Experimental and numerical investigations of the electro-mechanical response of particle filled elastomers—Part II: Continuum modeling approach

A comprehensive experimental study performed under a combination of electro-mechanical loads on a particle-filled silicone as a representative of dielectric elastomers is presented in the Part I of this work (Mehnert et al., submitted, 2021). The constitutive modeling and numerical simulation of ele...

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Bibliographic Details
Published in:European journal of mechanics, A, Solids A, Solids, 2022-11, Vol.96, p.104661, Article 104661
Main Authors: Mehnert, Markus, Faber, Jessica, Hossain, Mokarram, Chester, Shawn A., Steinmann, Paul
Format: Article
Language:English
Subjects:
Dielectric elastomers
Electro-active polymers
Electro-mechanics
Particle filled polymers
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Summary:A comprehensive experimental study performed under a combination of electro-mechanical loads on a particle-filled silicone as a representative of dielectric elastomers is presented in the Part I of this work (Mehnert et al., submitted, 2021). The constitutive modeling and numerical simulation of electro-active polymers are essential fields of research in order to increase the acceptance of this group of soft smart materials in real-life applications. However, only few contributions containing constitutive modeling approaches are combined with experimental data obtained from electro-mechanically coupled loading conditions due to the complexity of corresponding experiments. In this contribution, we aim to develop an electro-mechanically coupled model, which closely replicates the response of a silicone polymer filled with a high dielectric permittivity filler of varying fractions that are characterized under a combination of electric and mechanical loads. Once the model is calibrated with the experimental data described in Part I of this contribution, it is used for a simple illustrative application example showcasing the capability of the model and the influence of the different material characteristics. •Description of a filler content dependent electro-mechanically coupled modeling approach.•Underlying Pseudo-viscoelastic mechanical material response.•Parameter identification using the experimental data from Part I.
ISSN:0997-7538
DOI:10.1016/j.euromechsol.2022.104661