Understanding Powder Behavior in an Additive Manufacturing Process Using DEM

The handling of bulk solids in the form of powders is a fundamental process in a wide range of manufacturing industries, such as the automotive, aerospace, food, and healthcare sectors. All these sectors employ additive manufacturing (AM), as it enables the production of complex parts in a short amo...

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Veröffentlicht in:	Processes 2022-09, Vol.10 (9), p.1754
Hauptverfasser:	Sousani, Marina, Pantaleev, Stefan
Format:	Artikel
Sprache:	eng
Schlagworte:	3-D printers 3D printing Additive manufacturing Aerospace industry Agile manufacturing Calibration Design of experiments Discrete element method Lead time Mechanics Simulation Simulation methods Velocity Workflow
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creator	Sousani, Marina Pantaleev, Stefan
description	The handling of bulk solids in the form of powders is a fundamental process in a wide range of manufacturing industries, such as the automotive, aerospace, food, and healthcare sectors. All these sectors employ additive manufacturing (AM), as it enables the production of complex parts in a short amount of time. Thus, it is considered an established method for developing an agile manufacturing environment that can drastically reduce the lead time from conception to the production stage. At the same time, powder is a unique material sensitive to environmental and machine conditions; hence, establishing an optimal configuration is not straight-forward. This work presents a discrete element method (DEM) simulation of an experimental dosing system used in AM. We introduce a robust workflow that correlates suitable experimental data with simulation results, establishing models of real powders with different flowability. The results showed an excellent agreement between the experimental data and the simulation results and provided a better understanding of the material behavior. Furthermore, we employed a coarse-grained approach to extract continuum fields from the discrete data. The results showed that the cohesion level in the system was enough to create agglomerates that hindered the transport of the material and produced nonuniform distribution.
doi_str_mv	10.3390/pr10091754
format	Article
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subjects	3-D printers 3D printing Additive manufacturing Aerospace industry Agile manufacturing Calibration Design of experiments Discrete element method Lead time Mechanics Simulation Simulation methods Velocity Workflow
title	Understanding Powder Behavior in an Additive Manufacturing Process Using DEM
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