Your search keyword '"globular powder"' showing total 2 results

1. The Application of Globular Water-Atomized Iron Powders for Additive Manufacturing by a LENS Technique

Author

Tomasz Czujko, Vlad Paserin, Robert A. Varin, Justyna Aniszewska, Tomasz Durejko, Anna Antolak-Dudka, and Michał Ziętala

Subjects

0209 industrial biotechnology, Range (particle radiation), Materials science, Morphology (linguistics), Lens (geology), 02 engineering and technology, water atomization, 021001 nanoscience & nanotechnology, Article, Volumetric flow rate, Metal, 020901 industrial engineering & automation, visual_art, visual_art.visual_art_medium, globular powder, General Materials Science, Laser engineered net shaping, Particle size, Composite material, 0210 nano-technology, Porosity, additive manufacturing, LENS technique

Abstract

The water-atomized ATOMET 28, 1001, 4701, and 4801 powders, manufactured by Rio Tinto Metal Powders, were used for additive manufacturing by a laser engineered net shaping (LENS) technique. Their overall morphology was globular and rounded with a size distribution from about 20 to 200 µm. Only the ATOMET 28 powder was characterized by a strong inhomogeneity of particle size and irregular polyhedral shape of powder particles with sharp edges. The powders were pre-sieved to a size distribution from 40 to 150 µm before LENS processing. One particular sample—LENS-fabricated from the ATOMET 28 powder—was characterized by the largest cross-sectional (2D) porosity of 4.2% and bulk porosity of 3.9%, the latter determined by microtomography measurements. In contrast, the cross-sectional porosities of bulk, solid, nearly cubic LENS-fabricated samples from the other ATOMET powders exhibited very low porosities within the range 0.03–0.1%. Unexpectedly, the solid sample—LENS-fabricated from the reference, a purely spherical Fe 99.8 powder—exhibited a porosity of 1.1%, the second largest after that of the pre-sieved, nonspherical ATOMET 28 powder. Vibrations incorporated mechanically into the LENS powder feeding system substantially improved the flow rate vs. feeding rate dependence, making it completely linear with an excellent coefficient of fit, R2 = 0.99. In comparison, the reference powder Fe 99.8 always exhibited a linear dependence of the powder flow rate vs. feeding rate, regardless of vibrations.

Published

2018

2. The Application of Globular Water-Atomized Iron Powders for Additive Manufacturing by a LENS Technique.

Author

Durejko, Tomasz, Aniszewska, Justyna, Ziętala, Michał, Antolak-Dudka, Anna, Czujko, Tomasz, Varin, Robert A., and Paserin, Vlad

Subjects

*IRON powder, *THREE-dimensional printing, *METAL powders, *LASERS, *POROSITY, *MANUFACTURING processes

Abstract

The water-atomized ATOMET 28, 1001, 4701, and 4801 powders, manufactured by Rio Tinto Metal Powders, were used for additive manufacturing by a laser engineered net shaping (LENS) technique. Their overall morphology was globular and rounded with a size distribution from about 20 to 200 µm. Only the ATOMET 28 powder was characterized by a strong inhomogeneity of particle size and irregular polyhedral shape of powder particles with sharp edges. The powders were pre-sieved to a size distribution from 40 to 150 µm before LENS processing. One particular sample—LENS-fabricated from the ATOMET 28 powder—was characterized by the largest cross-sectional (2D) porosity of 4.2% and bulk porosity of 3.9%, the latter determined by microtomography measurements. In contrast, the cross-sectional porosities of bulk, solid, nearly cubic LENS-fabricated samples from the other ATOMET powders exhibited very low porosities within the range 0.03–0.1%. Unexpectedly, the solid sample—LENS-fabricated from the reference, a purely spherical Fe 99.8 powder—exhibited a porosity of 1.1%, the second largest after that of the pre-sieved, nonspherical ATOMET 28 powder. Vibrations incorporated mechanically into the LENS powder feeding system substantially improved the flow rate vs. feeding rate dependence, making it completely linear with an excellent coefficient of fit, R2 = 0.99. In comparison, the reference powder Fe 99.8 always exhibited a linear dependence of the powder flow rate vs. feeding rate, regardless of vibrations. [ABSTRACT FROM AUTHOR]

Published

2018