具有自适应低频吸收性能的3D打印超薄声学材料

Junxiang Fan , Lei Zhang , Xiaobo Wang , Zhi Zhang , Shuaishuai Wei , Bo Song , Aiguo Zhao , Xiao Xiang , Xuefeng Zhu , Yusheng Shi
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引用次数: 3

摘要

传统吸声器固有的吸声频率,使得在变化的声环境中难以解决声波的去除问题。本研究采用结构组合的概念,创新性地设计了具有自适应吸声性能的吸声超材料(AAMs),并通过3D打印技术制造。因此,将两个线圈通道组合在一个单元中,可以在有限的空间内有效地扩大吸收带宽。卷绕通道的纵向运动赋予了aam的整体深度和内部腔体可调;因此,吸声性能可以相应地调整。通过计算分析和实验验证,表明AAM的深度可在10 ~ 20 mm范围内调节,对应的两个通道的吸收频率分别为206 ~ 179 Hz和379 ~ 298 Hz。此外,有限元分析结果还表明,周期性布置可以进一步提高aam的吸声带宽。这项工作开辟了一种有前途的结构设计方法,为具有适应性吸收性能的声学器件提供了一条途径。
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3D Printed Ultra-thin Acoustic Metamaterials with Adaptable Low-frequency Absorption Performance

The inherent absorption frequency of traditional sound absorbers makes it difficult to solve the problem of acoustic wave removal in a changeable acoustic environment. In this study, acoustic absorption metamaterials (AAMs) with adaptable sound absorption performance were innovatively designed using the structural combination concept and fabricated via 3D printing. Accordingly, two coiled-up channels were combined in a single cell, which could effectively broaden the absorption bandwidth in a limited space. The longitudinal movement of the coiled-up channels endowed the tunable entire depth and internal cavity of the AAMs; thus, the sound absorption performance could be tailored accordingly. Through computational analysis and experimental verification, it was demonstrated that the depth of the AAM could be adjusted from 10 mm to 20 mm, and the corresponding absorption frequencies of the two channels ranged from 206 Hz to 179 Hz and 379 Hz to 298 Hz, respectively. In addition, the finite element results also indicate that the sound absorption bandwidth of AAMs could be further improved by the periodic arrangement of the units. This work opens a promising structural design approach for presenting a route toward acoustic devices with adaptable absorption performances.

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