Enhancing wave retarding and sound absorption performances in perforation-modulated sonic black hole structures

IF 4.3 2区 工程技术 Q1 ACOUSTICS
Sihui Li, Xiang Yu, Li Cheng
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引用次数: 0

Abstract

Sonic black hole (SBH) effects in a retarding duct can be exploited for sound wave manipulation and absorption. The phenomenon relies on two fundamental physical mechanisms: wave speed reduction and energy dissipation. In this study, we demonstrate that these two physical processes can be meticulously balanced through adjusting the perforation parameters in a perforation-modulated SBH (PMSBH). To elucidate the mechanism of slow wave generation and the effect of perforation parameters, an analytic model based on the Wentzel-Kramers-Brillouin (WKB) solutions to the linear acoustic wave equation is established. Alongside transient finite element simulations, the study unveils the roles that major physical parameters play in terms of regulating sound speed and sound absorption. The perforation ratio of the PMSBH is identified as the dominant factor affecting the slow-sound effect, with an optimal range of above 10 % for a PMSBH with densely segmented internal rings. Owing to the inclusion of the perforated boundary, prominent slow wave effects can still be maintained even with a reduced number of rings, provided that the perforation ratio is properly chosen within a reduced variation range. In both cases, the identified perforation ratio largely exceeds the conventional range widely adopted in the micro-perforation community when the slow wave effects are absent. On top of this, tuning the hole size can further enhance air friction for better sound absorption. Theoretical and numerical findings are experimentally validated, and the performance of the PMSBH is demonstrated. While bringing forward the concept of tunable design, this study offers physical insights and guidance for realizing effective sound absorbers embracing slow wave principles and perforation-induced sound absorption.
增强穿孔调制声波黑洞结构的阻波和吸声性能
阻滞管道中的声波黑洞(SBH)效应可用于声波操纵和吸收。这种现象依赖于两种基本物理机制:波速降低和能量耗散。在本研究中,我们证明了这两个物理过程可以通过调整穿孔调制 SBH(PMSBH)中的穿孔参数来实现微妙的平衡。为了阐明慢波产生的机制和穿孔参数的影响,我们建立了一个基于线性声波方程的 Wentzel-Kramers-Brillouin (WKB) 解法的分析模型。通过瞬态有限元模拟,研究揭示了主要物理参数在调节声速和吸声方面的作用。PMSBH 的穿孔率被认为是影响慢声效应的主要因素,对于具有密集分段内环的 PMSBH 而言,最佳穿孔率范围在 10% 以上。由于包含了穿孔边界,即使环数减少,只要在较小的变化范围内适当选择穿孔率,仍能保持突出的慢波效应。在这两种情况下,当没有慢波效应时,所确定的穿孔率大大超出了微穿孔界广泛采用的常规范围。除此以外,调整孔径还能进一步增强空气摩擦力,从而获得更好的吸音效果。实验验证了理论和数值结果,并展示了 PMSBH 的性能。这项研究在提出可调设计概念的同时,还为实现包含慢波原理和穿孔吸声的有效吸声装置提供了物理见解和指导。
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来源期刊
Journal of Sound and Vibration
Journal of Sound and Vibration 工程技术-工程:机械
CiteScore
9.10
自引率
10.60%
发文量
551
审稿时长
69 days
期刊介绍: The Journal of Sound and Vibration (JSV) is an independent journal devoted to the prompt publication of original papers, both theoretical and experimental, that provide new information on any aspect of sound or vibration. There is an emphasis on fundamental work that has potential for practical application. JSV was founded and operates on the premise that the subject of sound and vibration requires a journal that publishes papers of a high technical standard across the various subdisciplines, thus facilitating awareness of techniques and discoveries in one area that may be applicable in others.
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