A Staggered Explicit-Implicit Finite Element Formulation for Electroactive Polymers

TL;DR

This paper introduces a staggered explicit-implicit finite element method for electroactive polymers, achieving comparable accuracy to monolithic methods but with reduced computational costs, enabling large-scale 3D problem solving.

Contribution

It provides a theoretical basis and demonstrates the effectiveness of a staggered finite element formulation for electromechanical problems in electroactive polymers.

Findings

Staggered approach matches monolithic accuracy in complex problems.

Significantly reduces computational expense.

Effective for large-scale 3D electromechanical simulations.

Abstract

Electroactive polymers such as dielectric elastomers (DEs) have attracted significant attention in recent years. Computational techniques to solve the coupled electromechanical system of equations for this class of materials have universally centered around fully coupled monolithic formulations, which while generating good accuracy requires significant computational expense. However, this has significantly hindered the ability to solve large scale, fully three-dimensional problems involving complex deformations and electromechanical instabilities of DEs. In this work, we provide theoretical basis for the effectiveness and accuracy of staggered explicit-implicit finite element formulations for this class of electromechanically coupled materials, and elicit the simplicity of the resulting staggered formulation. We demonstrate the stability and accuracy of the staggered approach by solving complex electromechanically coupled problems involving electroactive polymers, where we focus on problems involving electromechanical instabilities such as creasing, wrinkling, and bursting drops. In all examples, essentially identical results to the fully monolithic solution are obtained, showing the accuracy of the staggered approach at a significantly reduced computational cost.