Multi-Scale Design of Meta-Materials With Offset Periodicity

Volume 2A: 45th Design Automation Conference Pub Date : 2019-08-18 DOI:10.1115/detc2019-98341

R. Sadiwala, G. Fadel

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Abstract

Meta-materials are a class of artificial materials with a wide range of bulk properties that are different from the base material they are made of. The term meta-material in the context of this research refers to a continuous, heterogeneous structure with prescribed elastic properties. Such meta-materials are designed using Topology Optimization (TO). Tools like SIMP interpolation, mesh filtering and continuation methods are used to address the numerical issues with Topology Optimization. In a previous research [1], by offsetting meta-material layers by a half-width of the Unit Cell, an auxetic honeycomb-like geometry was obtained. This was the first time such a shape was observed as the result of Topology Optimization targeting the effective shear modulus using square Unit Cells. This was obtained while designing the shear beam of a non-pneumatic wheel. This research studies the design of meta-materials using offsets other than zero or half-widths. The same problem [1] was solved for different values of offset, and the obtained geometries and volume fractions are studied. It is concluded that it may be beneficial for designers to consider offsetting meta-material layers with offsets other than half-width, to design novel, potentially better performing structures.

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具有偏置周期的超材料多尺度设计

超材料是一类人造材料，具有广泛的体积特性，与制造它们的基础材料不同。在本研究中，“超材料”一词是指具有规定弹性特性的连续、非均质结构。这种超材料是用拓扑优化(TO)技术设计的。使用SIMP插值、网格滤波和延拓方法等工具来解决拓扑优化的数值问题。在先前的一项研究[1]中，通过将超材料层偏移半宽度的Unit Cell，获得了一种辅助蜂窝状几何结构。这是第一次观察到这样的形状，作为拓扑优化的结果，针对有效剪切模量使用方形单元格。这是在设计非气动轮的剪力梁时得到的。本研究研究使用零或半宽度以外的偏移量设计超材料。对相同的问题[1]求解不同的偏移值，并对得到的几何形状和体积分数进行了研究。由此得出结论，设计师可以考虑用半宽以外的偏移量来抵消超材料层，从而设计出新颖的、可能性能更好的结构。

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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Volume 2A: 45th Design Automation Conference

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