Computational analysis of phononic crystal vibration isolators via FEM coupled with the acoustic black hole effect to attenuate railway-induced vibration

•The low-frequency multi-modal features of ABH rubber are applied to construct a novel phononic crystal vibration isolator.•The novel isolator increases the number of bandgaps and widens the bandgap.•A train–floating slab track–tunnel coupled dynamic model is established to investigate the vibration...

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Bibliographic Details
Published in:Construction & building materials 2021-05, Vol.283, p.122802, Article 122802
Main Authors: Zhao, Caiyou, Zheng, Junyuan, Sang, Tao, Wang, Liuchong, Yi, Qiang, Wang, Ping
Format: Article
Language:English
Subjects:
ABH
Bandgap
Floating slab track
Phononic crystal vibration isolator
Vibration isolation capability
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Summary:•The low-frequency multi-modal features of ABH rubber are applied to construct a novel phononic crystal vibration isolator.•The novel isolator increases the number of bandgaps and widens the bandgap.•A train–floating slab track–tunnel coupled dynamic model is established to investigate the vibration isolation capability. The problem of ambient vibration caused by urban rail transit continues to be serious, but it has not been satisfactorily resolved. This study investigates the structure of a novel phononic crystal vibration isolator (NPCVI) in which the low-frequency and multi-modal features of the acoustic black hole (ABH) structure are used to create coupling vibration between the ABH rubber and steel resonator. The bandgap is widened and the vibration isolation capability of the phononic crystal vibration isolator is optimized. By establishing a finite element model, the multi-bandgap behavior of the NPCVI is discussed, and its vibration isolation capability is demonstrated via studies of the force transmission spectrum. The energy distribution in the finite element model reveals the nature of multi-bandgap formation. Finally, a train–floating slab track–tunnel coupled dynamic model is established to investigate the vibration isolation capability of the NPCVI under the excitation of various track irregularities. The results demonstrate that, under various train speeds, the NPCVI exhibits a superior vibration isolation capability as compared to that of a steel-spring vibration isolator.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2021.122802