PROGRAMMABLE BEHAVIOR OF THE METAMATERIAL BY KINDS OF UNIT CELLS CONNECTION

Q3 Materials Science

PNRPU Mechanics Bulletin Pub Date : 2023-12-15 DOI:10.15593/perm.mech/2023.1.03

Smolin I.Yu., Programmable, Л . Р . Ахметшин, И . Ю . Смолин, Igor S. Yurievich, L. Akhmetshin, I.Yu. Smolin, ©. Pnrpu

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Abstract

The paper is devoted to the numerical analysis of uniaxial loading of a sample of the mechanical metamaterial. The structure of the mechanical metamaterial is constructed of a ring and four ligaments, which make up a tetrachiral structure. The peculiarity of such a structure consists in torsion of the sample under the force load. Two methods of connecting cells in the metamaterial are considered: "adjoining" and "overlapping". The "adjoining" method of joining cells increases the thickness of the internal structure of the sample, which allows us to consider it as a topological defect of the metamaterial. The "overlapping" method saves the base material from which the tetrachiral structure is constructed. Differences in the structure when constructing a three-dimensional sample result in a significant change in the characteristics of the sample. Numerical solution of the problem is performed in a three-dimensional formulation using the finite element method. The constitutive relation describing the behavior of the model corresponds to Hooke's law. Numerical simulation of uniaxial loading made it possible to obtain the results of mechanical response and to analyze the effective properties of metamaterials. A topological defect in the form of a thickening of the internal structure elements led to a difference in the linear dimensions of the two samples. The increased thickness of the unit cell connection elements resulted in a decrease in the effective density of the metamaterial sample. The same sample showed a triple increase in the value of the elastic modulus. The greater ability to resist deformation resulted in a reduced twist effect compared to the sample whose cells were joined by the "overlapping" method. The results obtained will make it possible to program the mechanical behavior and properties of the metamaterial sample.

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可编程的超材料的行为由各种单元细胞连接

本文对力学超材料试样的单轴加载进行了数值分析。这种机械超材料的结构是由一个环和四个韧带构成的，构成了一个四手结构。这种结构的特点在于试样在力荷载作用下的扭转。在超材料中考虑了两种连接细胞的方法:“相邻”和“重叠”。连接细胞的“相邻”方法增加了样品内部结构的厚度，这使我们可以将其视为超材料的拓扑缺陷。“重叠”法节省了构成四手结构的基材。在构建三维样品时，结构的差异会导致样品特征的显著变化。采用三维有限元法对该问题进行了数值求解。描述模型行为的本构关系符合胡克定律。单轴载荷的数值模拟可以得到力学响应的结果和分析超材料的有效性能。内部结构元素增厚形式的拓扑缺陷导致两个样品的线性尺寸不同。单元胞连接元件厚度的增加导致了超材料样品有效密度的降低。同一试样的弹性模量增加了三倍。与通过“重叠”方法连接细胞的样品相比，更大的抗变形能力导致扭曲效应降低。所得结果将使对超材料样品的力学行为和性能进行编程成为可能。

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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来源期刊

PNRPU Mechanics Bulletin Materials Science-Materials Science (miscellaneous)

CiteScore

1.10

自引率

0.00%

发文量