The Effect of Morphology and Particle-Size Distribution of VT20 Titanium Alloy Powders on the Mechanical Properties of Deposited Coatings

The surface morphology of coatings produced from spherical and nonspherical VT20 titanium alloy powders with different particle-size distributions has been studied. The microhardness and plasticity of the coatings have been determined. The coatings deposited with nonspherical powders are characteriz...

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Veröffentlicht in:	Powder metallurgy and metal ceramics 2019-03, Vol.57 (11-12), p.697-702
Hauptverfasser:	Duriagina, Z. A., Lemishka, I. A., Trostianchyn, A. M., Kulyk, V. V., Shvachko, S. G., Tepla, T. L., Pleshakov, E. I., Kovbasyuk, T. M.
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Schlagworte:	Aerospace engineering Aerospace industry Alloy powders Alloys Aviation Ceramics Characterization and Evaluation of Materials Chemistry and Materials Science Coatings Composites Glass Hardness (Materials) Materials Science Mechanical engineering Mechanical properties Metallic Materials Microhardness Morphology Natural Materials Particle size distribution Plastic properties Powders (Particulate matter) Protective and Functional Powder Coatings Specialty metals industry Spherical powders Technical institutes Technology Titanium Titanium alloys Titanium base alloys Yield stress
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container_end_page	702
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container_title	Powder metallurgy and metal ceramics
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creator	Duriagina, Z. A. Lemishka, I. A. Trostianchyn, A. M. Kulyk, V. V. Shvachko, S. G. Tepla, T. L. Pleshakov, E. I. Kovbasyuk, T. M.
description	The surface morphology of coatings produced from spherical and nonspherical VT20 titanium alloy powders with different particle-size distributions has been studied. The microhardness and plasticity of the coatings have been determined. The coatings deposited with nonspherical powders are characterized by a fine-grained structure and their micromechanical properties are comparable to those of the coatings deposited with spherical powders. The coatings deposited with the powders of the –160+40 μm fraction show an optimum ratio of microhardness, plasticity, and yield stress, regardless of their structural morphology.
doi_str_mv	10.1007/s11106-019-00033-8
format	Article
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subjects	Aerospace engineering Aerospace industry Alloy powders Alloys Aviation Ceramics Characterization and Evaluation of Materials Chemistry and Materials Science Coatings Composites Glass Hardness (Materials) Materials Science Mechanical engineering Mechanical properties Metallic Materials Microhardness Morphology Natural Materials Particle size distribution Plastic properties Powders (Particulate matter) Protective and Functional Powder Coatings Specialty metals industry Spherical powders Technical institutes Technology Titanium Titanium alloys Titanium base alloys Yield stress
title	The Effect of Morphology and Particle-Size Distribution of VT20 Titanium Alloy Powders on the Mechanical Properties of Deposited Coatings
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