Design and Numerical Analysis of Locally-Resonant Meta-Lattice Structure for Vibration Attenuation

Volume 1: Acoustics, Vibration, and Phononics Pub Date : 2022-10-30 DOI:10.1115/imece2022-95206

Utku Güngör, A. Kurt, Mert Lale, Furkan Acar, R. M. Görgülüarslan, H. Ö. Ünver

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Abstract

Meta-materials are artificial materials that perform superior properties in addition to natural behavior. Regardless of their chemical properties, metamaterials show high performance due to their geometric orientation. There are mechanical metamaterials that are used in vibration and acoustic fields, the main subject of which is wave transmission. The propagation of mechanical waves, which can cause problems such as structural damage, fatigue, poor performance, and discomfort in the industry, can be prevented or reduced by using meta-materials. Mechanical waves of various frequencies can be reduced or eliminated by locally resonant metamaterials obtained by adding various masses to viscoelastic materials. Metamaterials can be designed by modifying various lattice structures. Higher performance metamaterials are designed in this study by modifying the lattice structures used in the literature for vibration isolation. Finite element analyzes are carried out to show the transmissibility performance of the designed meta-lattice structures.

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局部共振元晶格结构减振设计与数值分析

超材料是一种人造材料，除了具有自然性能外，还具有优越的性能。无论其化学性质如何，由于其几何取向，超材料表现出高性能。有一些机械超材料用于振动和声场，其主要研究对象是波的传输。机械波的传播在工业中会导致结构损坏、疲劳、性能差和不适等问题，可以通过使用超材料来预防或减少。通过在粘弹性材料中加入不同质量得到局部共振的超材料，可以减小或消除各种频率的机械波。可以通过修改各种晶格结构来设计超材料。在本研究中，通过修改文献中用于隔振的晶格结构，设计了性能更高的超材料。对所设计的元晶格结构的透射率进行了有限元分析。

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Volume 1: Acoustics, Vibration, and Phononics

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