Production of Thermal Spray Cr3C2-Ni Powders by Mechanically Activated Synthesis

The aim of this research was to optimize the mechanically activated synthesis (MAS) technology of the Cr3C2-Ni powder intended for thermal spraying. The MAS production route included ball milling for 72 h (ball-to-powder ratio 20:1) and sintering under 1075 °C in vacuum for 4 h. Sintered compact was...

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Bibliographic Details
Published in:Key engineering materials 2019-04, Vol.799, p.31-36
Main Authors: Jankauskas, Vytenis, Traksmaa, Rainer, Leišys, Rimtautas, Surzhenkov, Andrei, Juhani, Kristjan, Tkachivskyi, Dmytro, Kulu, Priit, Viljus, Mart
Format: Article
Language:English
Subjects:
Abrasive wear
Abrasives
Ball milling
Chromium carbide
Coatings
Electron microscopes
Elongation
Flame spraying
Morphology
Optimization
Oxy-fuel
Phase composition
Powder spraying
Sintering (powder metallurgy)
Solid solutions
Sprayed coatings
Synthesis
Thermal spraying
Wear rate
Wear tests
X-ray diffraction
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Summary:The aim of this research was to optimize the mechanically activated synthesis (MAS) technology of the Cr3C2-Ni powder intended for thermal spraying. The MAS production route included ball milling for 72 h (ball-to-powder ratio 20:1) and sintering under 1075 °C in vacuum for 4 h. Sintered compact was crushed, classified by sieving to obtain the fraction suitable for thermal spraying (20–45 μm). The morphology and the phase composition of the powder were analyzed by a scanning electron microscope (SEM) and X-ray diffraction (XRD). The optimal Cr:C ratio found was 7:1. The powder had an equiaxial or a slightly elongated lamellar shape, Cr3C2 carbides in a single powder particle had an elongated shape. The principal phases in the optimized powder were Cr3C2, Cr7C3 and Ni (Cr) solid solution. Coatings from the manufactured powder were produced by the high velocity oxy-fuel (HVOF) spraying. The abrasive wear tests were carried out according to standard ASTM G65. The wear tests showed that the sprayed coatings from the experimental powder exhibited about five times higher wear rate at abrasive wear conditions than the coatings from the reference commercial powder.
ISSN:1013-9826
1662-9795
1662-9795
DOI:10.4028/www.scientific.net/KEM.799.31