A compact multifunctional metastructure for Low-frequency broadband sound absorption and crash energy dissipation

Sound absorption structures, as an effective approach to reducing sound radiation, have always received extensive attention in the engineering of vibration and noise reduction. In this work, a novel compact multifunctional metastructure is proposed for both low-frequency broadband sound absorption and excellent crash energy dissipation. Cavity resonators with internally extended tubes (CRIET) with hexagonal honeycomb configuration were selected as unit components. An optimization method was proposed to against degradation from impedance coupling effect and contribute to flatter and higher sound absorption coefficient (SAC) curves. The as-designed metastructure has been demonstrated experimentally to have quasi-perfect broadband sound absorption in the target range of 600-1000 Hz with an average SAC above 0.9 and a deep-subwavelength thickness of 30 mm. Compression experiment showed that the CRIET metastructure with hexagonal honeycomb configuration had the same unique excellent load-bearing and crash energy dissipation performance as an intact honeycomb structure. This study provides inspirations and methods for the compact and multifunctional design of broadband sound absorption structures. (C) 2022 Published by Elsevier Ltd.

Automated summary

In this study, a novel compact multifunctional metastructure was proposed for low-frequency broadband sound absorption and crash energy dissipation. The metastructure, consisting of cavity resonators with internally extended tubes with a hexagonal honeycomb configuration, was optimized to improve sound absorption performance. Experimental results showed that the designed metastructure achieved quasi-perfect broadband sound absorption and exhibited the same crash energy dissipation performance as an intact honeycomb structure. This study provides inspiration and methods for the compact and multifunctional design of broadband sound absorption structures.