Improving sound insulation in low frequencies by multiple band-gaps in plate-type acoustic metamaterials

Low- and medium-frequency noise from ship cabins is difficult to control effectively. Excessive noise can seriously affect the acoustic stealth performance of ships. A novel membrane-type acoustic metamaterial is proposed in this paper with light weight and good sound insulation performance at low frequencies. The sound insulation performance of the metamaterial structure is analysed by using the acoustic-solid coupling module in COMSOL software. Then, the ability to change the sound insulation performance of membrane-type acoustic metamaterials with cell structure and material parameters is obtained. The research results in this paper provide powerful technical support for noise control in ship cabins.

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Multi-mass synergetic coupling perforated bi-layer plate-type acoustic metamaterials for sound insulation

International Journal of Modern Physics B ◽

10.1142/s0217979220501362 ◽

2020 ◽

Vol 34 (13) ◽

pp. 2050136

Author(s):

Weikang Huang ◽

Tianning Chen ◽

Quanyuan Jiang ◽

Xinpei Song ◽

Wuzhou Yu ◽

...

Keyword(s):

Structural Parameters ◽

Perforated Plate ◽

Low Frequency ◽

Sound Insulation ◽

Frequency Noise ◽

Acoustic Metamaterials ◽

Practical Engineering ◽

Broadband Sound ◽

Insulation Performance ◽

Plate Type

Thin plate-type acoustic metamaterials have the advantages of lightweight, high rigidity and adjustable parameters, showing great practical application values in sound wave control. In this paper, a type of perforated bi-layer plate-type acoustic metamaterials (PBPAM) is designed for low-frequency noise control. The sound insulation peaks can be increased by combining the perforated plate and synergetic masses, making the sound insulation performance close to the mass law at the resonant frequency. Compared to the results predicted by the mass law, a better performance of sound insulation is achieved based on the PBPAM. The effects of the structural parameters are investigated in this study. Based on the impedance tube experiments, the measured results have a good agreement with the simulated ones. This work can provide a reference for low-frequency and broadband sound insulation based on plate-type acoustic metamaterials in practical engineering.

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Multilevel plate-type acoustic metamaterials with level-to-level modal antiresonance for sound insulation

Journal of Physics D Applied Physics ◽

10.1088/1361-6463/ac3bf3 ◽

2021 ◽

Author(s):

Yingrui Ye ◽

Xiaopeng Wang ◽

Bo Zhang ◽

Tianning Chen

Keyword(s):

Large Scale ◽

Transmission Loss ◽

Sound Insulation ◽

Acoustic Metamaterials ◽

Aircraft Cabins ◽

Actual Application ◽

Out Of Plane ◽

The Masses ◽

Application Requirements ◽

Plate Type

Abstract With the goal of engineering applications, the scalability of the plate-type acoustic metamaterials (PAMs) is significant. However, most of the designed large-scale PAMs are formed by extending a single PAM cell to an array of cells, which will inevitably introduce the vibroacoustic behavior of the entire array structure, resulting in the decay of the sound transmission loss (STL) performance in certain frequency bands. To overcome this weakness, we present a new conceptual design of multilevel PAM to enhance STL performance again by considering level-to-level modal antiresonance. The modal antiresonance of the second-level PAM, which manifests itself as the coupling through out-of-plane vibration of the first- and second-level PAMs, is analyzed to reveal the physical mechanisms. In addition, we also find that the STL profile of the second-level PAM has different dependence on the masses placed on the PAM cell and PAM array. We theoretically design and experimentally demonstrate the sound insulation properties of the proposed second-level PAM. Since the configuration of the multilevel PAM can be easily and flexibly designed in accordance with actual application requirements, it has broad application prospects including but not limiting to submarine shells, aircraft cabins, transformer rooms.

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Plate-type metamaterials for extremely broadband low-frequency sound insulation

International Journal of Modern Physics B ◽

10.1142/s0217979218500194 ◽

2018 ◽

Vol 32 (03) ◽

pp. 1850019 ◽

Cited By ~ 3

Author(s):

Xiaopeng Wang ◽

Xinwei Guo ◽

Tianning Chen ◽

Ge Yao

Keyword(s):

Transmission Loss ◽

Structural Parameters ◽

Low Frequency ◽

Thin Plates ◽

Sound Insulation ◽

Frequency Noise ◽

Low Frequencies ◽

Acoustic Metamaterial ◽

Unit Cells ◽

Plate Type

A novel plate-type acoustic metamaterial with a high sound transmission loss (STL) in the low-frequency range ([Formula: see text]1000 Hz) is designed, theoretically proven and then experimentally verified. The thin plates with large modulus used in this paper mean that we do not need to apply tension to the plates, which is more applicable to practical engineering, the achievement of noise reduction is better and the installation of plates is more user-friendly than that of the membranes. The effects of different structural parameters of the plates on the sound-proofed performance at low-frequencies were also investigated by experiment and finite element method (FEM). The results showed that the STL can be modulated effectively and predictably using vibration theory by changing the structural parameters, such as the radius and thickness of the plate. Furthermore, using unit cells of different geometric sizes which are responsible for different frequency regions, the stacked panels with thickness [Formula: see text]16 mm and weight [Formula: see text]5 kg/m2 showed high STL below 2000 Hz. The acoustic metamaterial proposed in this study could provide a potential application in the low-frequency noise insulation.

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Study on broadband low-frequency sound insulation of multi-channel resonator acoustic metamaterials

AIP Advances ◽

10.1063/5.0047416 ◽

2021 ◽

Vol 11 (4) ◽

pp. 045321

Author(s):

Chi Xu ◽

Hui Guo ◽

Yinghang Chen ◽

Xiaori Dong ◽

Hongling Ye ◽

...

Keyword(s):

Low Frequency ◽

Sound Insulation ◽

Acoustic Metamaterials ◽

Frequency Sound

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Prediction of Sound Insulation at Low Frequencies Using Artificial Neural Networks

Building Acoustics ◽

10.1260/135101002761035735 ◽

2002 ◽

Vol 9 (1) ◽

pp. 49-71 ◽

Cited By ~ 2

Author(s):

Anna Fora-Moncada ◽

Barry Gibbs

Keyword(s):

Neural Networks ◽

Artificial Neural Networks ◽

Sound Insulation ◽

Low Frequencies ◽

Artificial Neural

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Tunable Band Gaps of Acoustic Waves in Two-Dimensional Phononic Crystals With Reticular Band Structures

Volume 15: Sound, Vibration and Design ◽

10.1115/imece2009-13102 ◽

2009 ◽

Cited By ~ 1

Author(s):

Zi-Gui Huang ◽

Yunn-Lin Hwang ◽

Pei-Yu Wang ◽

Yen-Chieh Mao

Keyword(s):

Acoustic Waves ◽

Composite Structures ◽

Phononic Crystals ◽

Band Gaps ◽

Sound Insulation ◽

Two Dimensional ◽

The Finite Element Method ◽

Elastic Band ◽

Band Structures ◽

Elastic Band Gaps

The excellent applications and researches of so-called photonic crystals raise the exciting researches of phononic crystals. By the analogy between photon and phonon, repetitive composite structures that are made up of different elastic materials can also prevent elastic waves of some certain frequencies from passing by, i.e., the frequency band gap features also exist in acoustic waves. In this paper, we present the results of the tunable band gaps of acoustic waves in two-dimensional phononic crystals with reticular band structures using the finite element method. Band gaps variations of the bulk modes due to different thickness and angles of reticular band structures are calculated and discussed. The results show that the total elastic band gaps for mixed polarization modes can be enlarged or reduced by adjusting the orientation of the reticular band structures. The phenomena of band gaps of elastic or acoustic waves can potentially be utilized for vibration-free, high-precision mechanical systems, and sound insulation.

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Sound Insulation at Low Frequencies

The Journal of the Acoustical Society of America ◽

10.1121/1.1981779 ◽

1972 ◽

Vol 52 (1A) ◽

pp. 119-119

Author(s):

K. A. Mulholland ◽

R. H. Lyon

Keyword(s):

Sound Insulation ◽

Low Frequencies

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Bridging-Coupling Band Gaps in Nonlinear Acoustic Metamaterials

Physical Review Applied ◽

10.1103/physrevapplied.10.054049 ◽

2018 ◽

Vol 10 (5) ◽

Cited By ~ 6

Author(s):

Xin Fang ◽

Jihong Wen ◽

Dianlong Yu ◽

Jianfei Yin

Keyword(s):

Band Gaps ◽

Acoustic Metamaterials ◽

Nonlinear Acoustic

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Demultiplexing Infrasound Phonons With Tunable Magnetic Lattices

Frontiers in Materials ◽

10.3389/fmats.2020.606877 ◽

2020 ◽

Vol 7 ◽

Author(s):

Audrey A. Watkins ◽

Osama R. Bilal

Keyword(s):

Self Assembly ◽

Small Volume ◽

Low Frequency ◽

Acoustic Metamaterials ◽

Propagation Characteristics ◽

Low Frequencies ◽

Experimental Realization ◽

Nonlinear Properties ◽

Potential Applications ◽

Low Frequency Waves

Controlling infrasound signals is crucial to many processes ranging from predicting atmospheric events and seismic activities to sensing nuclear detonations. These waves can be manipulated through phononic crystals and acoustic metamaterials. However, at such ultra-low frequencies, the size (usually on the order of meters) and the mass (usually on the order of many kilograms) of these materials can hinder its potential applications in the infrasonic domain. Here, we utilize tunable lattices of repelling magnets to guide and sort infrasound waves into different channels based on their frequencies. We construct our lattices by confining meta-atoms (free-floating macroscopic disks with embedded magnets) within a magnetic boundary. By changing the confining boundary, we control the meta-atoms’ spacing and therefore the intensity of their coupling potentials and wave propagation characteristics. As a demonstration of principle, we present the first experimental realization of an infrasound phonon demultiplexer (i.e., guiding ultra-low frequency waves into different channels based on their frequencies). The realized platform can be utilized to manipulate ultra-low frequency waves, within a relatively small volume, while utilizing negligible mass. In addition, the self-assembly nature of the meta-atoms can be key in creating re-programmable materials with exceptional nonlinear properties.

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