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Mechanical vibration absorber for flexural wave attenuation in multi-materials metastructure

Authors
Liu, LongKim, Ji WanYoon, Gil HoYi, Bing
Issue Date
Mar-2024
Publisher
Elsevier BV
Keywords
Band gap; Composite sandwich; Flexural wave attenuation; Mechanical vibration; Metastructure; Phononic crystal
Citation
Composite Structures, v.331, pp 1 - 13
Pages
13
Indexed
SCIE
SCOPUS
Journal Title
Composite Structures
Volume
331
Start Page
1
End Page
13
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/197374
DOI
10.1016/j.compstruct.2023.117859
ISSN
0263-8223
1879-1085
Abstract
Vibration isolation is a promise to suppress mechanical vibration from a host structure, similarly, a mechanical vibration absorber, a simple but effective device to attenuate flexural wave propagation, which has been implemented in civil and mechanical engineering. This paper presents a type of composite sandwich phononic crystal to attenuate the flexural wave propagation in a beam structure, which can effectively suppress mechanical vibration in a broad band gap by repetitively arranging phononic crystal. First, the elastic wave dispersion characteristic in a composite sandwich beam structure is derived, and a triangular shape phononic crystal for flexural wave attenuation by taking advantage of destructive interference is presented. Then two dimensional phononic crystals are designed by assembling four different unit-cells of metabeam. Finally, numerical experiments are conducted to verify the effectiveness of the proposed mechanical metamaterial absorbers to attenuate flexural wave propagation, the numerical results indicate that the proposed metamaterial is of good performance in mechanical vibration suppression, which can effectively mitigate structure vibration in low-frequency domain than the structure without phononic crystal and single layer metamaterial beam structure. It is the first attempt to design a mechanical metamaterial absorber with the mechanism of destructive interference with composite sandwich phononic crystal.
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