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Main Authors: Gaboriault, Olivier, Timercan, Anatolie, Pelletier, Roger, Lefebvre, Louis-Philippe, Melancon, David, Blais, Bruno
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.26402
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author Gaboriault, Olivier
Timercan, Anatolie
Pelletier, Roger
Lefebvre, Louis-Philippe
Melancon, David
Blais, Bruno
author_facet Gaboriault, Olivier
Timercan, Anatolie
Pelletier, Roger
Lefebvre, Louis-Philippe
Melancon, David
Blais, Bruno
contents A custom apparatus designed to isolate and replicate the spreading process of metal powder in additive manufacturing demonstrates a sudden and unexplained increase in packing density beyond layers 5 to 10. We replicate the experiments that lead to densification with the discrete element method (DEM) using \lethe{}, an open-source software framework. We show that large-scale multi-layer DEM simulations are able to reproduce the densification observed experimentally. Using the Lagrangian simulation results, we highlight significant particle displacement in the powder bed at lower layer number, accompanied by static zones generated by the vertical wall surrounding the powder bed. The amplitude of the densification and the layer number at which it starts to occur is correlated to the distance between those two vertical walls which delimit the powder spreading area. This study addresses the gap between mono-layer powder spreading studies on hard-flat surfaces and the actual metal powder-based additive manufacturing processes by providing a better understanding of how the powder bed behaves during multi-layer spreading.
format Preprint
id arxiv_https___arxiv_org_abs_2509_26402
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Increase in packing density during multi-layer powder spreading: An experimental and numerical study
Gaboriault, Olivier
Timercan, Anatolie
Pelletier, Roger
Lefebvre, Louis-Philippe
Melancon, David
Blais, Bruno
Applied Physics
A custom apparatus designed to isolate and replicate the spreading process of metal powder in additive manufacturing demonstrates a sudden and unexplained increase in packing density beyond layers 5 to 10. We replicate the experiments that lead to densification with the discrete element method (DEM) using \lethe{}, an open-source software framework. We show that large-scale multi-layer DEM simulations are able to reproduce the densification observed experimentally. Using the Lagrangian simulation results, we highlight significant particle displacement in the powder bed at lower layer number, accompanied by static zones generated by the vertical wall surrounding the powder bed. The amplitude of the densification and the layer number at which it starts to occur is correlated to the distance between those two vertical walls which delimit the powder spreading area. This study addresses the gap between mono-layer powder spreading studies on hard-flat surfaces and the actual metal powder-based additive manufacturing processes by providing a better understanding of how the powder bed behaves during multi-layer spreading.
title Increase in packing density during multi-layer powder spreading: An experimental and numerical study
topic Applied Physics
url https://arxiv.org/abs/2509.26402