Design and Acoustic Characterization of Microperforated Plate–Triply Periodic Minimal Surface Hybrid Acoustic Metamaterials

ZHANG Mingkang; LIU Wenbin; CHEN Jie; WANG Di; WANG Guanhao

doi:10.16080/j.issn1671-833x.25010070

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Design and Acoustic Characterization of Microperforated Plate–Triply Periodic Minimal Surface Hybrid Acoustic Metamaterials

更新时间：2026-03-27

- Design and Acoustic Characterization of Microperforated Plate–Triply Periodic Minimal Surface Hybrid Acoustic Metamaterials
- Aeronautical Manufacturing Technology Vol. 69, Issue 1/2, (2026)
- 作者机构：
  
  1. 广东海洋大学机械与能源工程学院,阳江,529500
  2. 广东省科学院智能制造研究所,广州,510000
  3. 华南理工大学机械与汽车工程学院,广州,510000
- 作者简介：
- 基金信息：
- DOI：10.16080/j.issn1671-833x.25010070
  CLC：
- Published：2026
- 稿件说明：
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ZHANG Mingkang, LIU Wenbin, CHEN Jie, et al. Design and Acoustic Characterization of Microperforated Plate–Triply Periodic Minimal Surface Hybrid Acoustic Metamaterials[J]. Aeronautical Manufacturing Technology, 2026, 69(1/2).
DOI：

ZHANG Mingkang, LIU Wenbin, CHEN Jie, et al. Design and Acoustic Characterization of Microperforated Plate–Triply Periodic Minimal Surface Hybrid Acoustic Metamaterials[J]. Aeronautical Manufacturing Technology, 2026, 69(1/2). DOI： 10.16080/j.issn1671-833x.25010070.

摘要

针对航空航天低频噪音问题，将微穿孔板（Microperforated plate，MPP）和三周期极小曲面（Triply periodic minimal surface，TPMS）进行复合设计获得MPP–TPMS 夹芯结构，实现了对中低频噪声的高效吸声，同时保持了轻量化与紧凑性优势。选用TPMS 结构中的Primitive 结构作为结构芯材，可通过设计穿孔板– 腔体单元，形成亥姆霍兹共振器阵列。基于微穿孔板吸声理论和Johnson–Champoux–Allard 等效流体理论，建立MPP–Primitive 夹芯结构的吸声理论模型，探究局部共振效应和热粘滞耗散机制在声波衰减中的耦合作用。利用熔融沉积成型（Fused deposition modeling，FDM）技术制备样品，采用声阻抗管测试和有限元仿真，探究了微穿孔板、Primitive 单元体尺寸、腔体厚度、MPP 孔径对吸声特性的影响。结果表明，MPP 结构与TPMS 结构的组合设计，激活了结构中亥姆霍兹共振腔吸声机制，大幅提升吸声特性，吸声频带向低频区域移动，吸声峰值接近1；通过增大Primitive 单元体尺寸，有效扩张共振腔体积，降低低频声阻抗，增强与低频声波声阻抗匹配，从而提升低频声波吸收效率；通过减小MPP 孔径，使吸声峰峰值得到提升并向低频迁移；增加Primitive 腔体厚度，延长声波传播路径，通过增强粘滞耗散与热传导效应将亥姆霍兹共振峰向低频迁移。这项工作为亚波长低频吸声MPP–TPMS 复合吸声超材料制备提供了设计参考。

Abstract

Aimed at low-frequency noise in aerospace applications

a micro-perforated plate (MPP) and a triply periodic minimal Surface (TPMS) was combined as a MPP–TPMS sandwich structure. This structure achieves efficient mid-to-low frequency sound absorption while maintaining advantages in lightweight design and compactness. The Primitive structure in the TPMS structure was selected as the structural core material

and a Helmholtz resonator array can be formed by designing a perforated plate-cavity unit. Based on microperforated plate sound absorption theory and Johnson-Champoux-Allard equivalent fluid theory

a theoretical sound absorption model of the MPP–Primitive sandwich structure was established to explore the coupling effect of local resonance effect and thermal viscous dissipation mechanism in sound wave attenuation. Samples were fabricated by fused deposition modeling (FDM) technology. The effects of MPP

unit cell size of Primitive

cavity thickness

and MPP aperture on the acoustic properties of the sandwich structure were systematically investigated through acoustic impedance tube tests and finite element simulations. The results demonstrate that the combination of MPP and TPMS activates the sound absorption mechanism of the Helmholtz resonance cavity and greatly improves the sound absorption characteristics

and the sound absorption frequency band moves towards the lowfrequency region

and the sound absorption peak is close to 1. Increasing the size of the Primitive effectively expands the volume of the resonance cavity

reduces the low-frequency acoustic impedance

and enhances the acoustic impedance matching with low-frequency sound waves

thereby improving the absorption efficiency of low-frequency sound waves. Reducing the MPP’s aperture and increasing the surface acoustic resistance of the structure effectively broadens the bandwidth of the sound absorption peak

greatly improving the peak value of the sound absorption and migrating it to low frequencies. Increasing the thickness of the primitive cavity

extending the sound wave propagation path

and migrating the Helmholtz resonance peak to low frequencies by enhancing viscous dissipation and heat conduction effects. This work provides support for the design of sub-wavelength low-frequency sound-absorbing MPP–TPMS composite sound-absorbing metamaterials.

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