Forming Low-Frequency Complete Vibration Bandgaps in a thin Nonmetallic Elastic Metamaterial Plate

Low-frequency vibration-bandgaps in elastic metamaterials open new possibilities to minimize low-frequency vibration and noise. Unfortunately, fabricating a complete vibration bandgap for low frequencies still represents a challenging engineering task. In this paper, a new type of a low-frequency co...

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Bibliographic Details
Published in:Acoustical physics 2019-05, Vol.65 (3), p.322-333
Main Authors: Suobin Li, Dou, Yihua, Chen, Tianning, Wan, Zhiguo, Ju, Luyan, Zhang, Fan, Cui, Xiao Xiao
Format: Article
Language:English
Subjects:
Acoustics
Coupling
Decoupling
Elastic waves
Energy gap
Fillers
Finite element method
Frequency ranges
Mass-spring systems
Metamaterials
Mode superposition method
Noise reduction
Physical Fundamentals of Engineering Acoustics
Physics
Physics and Astronomy
Resonators
Rubber
Vibration control
Vibration damping
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Summary:Low-frequency vibration-bandgaps in elastic metamaterials open new possibilities to minimize low-frequency vibration and noise. Unfortunately, fabricating a complete vibration bandgap for low frequencies still represents a challenging engineering task. In this paper, a new type of a low-frequency complete vibration bandgap in a thin non-metal elastic metamaterial plate is introduced and investigated numerically. The proposed elastic metamaterial plate consists of decoupling-resonators, which are deposited on a 2D, locally resonant phononic-crystal plate, made of an array of rubber fillers, which are embedded in a nonmetallic plate. The dispersion relationship, the power-transmission spectrum, and the displacement fields for the eigenmode are calculated using the finite element method. It is shown that coupling between the local resonance mode of the decoupling-resonators and the Lamb-wave mode of the epoxy plate, consistent with the modal superposition principle, is responsible for the formation of vibration bandgaps. Moreover, the equivalent spring-mass system for the coupling-resonators can be decoupled by introducing a rubber filler. In addition, both longitudinal and the transverse elastic wave bandgaps can be tuned to the same low-frequency range. As a result, a novel kind of low-frequency complete vibration bandgap, which can damp a low-frequency elastic wave, is produced. Furthermore, the effects of the decoupling-resonators on the vibration bandgap are investigated. It is now possible that an elastic metamaterial plate can be dampen with complete low-frequency vibration bandgaps, which can potentially be used for commercial noise and vibration reduction .
ISSN:1063-7710
1562-6865
DOI:10.1134/S1063771019030084