利用离散元素法开发激光粉末床熔融工艺中功能分级粉末铺展的方法学

IF 2.4 4区 材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING Welding in the World Pub Date : 2024-06-18 DOI:10.1007/s40194-024-01796-4
Shakti Swaroop Choudhury, Ratna Kumar Annabattula, Murugaiyan Amirthalingam
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引用次数: 0

摘要

使用多材料元件可以定制物理特性、减轻重量、实现有效的热管理,还可以创建材料兼容的缓冲元件,轻松连接两种材料。这些特性超越了单一材料组件的能力。当使用具有尖锐界面的多种材料时,由于在使用负载条件下存在尖锐的应力集中梯度,通常会在界面处发生故障。如果界面上的多种材料成分能够平滑变化,则可以延缓失效。为了避免这种情况,可以采用具有扩散界面的功能分级材料。功能分级材料(FGM)在特定方向上具有优先的空间特性变化。然而,通过传统方法生产复杂的 FGM 组件具有挑战性,因为传统制造方法是针对特定部件和工具的。使用粉末床熔融(PBF)等增材制造技术制造的部件可以制造出具有复杂几何特征和微米级精度的 FGM。这为利用 FGM 组件进行创新设计开辟了新途径。利用 PBF 制造 FGM 的方法仍处于起步阶段,需要进一步关注以实现无缺陷组件。通过采用高保真数学模型,可以开发出新的方法,并最大限度地减少昂贵的试错实验开发策略。离散元素法 (DEM) 是一种适合于对不连续介质(如 PBF 中的粉末颗粒)进行建模的数值方法。本研究开发了粉末床熔化过程中的铺展程序,以便在激光熔化前获得所需的材料成分分布。采用基于分区的方法实现了沿铺展方向的功能分级。通过一个名为 "分级指数"(GI)的参数,研究了重涂速度对材料分布演变的作用。开发了一种独特的实验装置来分析所开发模型的预测结果。结果表明,在涂布机上的角度分区可在构建平台上产生定制的功能分级铺展,所获得的分级铺展随重涂机速度、分区角度和铺展层厚度的变化而变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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A methodology for the development of functionally graded powder spreading in laser powder bed fusion process using discrete element method

The use of multi-material components offers customization of physical properties, weight reduction, effective thermal management, and the creation of material-compatible buffer components to join two material with ease. These features surpass the capabilities of single-material compositions. When the multiple materials are used with sharp interfaces, failure often occurs at the interfaces due to the presence of sharp stress concentration gradients under service loading conditions. Failure can be delayed, if the multi-material compositions across the interface can be varied smoothly. To prevent this, functionally graded materials with diffuse interfaces can be employed. Functionally graded materials (FGM) possess preferred spatial variation of properties aligned in specific directions. However, producing complex FGM components through conventional methods is challenging, as the conventional manufacturing methods are part and tool-specific. Components made using additive manufacturing, such as powder bed fusion (PBF), can create FGM with intricate geometric features and precision at the micron scale. This opens up new avenues for innovative design possibilities with FGM components. The methodologies developed to create FGM by PBF are still in their infancy and require further attention to realize defect-free components. By employing high-fidelity mathematical models, new methodologies can be developed and minimize expensive trial-and-error experimental development strategies. The discrete element method (DEM) is a suitable numerical approach for modelling discontinuous media, such as powder particles in PBF. In this study, a spreading procedure in a powder bed fusion process is developed so that the desired distribution of material composition can be obtained before laser melting. A partition-based approach is adapted to achieve functional gradation along the spreading direction. The role of recoater speed on the evolution of the distribution of the material was studied through a parameter called gradation index (GI). A unique experimental setup was developed to analyze the prediction of the developed model. Results show that an angular partition at the dispenser can generate a customized functionally graded spreading in the build platform, and the obtained graded spreading is found to vary as a function of the recoater speed, partition angle, and spread layer thickness.

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来源期刊
Welding in the World
Welding in the World METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
4.20
自引率
14.30%
发文量
181
审稿时长
6-12 weeks
期刊介绍: The journal Welding in the World publishes authoritative papers on every aspect of materials joining, including welding, brazing, soldering, cutting, thermal spraying and allied joining and fabrication techniques.
期刊最新文献
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