Low-frequency sound insulation of thin plates

Purpose With the development of the modern technology and aerospace industry, the noise pollution is remarkably affecting people’s daily life and has been become a serious issue. Therefore, it is the most important task to develop efficient sound attenuation barriers, especially for the low-frequency audible range. However, low-frequency sound attenuation is usually difficult to achieve for the constraints of the conventional mass-density law of sound transmission. The traditional acoustic materials are reasonably effective at high frequency range. This paper aims to discuss this issue. Design/methodology/approach Membrane-type local resonant acoustic metamaterial is an ideal low-frequency sound insulation material for its structure is simple and lightweight. In this paper, the finite element method is used to study the low-frequency sound insulation performances of the coupled-membrane type acoustic metamaterial (CMAM). It consists of two identical tensioned circular membranes with fixed boundary. The upper membrane is decorated by a rigid platelet attached to the center. The sublayer membrane is attached with two weights, a central rigid platelet and a concentric ring with inner radius e. The influences of the distribution and number of the attached mass, also asymmetric structure on the acoustic attenuation characteristics of the CMAM, are discussed. Findings In this paper, the acoustic performance of asymmetric coupled-membrane metamaterial structure is discussed. The influences of mass number, the symmetric and asymmetry structure on the sound insulation performance are analyzed. It is shown that increasing the number of mass attached on membrane, structure exhibits low-frequency and multi-frequency acoustic insulation phenomenon. Compared with the symmetrical structure, asymmetric structure shows the characteristics of lightweight and multi-frequency sound insulation, and the sound insulation performance can be tuned by adjusting the distribution mode and location of mass blocks. Originality/value Membrane-type local resonant acoustic metamaterial is an ideal low-frequency sound insulation material for its structure is simple and lightweight. How to effectively broaden the acoustic attenuation band at low frequency is still a problem. But most of researchers focus on symmetric structures. In this study, the asymmetric coupled-membrane acoustic metamaterial structure is examined. It is demonstrated that the asymmetric structure has better sound insulation performances than symmetric structure.

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Enhancement of low-frequency sound insulation using piezoelectric resonators

Journal of the Brazilian Society of Mechanical Sciences and Engineering ◽

10.1007/s40430-013-0034-x ◽

2013 ◽

Vol 35 (4) ◽

pp. 357-367 ◽

Cited By ~ 1

Author(s):

Téo L. Rocha ◽

Márcio Calçada ◽

Yuri A. Ribeiro Silva

Keyword(s):

Low Frequency ◽

Sound Insulation ◽

Frequency Sound ◽

Piezoelectric Resonators

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Low-Frequency, Open, Sound-Insulation Barrier by Two Oppositely Oriented Helmholtz Resonators

Micromachines ◽

10.3390/mi12121544 ◽

2021 ◽

Vol 12 (12) ◽

pp. 1544

Author(s):

Yi-Jun Guan ◽

Yong Ge ◽

Hong-Xiang Sun ◽

Shou-Qi Yuan ◽

Xiao-Jun Liu

Keyword(s):

High Performance ◽

Low Frequency ◽

Single Layer ◽

Sound Insulation ◽

Architectural Acoustics ◽

Frequency Sound ◽

Helmholtz Resonators ◽

Viscous Loss ◽

Insulation Effect ◽

Broadband Sound

In this work, a low-frequency, open, sound-insulation barrier, composed of a single layer of periodic subwavelength units (with a thickness of λ/28), is demonstrated both numerically and experimentally. Each unit was constructed using two identical, oppositely oriented Helmholtz resonators, which were composed of a central square cavity surrounded by a coiled channel. In the design of the open barrier, the distance between two adjacent units was twice the width of the unit, showing high-performance ventilation, and low-frequency sound insulation. A minimum transmittance of 0.06 could be observed around 121.5 Hz, which arose from both sound reflections and absorptions, created by the coupling of symmetric and asymmetric eigenmodes of the unit, and the absorbed sound energy propagating into the central cavity was greatly reduced by the viscous loss in the channel. Additionally, by introducing a multilayer open barrier, a broadband sound insulation was obtained, and the fractional bandwidth could reach approximately 0.19 with four layers. Finally, the application of the multilayer open barrier in designing a ventilated room was further discussed, and the results presented an omnidirectional, broadband, sound-insulation effect. The proposed open, sound-insulation barrier with the advantages of ultrathin thickness; omnidirectional, low-frequency sound insulation; broad bandwidth; and high-performance ventilation has great potential in architectural acoustics and noise control.

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Quantitative analysis of low frequency acoustic characteristics for reverse horn by bottleneck effect analogy method

Modern Physics Letters B ◽

10.1142/s021798491950177x ◽

2019 ◽

Vol 33 (16) ◽

pp. 1950177

Author(s):

Xiao Liang ◽

Jiu Hui Wu ◽

Zhuo Zhou ◽

Zhe Chen

Keyword(s):

Quantitative Analysis ◽

Acoustic Waves ◽

Low Frequency ◽

Sound Insulation ◽

Simple Method ◽

Acoustic Characteristics ◽

Bottleneck Effect ◽

Sound Energy ◽

Frequency Sound ◽

Theoretical Results

Reverse horn as one of the Acoustic Black Hole (ABH) structures can be used to effectively reduce low frequency acoustic waves by focusing the sound energy. The sound waves in relatively low frequency range are focused on the tip of reverse horn, and most sound energy cannot flow out from the reverse horn’s tip. In this paper, we propose a quantitative analysis method by the bottleneck effect analogy to research the low frequency acoustic characteristics of reverse horn. Our theoretical results show that the low frequency sound wave can be focused on the tip of reverse horn, and the transmission coefficient of low frequency is proportional to the 3 power law of the reverse horn tip’s diameter. The experimental results verified our theoretical results. And the sound insulation property is studied by experiments. It is noteworthy that the insulation coefficient of two levels reverse horn whose second level tip’s diameter [Formula: see text] mm, is more than 0.92, and can increase further with the decrease of the second level horn tip’s diameter. It provides an effective and simple method for quantitatively analyzing the low frequency acoustic characteristics of the reverse horn. The proposed reverse horn has great potential applications for low frequency sound insulation control.

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Light-weight large-scale tunable metamaterial panel for low-frequency sound insulation

Applied Physics Express ◽

10.35848/1882-0786/ab916b ◽

2020 ◽

Vol 13 (6) ◽

pp. 067003

Author(s):

Hao Zhang ◽

Shengbing Chen ◽

Zongzheng Liu ◽

Yubao Song ◽

Yong Xiao

Keyword(s):

Large Scale ◽

Low Frequency ◽

Sound Insulation ◽

Light Weight ◽

Frequency Sound ◽

Tunable Metamaterial

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An Optimization Method for Maximizing the Low Frequency Sound Insulation of Plate Structures

Shock and Vibration ◽

10.1155/2018/7849327 ◽

2018 ◽

Vol 2018 ◽

pp. 1-8 ◽

Cited By ~ 1

Author(s):

Dayi Ou

Keyword(s):

Genetic Algorithm ◽

Boundary Conditions ◽

Low Frequency ◽

Sound Transmission ◽

Sound Insulation ◽

Plate Structures ◽

Arbitrary Boundary ◽

Frequency Sound ◽

Arbitrary Boundary Conditions ◽

Element Method

A combined approach based on finite element method, boundary element method, and genetic algorithm (FEM-BEM-GA) is proposed for optimizing the low frequency sound (LFS) insulation performance of plate structures. This approach can identify the optimal structural parameters (especially concerning the effects of arbitrary boundary conditions) so as to maximize the structural overall LFS insulation. The basic ideas of this approach are as follows: (1) the sound transmission loss (TL) analysis of a plate with arbitrary boundary conditions is conducted by the coupled FEM-BEM method; (2) the single-number rating method (such as low frequency sound transmission class) is used to assess the plate’s overall LFS insulation; and (3) the genetic algorithm (GA) is employed for searching the optimal solutions of the multiple-parameter optimization problem. The proposed approach is subsequently illustrated by numerical studies. The results show the effectiveness of consideration of the effects of boundary condition in the plate’s LFS insulation optimization and demonstrate the feasibility and effectiveness of this approach as a structure design tool.

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Study on low frequency sound insulation characteristic of thin acoustic black hole

Modern Physics Letters B ◽

10.1142/s0217984921501980 ◽

2021 ◽

pp. 2150198

Author(s):

Xiao Lian ◽

Shengsheng Wang ◽

Maolin Liu ◽

Songhui Nie ◽

Jinfeng Peng ◽

...

Keyword(s):

Black Hole ◽

Acoustic Waves ◽

Transmission Loss ◽

Low Frequency ◽

Sound Insulation ◽

Focusing Effect ◽

Frequency Sound ◽

Leading Role ◽

Potential Applications ◽

Energy Focusing

We use numerical and experimental methods to investigate the low frequency sound insulation characteristic of designed thin acoustic black hole (ABH). The numerical results show that the sound energy focusing effect plays a leading role in low frequency sound insulation of designed ABH, and the reflection at the edge of ABH is the main reason of sound insulation in medium and high frequencies. Experimental results display that the Sound Transmission Loss (STL) of the designed ABH is higher than 30 dB below 700 Hz, which shows that the isolated acoustic waves are more than 95%. The low frequency sound insulation performance of proposed ABHs is much better than the traditional acoustic materials, which has great potential applications for low frequency sound insulation.

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