消除大变形IPMC人工肌肉的背部松弛:一种噪音辅助无模式电极方法

Mohsen Annabestani, M. Sayad, Pouria Esmaeili-Dokht, Razieh Gorji, M. Fardmanesh
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引用次数: 7

摘要

离子聚合物金属复合材料(IPMCs)最主要的缺点之一是其背弛豫(BR)效应。BR是ipmc的一个不需要的和缓慢的反弯曲,它显示自己在期望弯曲的相反方向。提出了一些基于闭环控制的技术来消除BR效应。然而,这些技术仅适用于IPMC的小变形,而且它们采用闭环方法。而在实际应用中,IPMC变形较大,不能采用闭环系统。为了解决这些问题,我们提出了一种抑制IPMC BR效应的非反馈方法,该方法即使在大弯曲位移下也有效。所提出的技术是基于在IPMC无图案电极上外源噪声刺激产生的Nafion膜中自由水分子的快速往复运动。我们的想法已经在概念上得到了描述,并通过几个实验得到了验证。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Eliminating Back Relaxation in Large-Deformable IPMC Artificial Muscles: A Noise-Assistive Pattern-Free Electrode Approach
one of the most critical disadvantages of Ionic Polymer Metal Composites (IPMCs) is their Back Relaxation (BR) effect. The BR is an unwanted and slow counter-bending of IPMCs that shows itself in the opposite direction of the desired bending. Some techniques based on using closed-loop control have been proposed for eliminating the BR effect. However, those techniques are valid only for small deformation of IPMC, and also they use closed-loop approaches. While in practical applications, the IPMC deformation should be large, and we cannot use the closed-loop system. To address these problems, we have proposed a non-feedback method for restraining the IPMC BR effect, which works even in large bending displacement. The proposed technique is based on fast reciprocating motions of free water molecules in the Nafion membrane which is producing by exogenous noise stimulations on the pattern-free electrodes of IPMC. Our idea has been described conceptually and validated by several experiments.
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