An energy-based model for both rate-dependent and rate-independent hysteretic effects in uniaxially-loaded dielectric elastomer actuators

Smart structures and materials. Nondestructive evaluation for health monitoring and diagnostics Pub Date : 2023-04-28 DOI:10.1117/12.2657685

Johannes Prechtl, Felix Scherf, J. Kunze, K. Flaßkamp, G. Rizzello

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Abstract

It is widely known that dielectric elastomer (DE) material exhibits a strongly rate-dependent hysteresis in their stress-stretch response. It is experimentally observed, however, that the hysteresis of some DE materials (e.g., silicone) behaves as practically rate-independent when operating in the sub-Hz range. Despite this fact, the investigation and modeling of rate-independent hysteretic effects in DEs has received much less attention in the literature, compared to the rate-dependent ones. In this paper, we propose a new lumped-parameter dynamic model capable of describing a stress-stretch DE hysteresis with both rate-dependent and rate-independent effects. The model is grounded on a physics-based approach, combining classic thermodynamically-consistent modeling of DE large deformations and electro-mechanical coupling with a new energy-based Maxwell-Lion description of the hysteretic process. After presenting the theory, the model is validated by means of experiments conducted on silicone-based rolled DE actuators.

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单轴加载介质弹性体致动器中速率相关和速率无关滞回效应的能量模型

众所周知，介电弹性体(DE)材料在其应力-拉伸响应中表现出强烈的速率依赖性滞后。然而，实验观察到，当在亚赫兹范围内工作时，某些DE材料(例如硅树脂)的迟滞表现实际上与速率无关。尽管如此，与速率相关的滞后效应相比，DEs中速率无关的滞后效应的研究和建模在文献中受到的关注要少得多。在本文中，我们提出了一个新的集总参数动态模型，能够描述具有速率依赖和速率无关效应的应力-拉伸DE滞后。该模型基于物理方法，结合了经典的DE大变形的热力学一致建模和机电耦合，以及基于能量的新Maxwell-Lion滞回过程描述。在提出理论后，通过对硅基轧制DE执行器的实验对模型进行了验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Smart structures and materials. Nondestructive evaluation for health monitoring and diagnostics

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