复合材料的三维印刷:工艺的有限元/有限体积建模综述

Theodor-Florian Zach, M. Dudescu
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引用次数: 0

摘要

复合材料代表了材料科学和技术的发展,最大限度地提高了高端工业应用的性能。相关领域包括航空航天和国防、汽车或海军工业。快速成型制造(AM)技术由于消除了形状障碍、提供了大量可用材料并降低了成本,其市场份额正日益增长。复合材料的增材制造技术结合了制造业的两大发展趋势,兼具二者的优势,其具体优势在于无需为复合材料制造模具,甚至无需进行后固化处理。AM 复合材料面临的挑战是如何与传统复合材料竞争。本文旨在介绍不同范围的有限元分析(FEA)中的增材制造工艺。第一项成果是建筑定义(支撑定义)和沉积轨迹优化。此外,还利用计算流体动力学(CFD)对熔化/凝固进行了多物理场分析,以预测纤维取向和挤出轮廓。工艺建模还包括位移/温度分布,它会影响孔隙率、翘曲和残余应力,从而影响部件的特性。这有助于调整技术参数,从而改进制造工艺。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Three-Dimensional Printing of Composites: A Review of the Finite Element/Finite Volume Modelling of the Process
Composite materials represent the evolution of material science and technology, maximizing the properties for high-end industry applications. The fields concerned include aerospace and defense, automotive, or naval industries. Additive manufacturing (AM) technologies are increasingly growing in market shares due to the elimination of shape barriers, a plethora of available materials, and the reduced costs. The AM technologies of composite materials combine the two growing trends in manufacturing, combining the advantages of both, with a specific enhancement being the elimination of the need for mold manufacturing for composites, or even post-curing treatments. The challenge of AM composites is to compete with their conventional counterparts. The aim of the current paper is to present the additive manufacturing process across different spectrums of finite element analyses (FEA). The first outcomes are building definition (support definition) and the optimization of deposition trajectories. In addition, the multi-physics of melting/solidification using computational fluid dynamics (CFD) are performed to predict the fiber orientation and extrusion profiles. The process modelling continues with the displacement/temperature distribution, which influences porosity, warping, and residual stresses that influence characteristics of the component. This leads to the tuning of the technological parameters, thus improving the manufacturing process.
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