A low frequency underwater metastructure composed by helix metal and viscoelastic damping rubber

Nansha Gao; Yongyan Zhang

doi:10.1177/1077546318788446

A low frequency underwater metastructure composed by helix metal and viscoelastic damping rubber

Nansha Gao, Yongyan Zhang

School of Marine Science and Technology

Xi'an Jiaotong University

Research output: Contribution to journal › Article › peer-review

103 Scopus citations

Abstract

We report an underwater metastructure with excellent acoustic absorption that is constructed by perforating a helix structure into viscoelastic damping rubber. Finite element method results show that this metastructure can achieve the low frequency and broadband acoustic absorption below 1000 Hz. Waveform transformation, multiple scattering, and reflection energy dissipation mechanisms are the critical factors affecting the absorption performance. Different geometries and materials of the helix structure can adjust the acoustic absorption to a great extent. The proposed metastructure provides more possibilities for underwater acoustic manipulation applications.

Original language	English
Pages (from-to)	538-548
Number of pages	11
Journal	JVC/Journal of Vibration and Control
Volume	25
Issue number	3
DOIs	https://doi.org/10.1177/1077546318788446
State	Published - 1 Feb 2019

Keywords

energy dissipation mechanism
helix metastructure
Low frequency acoustic absorption
sub-wavelength scale
waveform transformation

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abstract = "We report an underwater metastructure with excellent acoustic absorption that is constructed by perforating a helix structure into viscoelastic damping rubber. Finite element method results show that this metastructure can achieve the low frequency and broadband acoustic absorption below 1000 Hz. Waveform transformation, multiple scattering, and reflection energy dissipation mechanisms are the critical factors affecting the absorption performance. Different geometries and materials of the helix structure can adjust the acoustic absorption to a great extent. The proposed metastructure provides more possibilities for underwater acoustic manipulation applications.",

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AB - We report an underwater metastructure with excellent acoustic absorption that is constructed by perforating a helix structure into viscoelastic damping rubber. Finite element method results show that this metastructure can achieve the low frequency and broadband acoustic absorption below 1000 Hz. Waveform transformation, multiple scattering, and reflection energy dissipation mechanisms are the critical factors affecting the absorption performance. Different geometries and materials of the helix structure can adjust the acoustic absorption to a great extent. The proposed metastructure provides more possibilities for underwater acoustic manipulation applications.

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KW - sub-wavelength scale

KW - waveform transformation

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A low frequency underwater metastructure composed by helix metal and viscoelastic damping rubber

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