by detonation gas-thermal spraying allowing spraying almost any powder compositions with high deposition efficiency of up to 90% and the possibility of spraying large areas at a relatively low cost, differentiation by coating thickness and size. The efficiency of detonation technology and related devices for the production of original composite cathodes for magnetron sputtering using the example of the powder composition Ni + Cr + B₄C is justified. These materials make it possible to obtain composite coatings with a unique composition and characteristics using a magnetron. Magnetron sputtering is one of the most suitable methods for the industry. The influence of the process mode of metal ceramic powder application on copper substrate is considered. The structure of a metal-ceramic composite target was studied by scanning electron microscopy. It was shown that the target surface is dense without visible pores. The elemental composition of the powder is uniformly distributed over the target surface.

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Periodical:

Key Engineering Materials (Volume 909)

Pages:

115-120

DOI:

https://doi.org/10.4028/p-74w31h

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Online since:

February 2022

Authors:

Viacheslav V. Sirota*, Sergey Zaitsev, Dmitriy Prokhorenkov, Michael Limarenko, Andrey Skiba, Marina G. Kovaleva

Keywords:

Microstructure, Multi-Chamber Detonation Device, Multicomponent Targets

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