利用加速离散元件模拟框架开发最佳 L-PBF 工艺参数

IF 2.4 3区 工程技术
Marwan Aarab, Bram J. A. Dorussen, Sandra S. Poelsma, Joris J. C. Remmers
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引用次数: 0

摘要

激光粉末床熔融技术(L-PBF)在生产复杂、轻质和高性能部件方面具有巨大潜力。由于依赖实验方法,传统的工艺参数优化成本高、时间长。目前的数值分析通常采用单线扫描建模,而要对大块材料质量进行优化,则需要对多个完全扫描层建模。在此,我们介绍一种利用离散元模拟与射线追踪建模激光热源的新方法。与传统优化方法相比,我们的方法大大降低了成本和时间消耗。通过 GPU 加速,可以对多层材料进行高效模拟,从而优化块状材料的参数。在一个案例研究中,仅用 5 天就优化了 AlSi10Mg 的参数,而如果没有 GPU 加速,这一过程需要 8 个多月。实验验证证实了优化工艺参数的质量,光密度达到了 99.91%。这使得分离的光密度达到 99.91%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Development of optimal L-PBF process parameters using an accelerated discrete element simulation framework

Development of optimal L-PBF process parameters using an accelerated discrete element simulation framework

Laser Powder Bed Fusion (L-PBF) has immense potential for the production of complex, lightweight, and high-performance components. The traditional optimization of process parameters is costly and time-intensive, due to reliance on experimental approaches. Current numerical analyses often model single-line scans, while it is necessary to model multiple fully scanned layers to optimize for bulk material quality. Here, we introduce a novel approach utilizing discrete element simulations with a ray tracing-modeled laser heat source. Our approach significantly reduces the cost and time consumption compared to conventional optimization methods. GPU acceleration enables efficient simulation of multiple layers, resulting in parameters optimized for bulk material. In a case study, parameters were optimized for AlSi10Mg in just 5 days, a process that would have taken over 8 months without GPU acceleration. Experimental validation affirms the quality of the optimized process parameters, achieving an optical density of 99.91%.

Graphical Abstract

Optimization using the accelerated simulation yielded an optimized parameter set within 5 days. This resulted in a part with an optical density of 99.91%.

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来源期刊
Granular Matter
Granular Matter MATERIALS SCIENCE, MULTIDISCIPLINARY-MECHANICS
CiteScore
4.30
自引率
8.30%
发文量
95
期刊介绍: Although many phenomena observed in granular materials are still not yet fully understood, important contributions have been made to further our understanding using modern tools from statistical mechanics, micro-mechanics, and computational science. These modern tools apply to disordered systems, phase transitions, instabilities or intermittent behavior and the performance of discrete particle simulations. >> Until now, however, many of these results were only to be found scattered throughout the literature. Physicists are often unaware of the theories and results published by engineers or other fields - and vice versa. The journal Granular Matter thus serves as an interdisciplinary platform of communication among researchers of various disciplines who are involved in the basic research on granular media. It helps to establish a common language and gather articles under one single roof that up to now have been spread over many journals in a variety of fields. Notwithstanding, highly applied or technical work is beyond the scope of this journal.
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