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Particle shape and size analysis for metal powders used for additive manufacturing: Technique description and application to a gas-atomized Ti64 powder and a plasma-atomized Ti64 powder

Published

Author(s)

Edward Garboczi, Nik Hrabe

Abstract

The particle size and shape distributions ofmetal powders used in additive manufacturing powder bed fusion processes are of technological importance for the final built product. Current three- dimensional (3D) measurements of these distributions always assume a spherical shape, while techniques that measure both size and shape are always two-dimensional (2D) measurements of particle projections. This paper describes a set of techniques using X-ray computed tomography, combined with various mathematical algorithms, to measure the 3D size, shape, and internal porosity of individual particles. Calibrating by a limited amount of visual examination of 3D images of individual particles, these techniques can classify powder particles as single near-spherical (SnS) particles, and non-spherical (NS) particles, which consist of either single highly non- spherical particles or multi-particles, where two or more smaller particles have been "welded" together. From this 3D data, other algorithms can generate 2D particle size and shape information to compare with the results of 2D measurement techniques. These techniques are applied to two metal powders composed of a specific alloy of titanium with aluminum and vanadium, denoted Ti-Al6-V4, which is in common use as a powder for selective laser or electron beam melting powder bed additive manufacturing. One powder was made with a gas-atomization process, and the other with a plasma- atomization process, and both have been recycled and both pass the specifications for additive manufacturing use. The powders differ in the fraction of NS particles and porous particles and in their size and shape distributions and average shape and size statistics. The SnS/NS classification enables one to show how these classes contribute to the overall particle size distributions, even for a single powder type, and is useful for comparing different sources of powder as well as studying how a single powder type changes over multiple recycling events.
Citation
Additive Manufacturing
Volume
31

Keywords

X-ray computed tomography, additive manufacturing, metal powder, selective laser melting, electron beam melting, powder bed, titanium alloy, Ti-Al6-V4, particle size distribution, particle shape distribution

Citation

Garboczi, E. and Hrabe, N. (2019), Particle shape and size analysis for metal powders used for additive manufacturing: Technique description and application to a gas-atomized Ti64 powder and a plasma-atomized Ti64 powder, Additive Manufacturing, [online], https://doi.org/10.1016/j.addma.2019.100965 (Accessed December 26, 2024)

Issues

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Created November 23, 2019, Updated July 23, 2024