Mesoscopic Simulation of Core–Shell Composite Powder Materials by Selective Laser Melting

Mechanical ball milling is used to produce multi-materials for selective laser melting (SLM). However, since different powders have different particle size distributions and densities there is particle segregation in the powder bed, which affects the mechanical properties of the printed part. Core–s...

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Veröffentlicht in:	Materials 2023-11, Vol.16 (21), p.7005
Hauptverfasser:	Bao, Tao, Tan, Yuanqiang, Xu, Yangli
Format:	Artikel
Sprache:	eng
Schlagworte:	Ball milling Chemical vapor deposition Energy conservation Heat storage Heat transfer Laser beam melting Lasers Manufacturing Materials selection Mechanical properties Melt pools Molding (process) Morphology Particle segregation Particle size Particle size distribution Powder beds Powders Process parameters Simulation Solidification Temperature Thermophysical properties Tungsten carbide
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creator	Bao, Tao Tan, Yuanqiang Xu, Yangli
description	Mechanical ball milling is used to produce multi-materials for selective laser melting (SLM). However, since different powders have different particle size distributions and densities there is particle segregation in the powder bed, which affects the mechanical properties of the printed part. Core–shell composite powder materials are created and used in the SLM process to solve this issue. Core–shell composite powder materials selective laser melting (CS-SLM) has advanced recently, expanding the range of additive manufacturing applications. Heat storage effects and heat transfer hysteresis in the SLM process are made by the different thermophysical characteristics of the core and the shell material. Meanwhile, the presence of melt flow and migration of unmelted particles in the interaction between unmelted particles and melt complicates the CS-SLM molding process. It is still challenging to investigate the physical mechanisms of CS-SLM through direct experimental observation of the process. In this study, a mesoscopic melt-pool dynamics model for simulating the single-track CS-SLM process is developed. The melting characteristics of nickel-coated tungsten carbide composite powder (WC@Ni) were investigated. It is shown that the powder with a smaller particle size is more likely to form a melt pool, which increases the temperature in the area around it. The impact of process parameters on the size of the melt pool and the distribution of the reinforced particles in the melt pool was investigated. The size of the melt pool is significantly affected more by changes in laser power than by changes in scanning speed. The appropriate control of the laser power or scanning speed can prevent enhanced particle aggregation. This model is capable of simulating CS-SLM with any number of layers and enables a better understanding of the CS-SLM process.
doi_str_mv	10.3390/ma16217005
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In this study, a mesoscopic melt-pool dynamics model for simulating the single-track CS-SLM process is developed. The melting characteristics of nickel-coated tungsten carbide composite powder (WC@Ni) were investigated. It is shown that the powder with a smaller particle size is more likely to form a melt pool, which increases the temperature in the area around it. The impact of process parameters on the size of the melt pool and the distribution of the reinforced particles in the melt pool was investigated. The size of the melt pool is significantly affected more by changes in laser power than by changes in scanning speed. The appropriate control of the laser power or scanning speed can prevent enhanced particle aggregation. 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subjects	Ball milling Chemical vapor deposition Energy conservation Heat storage Heat transfer Laser beam melting Lasers Manufacturing Materials selection Mechanical properties Melt pools Molding (process) Morphology Particle segregation Particle size Particle size distribution Powder beds Powders Process parameters Simulation Solidification Temperature Thermophysical properties Tungsten carbide
title	Mesoscopic Simulation of Core–Shell Composite Powder Materials by Selective Laser Melting
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