Lattice Structure Design for Additive Manufacturing: Unit Cell Topology Optimization

Bradley Hanks, M. Frecker
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引用次数: 3

Abstract

Additive manufacturing is a developing technology that enhances design freedom at multiple length scales, from the macroscale, or bulk geometry, to the mesoscale, such as lattice structures, and even down to tailored microstructure. At the mesoscale, lattice structures are often used to replace solid sections of material and are typically patterned after generic topologies. The mechanical properties and performance of generic unit cell topologies are being explored by many researchers but there is a lack of development of custom lattice structures, optimized for their application, with considerations for design for additive manufacturing. This work proposes a ground structure topology optimization method for systematic unit cell optimization. Two case studies are presented to demonstrate the approach. Case Study 1 results in a range of unit cell designs that transition from maximum thermal conductivity to minimization of compliance. Case Study 2 shows the opportunity for constitutive matching of the bulk lattice properties to a target constitutive matrix. Future work will include validation of unit cell modeling, testing of optimized solutions, and further development of the approach through expansion to 3D and refinement of objective, penalty, and constraint functions.
增材制造的点阵结构设计:单元胞拓扑优化
增材制造是一种发展中的技术,它可以在多个长度尺度上提高设计自由度,从宏观尺度(或体几何)到中尺度(如晶格结构),甚至到定制的微观结构。在中尺度,晶格结构经常被用来代替材料的固体部分,并且通常是在通用拓扑结构之后的图案。许多研究人员正在探索通用单元胞拓扑结构的机械性能和性能,但缺乏针对其应用进行优化的定制晶格结构的开发,并考虑到增材制造的设计。本文提出了一种用于系统单元优化的地面结构拓扑优化方法。提出了两个案例研究来演示该方法。案例研究1产生了一系列从最大导热系数到最小顺应性的单元电池设计。案例研究2显示了体晶格特性与目标本构矩阵本构匹配的机会。未来的工作将包括验证单元胞模型,测试优化的解决方案,以及通过扩展到3D和改进目标、惩罚和约束函数来进一步开发方法。
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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