TY - GEN
T1 - Sound absorption enhancement of metamaterial-based micro-perforated panels with mass-cantilever resonators
AU - Shuwei, Ren
AU - Xiangyang, Zeng
AU - Haitao, Wang
AU - Ye, Lei
N1 - Publisher Copyright:
© Proceedings of the 26th International Congress on Sound and Vibration, ICSV 2019. All rights reserved.
PY - 2019
Y1 - 2019
N2 - Metamaterial-based micro-perforated panels (MMPPs) were proposed by adding local resonators (LRs) upon one face of a conventional flexible micro-perforated panel (FMPP). Mass-cantilever resonant structures are adopted as LRs here, and they are separated on a sub-wavelength scale. Through theoretical and numerical analyzing, MMPPs are proved able to enhance sound absorption in the stop bands caused by local resonances. Specifically, the theoretical model is developed based on effective medium method, as the distance between the LRs is much smaller than the structural wavelength in the host panel (i.e. FMPP) in the considered frequency range. The full-size simulation model is conducted by utilizing the commercial software COMSOL, considering all the multi-physical couplings among the fluid and solid domains. Good agreement is achieved between the theoretical predictions and the simulation results, for both the FMPPs and MMPPs. Physically, the theoretical and numerical models reveal that the sound absorption enhancement mechanism stems from the resulted additional phase shift, and the enlarged divergence between the average velocity of the air particles inside the perforations and that of the panel attached with LRs.
AB - Metamaterial-based micro-perforated panels (MMPPs) were proposed by adding local resonators (LRs) upon one face of a conventional flexible micro-perforated panel (FMPP). Mass-cantilever resonant structures are adopted as LRs here, and they are separated on a sub-wavelength scale. Through theoretical and numerical analyzing, MMPPs are proved able to enhance sound absorption in the stop bands caused by local resonances. Specifically, the theoretical model is developed based on effective medium method, as the distance between the LRs is much smaller than the structural wavelength in the host panel (i.e. FMPP) in the considered frequency range. The full-size simulation model is conducted by utilizing the commercial software COMSOL, considering all the multi-physical couplings among the fluid and solid domains. Good agreement is achieved between the theoretical predictions and the simulation results, for both the FMPPs and MMPPs. Physically, the theoretical and numerical models reveal that the sound absorption enhancement mechanism stems from the resulted additional phase shift, and the enlarged divergence between the average velocity of the air particles inside the perforations and that of the panel attached with LRs.
KW - Metamaterial
KW - MPP
KW - Sound absorption enhancement
KW - Velocity ratio
UR - http://www.scopus.com/inward/record.url?scp=85084012955&partnerID=8YFLogxK
M3 - 会议稿件
AN - SCOPUS:85084012955
T3 - Proceedings of the 26th International Congress on Sound and Vibration, ICSV 2019
BT - Proceedings of the 26th International Congress on Sound and Vibration, ICSV 2019
PB - Canadian Acoustical Association
T2 - 26th International Congress on Sound and Vibration, ICSV 2019
Y2 - 7 July 2019 through 11 July 2019
ER -