利用周期结构理论研究波纹声板的宽带声传输损耗

IF 1.9 4区工程技术 Q2 ACOUSTICS

Journal of Vibration and Acoustics-Transactions of the Asme Pub Date : 2022-09-27 DOI:10.1115/1.4055806

Rajan Prasad, A. Baxy, A. Banerjee

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引用次数: 0

摘要

分析了波纹芯双叶墙板的振动和声辐射特性。核心包括沿面板长度的重复单元格。每个单元是具有均匀截面的直梁和具有变截面的弯梁的组合。分析了波纹板在平应变条件下的振动声学特性。文中的分析表明，所提出的夹层板设计提供了宽带声传输损失(STL)特性。给出了结构的色散分析、强迫响应特性和声辐射特性。从频散分析中得到的弯曲频带隙是获得较高STL的重要判据。通过谱有限元模型分析了夹芯板的结构性能和声学性能。给出了不同锥度比下芯件的STL。研究发现，较高的锥度比使STL特性向低频范围偏移。

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Broadband sound transmission loss in a corrugated sound panel using periodic structure theory

The vibration and sound radiation characteristics of a double leaf panel wall with corrugated core are analyzed. The core comprises of repeating unit cell along the length of the panel. Each cell is a combination of a straight beam with uniform cross-section and curved beams with varying cross-section. The vibroacoustics property of the corrugated panel is analysed assuming plain strain condition. The analysis presented in the work shows that the proposed sandwich panel design provides broadband sound transmission loss (STL) characteristics. The dispersion analysis, forced response characteristics and sound radiation characteristics of the structure are presented. It is found that bending frequency band gap obtained from the dispersion analysis is a prominent criterion to achieve a higher STL. The structural and acoustic behaviours of the sandwich panel are analysed through the spectral finite element model. The STL for the core element for various taper ratios is presented. It is found that a higher taper ratio shifts the STL characteristics to the low frequency range.

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来源期刊

Journal of Vibration and Acoustics-Transactions of the Asme 工程技术-工程：机械

CiteScore

4.20

自引率

11.80%

发文量

审稿时长

7 months

期刊介绍： The Journal of Vibration and Acoustics is sponsored jointly by the Design Engineering and the Noise Control and Acoustics Divisions of ASME. The Journal is the premier international venue for publication of original research concerning mechanical vibration and sound. Our mission is to serve researchers and practitioners who seek cutting-edge theories and computational and experimental methods that advance these fields. Our published studies reveal how mechanical vibration and sound impact the design and performance of engineered devices and structures and how to control their negative influences. Vibration of continuous and discrete dynamical systems; Linear and nonlinear vibrations; Random vibrations; Wave propagation; Modal analysis; Mechanical signature analysis; Structural dynamics and control; Vibration energy harvesting; Vibration suppression; Vibration isolation; Passive and active damping; Machinery dynamics; Rotor dynamics; Acoustic emission; Noise control; Machinery noise; Structural acoustics; Fluid-structure interaction; Aeroelasticity; Flow-induced vibration and noise.