High-fidelity Modeling of Multilayer Building Process in Electron Beam Powder Bed Fusion: Build-quality Prediction and Formation-Mechanism Investigation

Chaochao Wu , Pu Xie , Muhammad Qasim Zafar , Haiyan Zhao
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Abstract

High-fidelity simulations of powder bed fusion (PBF) additive manufacturing have made significant progress over the past decade. In this study, an efficient two-dimensional frame was developed for simulating the electron beam PBF process with hundreds of tracks for the direct prediction of the build quality. The applicable parameter range of the developed model was determined by comparing the heat transfer with that in three-dimensional cases. Subsequently, powder deposition and selective melting were coupled for a continuous simulation of the multilayer process. Three powder deposition models were utilized to generate random powder particles, and their effects on the packing structure and the resultant simulated build quality were investigated. The predicted build quality was validated using experimental results from independent studies. By reproducing the building process, the defect development mechanism in a multilayer process was revealed for the coalescence behaviors of randomly distributed powder particles, which also confirmed the importance of simulation at the high-fidelity powder scale. The effects of key process parameters during multilayer and multi-track processes on the build quality were systematically investigated. In particular, the formation statuses of all tracks during the simulated building process were recorded and analyzed statistically, which provided crucial information on the printing process for understanding the building mechanism or performing uncertainty analysis.

Abstract Image

电子束粉末床熔合多层构建过程的高保真建模:构建质量预测和形成机制研究
在过去的十年里,粉末床聚变(PBF)增材制造的高保真度模拟取得了重大进展。在这项研究中,开发了一个有效的二维框架来模拟具有数百个轨道的电子束PBF过程,用于直接预测构建质量。通过与三维情况下的传热比较,确定了所开发模型的适用参数范围。随后,将粉末沉积和选择性熔融相结合,对多层工艺进行连续模拟。利用三个粉末沉积模型生成随机粉末颗粒,并研究了它们对填料结构和模拟构建质量的影响。使用独立研究的实验结果验证了预测的构建质量。通过再现构建过程,揭示了随机分布的粉末颗粒聚结行为在多层过程中的缺陷发展机制,这也证实了高保真度粉末尺度模拟的重要性。系统地研究了多层和多轨道工艺中关键工艺参数对构建质量的影响。特别是,对模拟建造过程中所有轨道的形成状态进行了记录和统计分析,为了解建造机理或进行不确定性分析提供了有关印刷过程的关键信息。
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