研究 AlSi10Mg 合金激光粉末床熔融凝固过程中热行为对微观结构的影响:相场分析

IF 1.7 4区 工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
B. Panda, Seshadev Sahoo, Cheruvu Siva Kumar, Ashish Kumar Nath
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引用次数: 0

摘要

在增材制造实验中使用激光粉末床熔融(L-PBF)方法,揭示了通过操纵热条件在凝固微结构中诱导形态演变的惊人潜力。这种性质的转变会对产品的最终质地和材料特性产生重大影响。本研究利用数值研究来考察使用 L-PBF 工艺制造的 AlSi10Mg 合金在不同热条件下的微观结构演变。为了研究微观结构的变化,我们采用了参数相场 (PF) 模型。该模型有效地复制了接种颗粒核的自然发展过程,并准确地模拟了形态的转变。通过对 AlSi10Mg 合金定向凝固过程中的形态转变进行数值研究,确定了 PF 模型的有效性。然后将该模型的预测结果与 Hunt 分析模型进行比较。当温度梯度 (G) 与凝固速率 (R) 的比值增大时,可观察到柱状微观结构的形成,其次生枝晶臂间距显著减小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigating the influence of thermal behavior on microstructure during solidification in laser powder bed fusion of AlSi10Mg alloys: A phase-field analysis
The utilization of the laser powder bed fusion (L-PBF) method in additive manufacturing experiments has revealed the intriguing potential to induce morphological evolutions within the solidification microstructure by manipulating the thermal conditions. Transitions of this nature can have a substantial impact on the ultimate texture and material properties of the product. This study utilizes numerical investigations to examine the microstructure evolution of the AlSi10Mg alloy, which is fabricated using the L-PBF process, under different thermal conditions. In order to investigate the changes in the microstructure, we employ a parameter phase-field (PF) model. This model effectively replicates the natural development of nuclei from inoculant particles and accurately simulates the transitions in the morphology. The PF model’s validity is determined through the numerical investigation of morphological transitions during directional solidification of the AlSi10Mg alloy. The model’s predictions are then compared to the analytical Hunt model. The formation of a columnar microstructure with a significantly reduced secondary dendrite arm spacing is observed when the ratio of the temperature gradient (G) to the solidification rate (R) is increased.
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来源期刊
CiteScore
3.60
自引率
9.50%
发文量
125
审稿时长
>12 weeks
期刊介绍: The Journal of Laser Applications (JLA) is the scientific platform of the Laser Institute of America (LIA) and is published in cooperation with AIP Publishing. The high-quality articles cover a broad range from fundamental and applied research and development to industrial applications. Therefore, JLA is a reflection of the state-of-R&D in photonic production, sensing and measurement as well as Laser safety. The following international and well known first-class scientists serve as allocated Editors in 9 new categories: High Precision Materials Processing with Ultrafast Lasers Laser Additive Manufacturing High Power Materials Processing with High Brightness Lasers Emerging Applications of Laser Technologies in High-performance/Multi-function Materials and Structures Surface Modification Lasers in Nanomanufacturing / Nanophotonics & Thin Film Technology Spectroscopy / Imaging / Diagnostics / Measurements Laser Systems and Markets Medical Applications & Safety Thermal Transportation Nanomaterials and Nanoprocessing Laser applications in Microelectronics.
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