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Main Authors: Ghosh, Kamalendu, Shrimali, Bhavesh
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.07900
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author Ghosh, Kamalendu
Shrimali, Bhavesh
author_facet Ghosh, Kamalendu
Shrimali, Bhavesh
contents Dielectric elastomers are increasingly studied for their potential in soft robotics, actuators, and haptic devices. Under time-dependent loading, they dissipate energy via viscous deformation and friction in electric polarization. However, most constitutive models and finite element (FE) implementations consider only mechanical dissipation because mechanical relaxation times are much larger than electric ones. Accounting for electric dissipation is crucial when dealing with alternating electric fields. Ghosh et al. (2021) proposed a fully coupled three-dimensional constitutive model for isotropic, incompressible dielectric elastomers. We critically investigate their numerical scheme for solving the initial boundary value problem (IBVP) describing the time-dependent behavior. We find that their fifth-order explicit Runge-Kutta time discretization may require excessively small or unphysical time steps for realistic simulations due to the stark contrast in mechanical and electric relaxation times. To address this, we present a stable implicit time-integration algorithm that overcomes these constraints. We implement this algorithm with a conforming FE discretization to solve the IBVP and present the mixed-FE formulation implemented in FEniCSx. We demonstrate that the scheme is robust, accurate, and capable of handling finite deformations, incompressibility, and general time-dependent loading. Finally, we validate our code against experimental data for VHB 4910 under complex time-dependent electromechanical loading, as studied by Hossain et al. (2015).
format Preprint
id arxiv_https___arxiv_org_abs_2411_07900
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hybrid finite element implementation of two-potential constitutive modeling of dielectric elastomers
Ghosh, Kamalendu
Shrimali, Bhavesh
Computational Physics
Numerical Analysis
Dielectric elastomers are increasingly studied for their potential in soft robotics, actuators, and haptic devices. Under time-dependent loading, they dissipate energy via viscous deformation and friction in electric polarization. However, most constitutive models and finite element (FE) implementations consider only mechanical dissipation because mechanical relaxation times are much larger than electric ones. Accounting for electric dissipation is crucial when dealing with alternating electric fields. Ghosh et al. (2021) proposed a fully coupled three-dimensional constitutive model for isotropic, incompressible dielectric elastomers. We critically investigate their numerical scheme for solving the initial boundary value problem (IBVP) describing the time-dependent behavior. We find that their fifth-order explicit Runge-Kutta time discretization may require excessively small or unphysical time steps for realistic simulations due to the stark contrast in mechanical and electric relaxation times. To address this, we present a stable implicit time-integration algorithm that overcomes these constraints. We implement this algorithm with a conforming FE discretization to solve the IBVP and present the mixed-FE formulation implemented in FEniCSx. We demonstrate that the scheme is robust, accurate, and capable of handling finite deformations, incompressibility, and general time-dependent loading. Finally, we validate our code against experimental data for VHB 4910 under complex time-dependent electromechanical loading, as studied by Hossain et al. (2015).
title Hybrid finite element implementation of two-potential constitutive modeling of dielectric elastomers
topic Computational Physics
Numerical Analysis
url https://arxiv.org/abs/2411.07900