Plate-type acoustic metamaterials with integrated Helmholtz resonators

Plate-type acoustic metamaterials (PAM) consist of a thin film with periodically added masses. These metamaterials can be designed to be very lightweight and exhibit narrow bands at low frequencies with high sound transmission loss values that can exceed the corresponding mass-law considerably. In this paper, a new approach for improving the bandwidth of PAM by using Helmholtz resonators which rep-resent the added masses is investigated. The key principle of this design is that the Helmholtz resonance gives rise to an additional peak in the transmission loss spectrum which can be tuned to increase the bandwidth of the PAM. Sound transmission loss measurements of a large-scale test sample with 270 res-onators are used to demonstrate the performance of the proposed metamaterial under diffuse field exci-tation. Then, numerical simulations based on the finite element method are used to further investigate the physical mechanisms of the PAM with Helmholtz resonators. It is shown that when the baseplates of the Helmholtz resonators are stiff enough, the Helmholtz resonance is decoupled from the vibro-acoustics of the PAM. This can be exploited to effectively increase the bandwidth of PAM without any sig-nificant reductions of the sound transmission loss due to coupling resonances.(c) 2022 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

Automated summary

This paper investigates a new approach for improving the bandwidth of plate-type acoustic metamaterials (PAM) by using Helmholtz resonators. By adding Helmholtz resonators to PAM, the bandwidth of sound transmission loss can be increased without significant reductions in sound transmission loss.