4.7 Article

Design, manufacture, and characterisation of hierarchical metamaterials for simultaneous ultra-broadband sound-absorbing and superior mechanical performance

期刊

VIRTUAL AND PHYSICAL PROTOTYPING
卷 18, 期 1, 页码 -

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TAYLOR & FRANCIS LTD
DOI: 10.1080/17452759.2022.2111585

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Additive manufacturing technologies; ultra-broad half-absorption band; the unique resonant responses; specific energy absorption

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This paper proposes a hierarchical metamaterial that can absorb both sound and mechanical energy by modulating its structural features. The material has an increasing absorption bandwidth and can absorb energy at different frequencies. The unique resonant responses of the material are demonstrated through analysis and experiments, and the enhancement mechanism is revealed. Compared to the original material, the hierarchical metamaterial shows significantly improved specific energy absorption.
For engineering applications, sound-absorbing materials are supposed to withstand potential impact loading conditions. However, there is a lack of attempts on multifunctional metamaterials for both acoustic and mechanical purposes. Herein, a hierarchical metamaterial manufactured by fused deposition modelling (FDM) that exhibits simultaneous acoustic and mechanical energy-absorbing capacities is proposed in this work. The metamaterial obtains a successively increasing absorption bandwidth with the growth of the hierarchical order. Ultra-broad half-absorption band from 0.96 to 6.00 kHz is obtained for the fourth order. The unique resonant responses are demonstrated analytically, numerically, and experimentally via properly modulating the structural features. The enhancement mechanism is physically revealed by analysing the impedance matching and resonant damping states. Moreover, compared with its original counterpart, the specific energy absorption (SEA) of the first-order and the second-order hierarchical metamaterials increases by 228% and 434%, respectively. This work provides an effective approach for designing multifunctional metamaterials.

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