Smart electro-magneto-viscoelastomer minimum energy structures with particle-reinforcements: theoretical equilibrium and nonlinear dynamics of actuated configurations
Smart electro-magneto-viscoelastomer minimum energy structures with particle-reinforcements: theoretical equilibrium and nonlinear dynamics of actuated configurations
Soft transduction technology is rapidly adopting soft active elastomer-based minimum energy structures because of their distinctive programmable shape-morphing characteristics. For effective device design, an understanding of the nonlinear dynamic behavior is crucial as they often experience time-dependent
motion while operating. Moreover, there has been an increasing scientific interest in enhancing the actuation performance of soft active elastomers by imparting particle reinforcements. This article provides a theoretical framework for investigating the nonlinear dynamics of smart composite elastomer-based minimum energy structures (SCEMES) with the provision of non-aligned electric and magnetic fields, leading to an actively programmable pre-stretch paradigm. Unlike conventional actuators, the proposed SCEMES is made up of a polymer that has electro-magnetic properties and is filled with appropriate fillers with specific volume fractions. An electromagneto-viscoelastic model is developed
here to predict actuator behavior and investigate the effects of particle reinforcement on equilibrium and actuated configurations. Besides strengthening the polymer, particle reinforcement is observed to enhance the equilibrium angle achieved by the structure with enhanced functionality. The proposed
nonlinear dynamic model is extended to investigate a number of critically influential parameters, including shear modulus ratio of fiber to matrix, frame bending stiffness, membrane pre-stretching, and electro-magnetic loading with time-dependent DC and AC modes of actuation. The results reveal that the
combined electro-magnetic actuation enhances the actuation range significantly. The attained tip angle of the actuator increases appreciably when the magnetic and electric fields are applied mutually perpendicular to each other, indicating that the direction of applied magnetic field governs the attained
actuated configuration. Further, particle reinforcement enrichments result in a depletion in oscillation amplitudes and an increase in excitation frequencies under the AC actuation mode. The efficient semi-analytical framework presented here would be crucial in developing new actuators, smart devices and
soft robots for a variety of advanced engineering and medical applications.
Khurana, A.
310738d7-0cdf-4568-8e8e-bb0aad270c7b
Naskar, S.
5f787953-b062-4774-a28b-473bd19254b1
Varma, R.K.
7c370afc-cb1d-4213-a0a1-7159af6e844d
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Khurana, A.
310738d7-0cdf-4568-8e8e-bb0aad270c7b
Naskar, S.
5f787953-b062-4774-a28b-473bd19254b1
Varma, R.K.
7c370afc-cb1d-4213-a0a1-7159af6e844d
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Khurana, A., Naskar, S., Varma, R.K. and Mukhopadhyay, T.
(2023)
Smart electro-magneto-viscoelastomer minimum energy structures with particle-reinforcements: theoretical equilibrium and nonlinear dynamics of actuated configurations.
International Journal of Engineering Science.
(In Press)
Abstract
Soft transduction technology is rapidly adopting soft active elastomer-based minimum energy structures because of their distinctive programmable shape-morphing characteristics. For effective device design, an understanding of the nonlinear dynamic behavior is crucial as they often experience time-dependent
motion while operating. Moreover, there has been an increasing scientific interest in enhancing the actuation performance of soft active elastomers by imparting particle reinforcements. This article provides a theoretical framework for investigating the nonlinear dynamics of smart composite elastomer-based minimum energy structures (SCEMES) with the provision of non-aligned electric and magnetic fields, leading to an actively programmable pre-stretch paradigm. Unlike conventional actuators, the proposed SCEMES is made up of a polymer that has electro-magnetic properties and is filled with appropriate fillers with specific volume fractions. An electromagneto-viscoelastic model is developed
here to predict actuator behavior and investigate the effects of particle reinforcement on equilibrium and actuated configurations. Besides strengthening the polymer, particle reinforcement is observed to enhance the equilibrium angle achieved by the structure with enhanced functionality. The proposed
nonlinear dynamic model is extended to investigate a number of critically influential parameters, including shear modulus ratio of fiber to matrix, frame bending stiffness, membrane pre-stretching, and electro-magnetic loading with time-dependent DC and AC modes of actuation. The results reveal that the
combined electro-magnetic actuation enhances the actuation range significantly. The attained tip angle of the actuator increases appreciably when the magnetic and electric fields are applied mutually perpendicular to each other, indicating that the direction of applied magnetic field governs the attained
actuated configuration. Further, particle reinforcement enrichments result in a depletion in oscillation amplitudes and an increase in excitation frequencies under the AC actuation mode. The efficient semi-analytical framework presented here would be crucial in developing new actuators, smart devices and
soft robots for a variety of advanced engineering and medical applications.
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Accepted/In Press date: 2023
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Local EPrints ID: 483859
URI: http://eprints.soton.ac.uk/id/eprint/483859
ISSN: 0020-7225
PURE UUID: 54573555-df32-4452-8dcb-5bd4993c64df
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Date deposited: 07 Nov 2023 17:44
Last modified: 18 Mar 2024 04:10
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Author:
A. Khurana
Author:
R.K. Varma
Author:
T. Mukhopadhyay
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