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Active feedforward control of flexural waves in an Acoustic Black Hole terminated beam

Active feedforward control of flexural waves in an Acoustic Black Hole terminated beam
Active feedforward control of flexural waves in an Acoustic Black Hole terminated beam
Acoustic Black Holes (ABHs) are structural features that are typically realised by introducing a tapering thickness profile into a structure that results in local regions of wave-speed reduction and a corresponding enhancement in the structural damping. In the ideal theoretical case, where the ABH tapers to zero thickness, the wave-speed reaches zero and the wave entering the ABH can be perfectly absorbed. In practical realisations, however, the thickness of the ABH taper and thus the wave-speed remain finite. In this case, to obtain high levels of structural damping, the ABH is typically combined with a passive damping material, such as a viscoelastic layer. This paper investigates the potential performance enhancements that can be achieved by replacing the complementary passive damping material with an Active Vibration Control (AVC) system in a beam-based ABH, thus creating an Active ABH (AABH). The proposed smart structure thus consists of a piezo-electric patch actuator, which is integrated into the ABH taper in place of the passive damping, and a wave-based, feedforward AVC strategy, which aims to minimise the broadband flexural wave reflection coefficient. To evaluate the relative performance of the proposed AABH, an identical AVC strategy is also applied to a beam with a constant thickness termination. It is demonstrated through experimental implementation, that the AABH is able to achieve equivalent broadband performance to the constant thickness beam-based AVC system, but with a lower computational requirement and a lower control effort, thus offering significant practical benefits.
Acoustic Black Hole, Active control, Reflection coefficient
0964-1726
Cheer, Jordan
8e452f50-4c7d-4d4e-913a-34015e99b9dc
Hook, Kristian
6c9b8a1f-84fe-4560-9138-89cf5e8f4c4b
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Cheer, Jordan
8e452f50-4c7d-4d4e-913a-34015e99b9dc
Hook, Kristian
6c9b8a1f-84fe-4560-9138-89cf5e8f4c4b
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6

Cheer, Jordan, Hook, Kristian and Daley, Stephen (2021) Active feedforward control of flexural waves in an Acoustic Black Hole terminated beam. Smart Materials and Structures, 30 (3), [035003]. (doi:10.1088/1361-665X/abd90f).

Record type: Article

Abstract

Acoustic Black Holes (ABHs) are structural features that are typically realised by introducing a tapering thickness profile into a structure that results in local regions of wave-speed reduction and a corresponding enhancement in the structural damping. In the ideal theoretical case, where the ABH tapers to zero thickness, the wave-speed reaches zero and the wave entering the ABH can be perfectly absorbed. In practical realisations, however, the thickness of the ABH taper and thus the wave-speed remain finite. In this case, to obtain high levels of structural damping, the ABH is typically combined with a passive damping material, such as a viscoelastic layer. This paper investigates the potential performance enhancements that can be achieved by replacing the complementary passive damping material with an Active Vibration Control (AVC) system in a beam-based ABH, thus creating an Active ABH (AABH). The proposed smart structure thus consists of a piezo-electric patch actuator, which is integrated into the ABH taper in place of the passive damping, and a wave-based, feedforward AVC strategy, which aims to minimise the broadband flexural wave reflection coefficient. To evaluate the relative performance of the proposed AABH, an identical AVC strategy is also applied to a beam with a constant thickness termination. It is demonstrated through experimental implementation, that the AABH is able to achieve equivalent broadband performance to the constant thickness beam-based AVC system, but with a lower computational requirement and a lower control effort, thus offering significant practical benefits.

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Accepted/In Press date: 6 January 2021
e-pub ahead of print date: 29 January 2021
Published date: 29 January 2021
Additional Information: Funding Information: This work was supported by an EPSRC iCASE studentship (Voucher Number 16000058) and the Intelligent Structures for Low Noise Environments (ISLNE) EPSRC Prosperity Partnership(EP/S03661X/1). Publisher Copyright: © 2021 The Author(s). Published by IOP Publishing Ltd Copyright: Copyright 2021 Elsevier B.V., All rights reserved.
Keywords: Acoustic Black Hole, Active control, Reflection coefficient

Identifiers

Local EPrints ID: 446751
URI: http://eprints.soton.ac.uk/id/eprint/446751
ISSN: 0964-1726
PURE UUID: d03d965e-8d2b-4b12-8d12-0a89e66f286b
ORCID for Jordan Cheer: ORCID iD orcid.org/0000-0002-0552-5506
ORCID for Kristian Hook: ORCID iD orcid.org/0000-0002-5011-0414

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Date deposited: 19 Feb 2021 17:33
Last modified: 30 Nov 2024 02:46

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Contributors

Author: Jordan Cheer ORCID iD
Author: Kristian Hook ORCID iD
Author: Stephen Daley

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