Manipulating flexural waves to enhance the broadband vibration mitigation through inducing programmed disorder on smart rainbow metamaterials
Manipulating flexural waves to enhance the broadband vibration mitigation through inducing programmed disorder on smart rainbow metamaterials
The application of smart materials and metastructures has been rapidly increasing in advanced multiphysical systems because of their ability to modify mechanical responses by adding circuits in a programmable way. This paper proposes to exploit functional gradation and programmed disorder for flexural wave manipulation to enhance broadband vibration control, leading to a new application of smart metamaterials. The graded metamaterial configuration involves arranging the shunted piezoelectric patches with algorithmically obtained spatially varying parameters, resulting in wideband wave attenuation and mode trapping. The considered locally grading parameter here is the shunt resonant frequency of the unit cells, designed following the rainbow trap idea and referred to as ‘rainbow’ metamaterials. Two metastructures are developed in this article by tuning the shunted piezoelectric electrical circuit in single and multiple configurations, each related to the unit cell. The computationally efficient spectral element method is employed to calculate the dynamic response, and the spectral transfer matrix method is integrated therein to obtain the dispersive diagram. Subsequently, effective vibration mitigation in a wider frequency band is realized through wave manipulation based on the concept of rainbow metamaterials. To this end, we have considered a unimorph beam hosting an array of piezoelectric unit cells with single and multiple resonant shunts for obtaining the numerical results, which demonstrate that the vibration attenuation zone of the multi-resonant rainbow arrangement becomes significantly wider than the single shunt configuration. The programmed disorder in the elastic waves imposes the veering effect, which generates an interaction between two dispersion curves showing a coupling phenomenon for the waves. It involves relevant energetic exchanges between the wave modes and strongly affect the undamped forced response of the system that can influence the wave trapping generated by the proposed metamaterial. Such outcomes lead to the realization of the benefit of rainbow smart metastructures compared to conventional locally resonant metamaterials on vibration and elastic bandwidth manipulation.
Graded metamaterial, Programmed disorder, Rainbow metamaterials, Spectral approach, Synthetic impedance, Veering phenomenon
650-671
de Moura, B.B.
265ac99d-d325-4f77-b5db-1ab081a2968d
Machado, M.R.
bb9ab94a-c9f5-488c-828b-cdfb39f5d448
Dey, S.
99c45bea-ee2e-4d07-bb94-28560a85b99c
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
19 October 2023
de Moura, B.B.
265ac99d-d325-4f77-b5db-1ab081a2968d
Machado, M.R.
bb9ab94a-c9f5-488c-828b-cdfb39f5d448
Dey, S.
99c45bea-ee2e-4d07-bb94-28560a85b99c
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
de Moura, B.B., Machado, M.R., Dey, S. and Mukhopadhyay, T.
(2023)
Manipulating flexural waves to enhance the broadband vibration mitigation through inducing programmed disorder on smart rainbow metamaterials.
Applied Mathematical Modelling, 125 (Part B), .
(doi:10.1016/j.apm.2023.10.011).
Abstract
The application of smart materials and metastructures has been rapidly increasing in advanced multiphysical systems because of their ability to modify mechanical responses by adding circuits in a programmable way. This paper proposes to exploit functional gradation and programmed disorder for flexural wave manipulation to enhance broadband vibration control, leading to a new application of smart metamaterials. The graded metamaterial configuration involves arranging the shunted piezoelectric patches with algorithmically obtained spatially varying parameters, resulting in wideband wave attenuation and mode trapping. The considered locally grading parameter here is the shunt resonant frequency of the unit cells, designed following the rainbow trap idea and referred to as ‘rainbow’ metamaterials. Two metastructures are developed in this article by tuning the shunted piezoelectric electrical circuit in single and multiple configurations, each related to the unit cell. The computationally efficient spectral element method is employed to calculate the dynamic response, and the spectral transfer matrix method is integrated therein to obtain the dispersive diagram. Subsequently, effective vibration mitigation in a wider frequency band is realized through wave manipulation based on the concept of rainbow metamaterials. To this end, we have considered a unimorph beam hosting an array of piezoelectric unit cells with single and multiple resonant shunts for obtaining the numerical results, which demonstrate that the vibration attenuation zone of the multi-resonant rainbow arrangement becomes significantly wider than the single shunt configuration. The programmed disorder in the elastic waves imposes the veering effect, which generates an interaction between two dispersion curves showing a coupling phenomenon for the waves. It involves relevant energetic exchanges between the wave modes and strongly affect the undamped forced response of the system that can influence the wave trapping generated by the proposed metamaterial. Such outcomes lead to the realization of the benefit of rainbow smart metastructures compared to conventional locally resonant metamaterials on vibration and elastic bandwidth manipulation.
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Rainbow_metamaterial
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Accepted/In Press date: 3 October 2023
e-pub ahead of print date: 14 October 2023
Published date: 19 October 2023
Additional Information:
Funding Information:
TM acknowledges the grant received from Science and Engineering Research Board , India (Grant no. SRG/2020/001398 ). MRM would like to acknowledge the support received through the Fundação de Apoio a Pesquisa do Distrito Federal-FAPDF (Grants no. 00193-00000766/2021-71 ), CNPq (Grant no. 404013/2021-0 ) and POLONEZ BIS project SWinT, reg. no. 2022/45/P/ST8/02123 co-funded by the National Science Centre and the European Union Framework Programme for Research and Innovation Horizon 2020 under the Marie Skłodowska-Curie grant agreement no. 945339 .
Keywords:
Graded metamaterial, Programmed disorder, Rainbow metamaterials, Spectral approach, Synthetic impedance, Veering phenomenon
Identifiers
Local EPrints ID: 485552
URI: http://eprints.soton.ac.uk/id/eprint/485552
ISSN: 0307-904X
PURE UUID: 441a7958-2956-44b3-98a5-3587a938e21a
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Date deposited: 08 Dec 2023 17:56
Last modified: 18 Mar 2024 04:10
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Contributors
Author:
B.B. de Moura
Author:
M.R. Machado
Author:
S. Dey
Author:
T. Mukhopadhyay
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