High-efficiency sound absorption by a nested and ventilated metasurface based on multi-slit synergetic resonance

Liu, Hongxing; Wu, Jiu Hui; Ma, Fuyin

doi:10.1088/1361-6463/abe6cd

Cited by 11 publications

(6 citation statements)

References 32 publications

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“…Muffler ducts are widely applied in gas emission and air exchange systems with fast flow rates [6], and as a key functional structure, the side-branch resonators are communicated through the main duct or slit channel for better performance of sound insulation and absorption [7][8][9]. Ducts with various side-branch Helmholtz resonator (HR) arrays, such as ringtype HRs [10,11], multi-order HRs [12][13][14], double-fishnet plates with HRs in the central layer [15], and circular HRs with shape modification, expand the attenuation bandwidth and transmission loss (TL) values [8,16,17].…”

Section: Introductionmentioning

confidence: 99%

A subwavelength ventilated structure for efficient broadband sound insulation

Hong

Sun

Tang

et al. 2023

J. Phys. D: Appl. Phys.

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Multifunctional structures such as ventilated sound barriers, have become the focus of recent research on the noise reduction and environmental comfort. However, its large size and complex inner structure hinder its potential applications. Novel structures with side-branch sectorial Helmholtz resonators (SHRs) and double-layered perforated slit plates enlightened by macro- perforated plates to enhance the soundproof performance and facilitate natural ventilation are proposed and experimentally validated. Compared with simple muffler ducts, the combinations with slit plates provide a smoother transmission loss (TL) curve with a broad and continuous TL band. We also study the influences of the independent parts and interactive effects of the assembly on the sound field, including the frequency migration and plate vibration. The proposed sub-wavelength structures with a thickness of 15mm can obtain TL values up to 25dB with a broad bandwidth from 930Hz to 1600Hz. Moreover, soundproof walls can be fabricated by using these structures with plenty of ventilated slits to freely exchange air and heat. This ventilation sound barrier is suitable for acoustic landscape buildings as it covers the main frequency spectrum of a human equal loudness contour.

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Section: Introductionmentioning

confidence: 99%

A subwavelength ventilated structure for efficient broadband sound insulation

Hong

Sun

Tang

et al. 2023

J. Phys. D: Appl. Phys.

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“…The development of metamaterial provides solutions for designing low-frequency absorbers with a sub-wavelength thickness. [13,14] The basic absorption metamaterial forms include Helmholtz resonators, [15][16][17] resonant membrane/plate structures, [18][19][20] Fabry-Pérot cavities, [12] slit-type absorbers, [21][22][23] and the combined or derived structures by these basic forms, [24][25][26][27][28][29][30][31][32][33] such as the widely used spacecoiling absorbers those combining from Helmholtz resonator and Fabry-Pérot cavity. [24][25][26][27][28] For the metamaterial and metasurface, the design method plays a really important role in achieving the excellent physical performance, especially for widening bandwidth and enhancing amplitude.…”

Section: Introductionmentioning

confidence: 99%

“…[24][25][26][27][28] For the metamaterial and metasurface, the design method plays a really important role in achieving the excellent physical performance, especially for widening bandwidth and enhancing amplitude. Several structural design methods are available for enhancing sound absorption performance or extending working bandwidth, including parallel synergistic coupling between multi-cells with gradient parameter distribution and weak coupling interaction between units, [12,16,17,19,21,22,34,35] increasing the number of resonance modes in a certain frequency band via the strong coupling interaction among the units to produce more absorption peaks, [18,33] parallel synergistic coupling between different types of soundabsorbing materials / structures, [29][30][31][32] and introducing artificial acoustic soft boundaries for reducing the sound reflection on the interface between the structure and air. [36,37] The most common and effective way to enhance the absorption performance is to use parallel superposition among weak coupling units, which could effectively broaden the working bandwidth to achieve the linear superposition.…”

Section: Introductionmentioning

confidence: 99%

Ultrathin Space‐Shift Phase‐Coherent Cancellation Metasurface for Broadband Sound Absorption

Ma,

Zhang,

Wang

et al. 2023

Small Methods

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A space‐shift phase‐coherent cancellation acoustic metasurface is developed, which can achieve broadband low‐frequency sound absorption via ultra‐thin integrated structure composed of multiple units with weak absorption capability. Through a space‐shift design of the channel length, the large‐size required in the thickness direction for low‐frequency absorption is transferred into an extremely ultra‐thin space layer. The units with gradient channel length are compactly arranged in an ultra‐thin layer through space folding, a coplanar sound absorption metasurface component with working bandwidth exceeding an octave and thickness of only λ/25 to λ/57 is obtained. As the construction of a special double‐hole “bridge” layout, even if the elements are sparsely distributed, strong coupling interactions between the units can sustain. When a certain local phase relationship is satisfied, the coherent cancellation of sound energy can be achieved, so as to reduce the sound reflection and scattering, and enhance the absorption performance. Therefore, from the perspective of phase relationship among units, the present work provides more clear physical image and intuitive theoretical explanation for achieving excellent broadband sound absorption through parallel superposition of multiple units with weak absorption capability. The proposed ultra‐thin sound absorbing metasurface can satisfy the thickness limitations and absorption performance requirements in most equipment.

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“…Based on the increasing demand of silent environments in daily life and industrial applications, research on broadband low-frequency sound absorption has been receiving more and more attention [1,2]. Conventional sound-absorbing materials, such as porous materials including sound-absorbing cotton and glass fiber [3,4], as well as micro-perforated panels [5], are usually effective in high-frequency sound absorption.…”

Section: Introductionmentioning

confidence: 99%

A compact low-frequency sound absorption metastructure realized by resonators with wavy bending necks

Zhang,

Song,

Wang

et al. 2023

J. Phys. D: Appl. Phys.

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In this work, a compact low-frequency sound absorption metastructure composed of multiple resonators with embedded wavy bending necks is proposed. By arranging this metastructure in parallel and optimizing the parameters, it exhibits excellent broadband sound absorption capability in low-frequency range and has a much more compact volume. Compared with the traditional resonators, an individual resonator of this metastructure can move down the absorption frequency about 120 Hz while maintaining the same thickness. Furthermore, different resonator units are combined into a sound absorption array by employing appropriate design techniques. We first built a small metastructure composed of four units to demonstrate the correctness and accuracy of our design method. Both theoretical models and finite element simulation models are built and experimental results show good agreement between them. To achieve the same absorption value and frequency range, the thickest resonator in the traditional resonator array must be 30% thicker than the one in the wavy bending neck resonator array, which means the overall size of the structure is 30% larger. Following this design method, perfect sound absorption within the frequency range of 248 Hz–420 Hz is achieved with a compact volume of 53 mm in radius and 47 mm in height. The design strategy presents a new approach to achieve perfect broadband low-frequency sound absorption.

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High-efficiency sound absorption by a nested and ventilated metasurface based on multi-slit synergetic resonance

Cited by 11 publications

References 32 publications

A subwavelength ventilated structure for efficient broadband sound insulation

A subwavelength ventilated structure for efficient broadband sound insulation

Ultrathin Space‐Shift Phase‐Coherent Cancellation Metasurface for Broadband Sound Absorption

A compact low-frequency sound absorption metastructure realized by resonators with wavy bending necks

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