Active control of an acoustic black hole using a feedback strategy
Active control of an acoustic black hole using a feedback strategy
Acoustic black holes (ABHs) are tapered structural features that can achieve high levels of structural damping within lightweight constraints. It has previously been proposed to integrate feedforward active vibration control into an ABH to enable control over a broad spectrum, however, the time-advanced information required in this control strategy is not always available. In addition, it has been shown that controlling the reflection coefficient in a beam-based ABH leads to an undesirable enhancement of the taper vibration. In this paper, a feedback control strategy is applied to an ABH terminated beam, with a piezoelectric patch providing the control actuation. The feedback strategy is a remote vibration control methodology and is used to examine the different compensators that are potentially available to control simultaneously both the local taper vibration and the reflected wave component. The investigation highlights that the taper vibration can be minimised without affecting the reflected wave, however, apart from a few isolated frequencies, it is shown that the reflected wave cannot be minimised without increasing the taper vibration relative to the passive case. Importantly, since the approach enables the passive ABH performance to be maintained whilst simultaneously minimising the vibration in the tip, the fatigue life of the structure can potentially be extended with the addition of the active control loop.
Acoustic black hole, Active control, Feedback, Remote damping
Hook, Kristian
6c9b8a1f-84fe-4560-9138-89cf5e8f4c4b
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Cheer, Jordan
8e452f50-4c7d-4d4e-913a-34015e99b9dc
23 June 2022
Hook, Kristian
6c9b8a1f-84fe-4560-9138-89cf5e8f4c4b
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Cheer, Jordan
8e452f50-4c7d-4d4e-913a-34015e99b9dc
Hook, Kristian, Daley, Stephen and Cheer, Jordan
(2022)
Active control of an acoustic black hole using a feedback strategy.
Journal of Sound and Vibration, 528, [116895].
(doi:10.1016/j.jsv.2022.116895).
Abstract
Acoustic black holes (ABHs) are tapered structural features that can achieve high levels of structural damping within lightweight constraints. It has previously been proposed to integrate feedforward active vibration control into an ABH to enable control over a broad spectrum, however, the time-advanced information required in this control strategy is not always available. In addition, it has been shown that controlling the reflection coefficient in a beam-based ABH leads to an undesirable enhancement of the taper vibration. In this paper, a feedback control strategy is applied to an ABH terminated beam, with a piezoelectric patch providing the control actuation. The feedback strategy is a remote vibration control methodology and is used to examine the different compensators that are potentially available to control simultaneously both the local taper vibration and the reflected wave component. The investigation highlights that the taper vibration can be minimised without affecting the reflected wave, however, apart from a few isolated frequencies, it is shown that the reflected wave cannot be minimised without increasing the taper vibration relative to the passive case. Importantly, since the approach enables the passive ABH performance to be maintained whilst simultaneously minimising the vibration in the tip, the fatigue life of the structure can potentially be extended with the addition of the active control loop.
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Feedback_ABH_JSV2021_Revised
More information
Accepted/In Press date: 9 March 2022
Published date: 23 June 2022
Additional Information:
Funding Information:
This work was supported by an EPSRC iCASE studentship, UK (Voucher number 16000058 ) and the Intelligent Structures for Low Noise Environments EPSRC Prosperity Partnership, UK ( EP/S03661X/1 ).
Publisher Copyright:
© 2022 The Author(s)
Keywords:
Acoustic black hole, Active control, Feedback, Remote damping
Identifiers
Local EPrints ID: 456436
URI: http://eprints.soton.ac.uk/id/eprint/456436
ISSN: 0022-460X
PURE UUID: 3580c1ee-3b2a-4356-aaa1-69ae013cb4dd
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Date deposited: 28 Apr 2022 16:48
Last modified: 30 Nov 2024 02:46
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Author:
Kristian Hook
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