Journal
POWDER TECHNOLOGY
Volume 429, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.powtec.2023.118873
Keywords
Particle size distribution; Stereology; Additive manufacturing
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Additive manufacturing powders require well-defined particle size distributions and spherical morphology for good powder flowability. Stereological corrections must be applied to measuring the particle size distributions, as the measured values typically underestimate the true diameters. Three stereological correction methods were assessed, and the Finite Difference Method was determined to be the most effective in improving the estimation of particle size distributions.
Additive manufacturing powders require well-defined Particle Size Distributions (PSDs) and spherical morphology for good powder flowability. To simplify characterisation processes, powders can be prepared using standard metallurgical preparation techniques, followed by optical imaging to determine the PSD of crosssectioned particles. However, this measured PSD typically provides underestimates of the true diameters; hence, stereological corrections must be applied. Three stereological correction methods: the Scheil-SchwartzSaltykov (SSS) method; the Goldsmith and Cruz-Orive (GCO) method and a Finite Difference Method (FDM) are assessed. Laser Size Diffraction (LSD) analysis provided the ground truth data. Particle cross-sections of 2,280 powder particles (Ti-6Al-4V) were analysed in the size range of 9-76 & mu;m. The mean absolute errors were found to be 2.3% for the SSS method, 2.4% for the GCO method, and 1.6% for the FDM method. Hence, whilst all three methods provided an improved estimate of the PSD, FDM was determined the most effective method in this case.
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