# Effect of temperature and pre-stretch on the dynamic performance of dielectric elastomer minimum energy structure

**Authors:** Zhipeng Wang, Qiaowei Xu, Yanmin Zhou, Gang Li, Bin He

PMC · DOI: 10.1038/s41598-024-66566-0 · Scientific Reports · 2024-07-04

## TL;DR

This paper studies how temperature and pre-stretch affect the performance of dielectric elastomer structures used in soft robotics.

## Contribution

A systematic modeling framework is proposed to analyze the effects of pre-stretch and temperature on DEMES dynamics.

## Key findings

- Pre-stretch and temperature jointly influence the bending angle and dynamic stability of DEMES.
- Appropriate temperature and higher pre-stretch ratios improve actuation performance.
- Low pre-stretch ratios can cause dynamic instability in DEMES.

## Abstract

Dielectric Elastomer Minimum Energy Structures (DEMES) have the ability of actively adjusting their shape to accommodate complex scenarios, understanding the actuation mechanism of DEMES is essential for their effective design and control, which has rendered them a focus of research in the field of soft robotics. The actuation ability of DEMES is usually influenced by external conditions, among which the electromechanical properties of DE materials are highly sensitive to temperature changes, and the pre-stretch ratio of DE materials has a significant impact on the dynamic performance of DEMES. Therefore, it is necessary to study the effects of temperature and pre-stretch ratio on the nonlinear dynamic behavior of DEMES. In this paper, in response to the lack of research on the influence of DE pre-stretch ratio on the actuation characteristics of DEMES, this paper proposes a systematic modeling and analysis framework that comprehensively considers pre-stretch factors, temperature factors, and viscoelastic factors, and establishes the motion control equation of DEMES affected by the coupling effect of DE pre-stretch ratio and temperature. The proposed analytical framework is used to analyze the evolution of the electromechanical response of DEMES under voltage excitation under the coupling of DE pre-stretch ratio and temperature. The results indicate that the bending angle, inelastic deformation, resonant frequency, and dynamic stability of DEMES can be jointly adjusted by the DE pre-stretch ratio and ambient temperature. A low pre-stretch ratio of DE can lead to dynamic instability of DEMES, while appropriate temperature conditions and higher pre-stretch ratios can significantly improve the actuation ability of DEMES. This can provide theoretical guidance for the design and deformation control of DEMES.

## Full-text entities

- **Diseases:** DE (MESH:D003635)
- **Chemicals:** DE (MESH:D004054)

## Full text

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## Figures

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## References

53 references — full list in the complete paper: https://tomesphere.com/paper/PMC11224424/full.md

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Source: https://tomesphere.com/paper/PMC11224424