| 2020 №12 (04) |
DOI of Article 10.37434/as2020.12.05 |
2020 №12 (06) |
Avtomaticheskaya Svarka (Automatic Welding), #12, 2020, pp. 37-43
Plasma-powder surfacing of composite alloys with separate feed of tungsten carbides and matrix alloy
A.I. Som, B.O. Halahuz
LLC firm «Plasma-Master Ltd». 52 Popudrenko Str, 02094, Kyiv. E-mail: info@plasma-master.com
Various combinations of separate feeding of cast spherical tungsten carbides and matrix alloy into the surfacing zone have been investigated. It has been established that when a self-fluxing nickel-based alloy is used as a matrix, the most stable surfacing process is achieved if tungsten carbides are fed through the axial hole of the focusing nozzle, and the matrix alloy through two channels located diametrically opposite to each other at its end. 6 Ref., 1 Tabl., 11 Fig.
Keywords: Plasma-powder surfacing, tungsten carbides, relite, self-fluxing alloy, matrix, carbide distribution, wear resistance, microhardness
Received: 2.12.2020
References
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3. Som, A.I. (1999) New plasmatrons for plasma-powder surfacing. Avtomatich. Svarka, 7, 44-48 [in Russian].
4. Zhudra, A.P. (2014) Tungsten carbide based cladding materials. The Paton Welding J., 6-7, 66-71. https://doi.org/10.15407/tpwj2014.06.13
5. Yuzvenko, Yu.A., Gavrish, V.A., Marienko, V.Yu. (1979) Laboratory units for evaluation of wear resistance of deposited metal. Theoretical and technological principles of surfacing. Properties and tests of deposited metal. Kiev, PWI, 23-27 [in Russian].
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