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离子聚合物金属复合材料电致动模型研究 被引量:4

An electro-mechanical model of ionic polymer metal composites
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摘要 离子聚合物金属复合材料(ionic polymer-metal composites,IPMC)是一种新型电致形变高分子材料,具有广阔应用前景。为了有效描述IPMC的形变规律,基于IPMC致动原理提出了一种电致动模型。建立了阶梯电压下IPMC膜内水合阳离子的力平衡方程,由水合阳离子的浓度分布及水分子的扩散计算得出水分子的浓度以及含水量分布,结合实验所确定的含水量和应变的关系从而确定IPMC沿厚度方向的应变分布。该计算方法适用于不同形状的IPMC致动器。以悬臂梁IPMC致动器为例,通过应变分布计算得到IPMC致动器在阶跃电压下的输出弯矩和相应的位移响应,模拟结果与实验结果的瞬时响应规律高度一致,证明该模型正确。该模型的建立为IPMC结构驱动一体化设计奠定了坚实的基础。 Ionic polymer-metal composites(IPMC) is a new type electroactive polymer material,it has broad application prospects.In order to effectively describe the deformation law of IPMC,an electric-mechanical actuator model for IPMC was proposed in this paper.In this model,force balance equation of hydrated cation was established,and the concentration of water molecules as well as the water content distribution was calculated based on the concentration of hydrated cation distribution and diffusion of water molecules;the relationship between water content and strain was determined by experiments;then the strain distribution along the thickness and the corresponding output displacement of IPMC sample were obtained.The method is suitable for different shapes of IPMC actuators.The results from the simulation and experiment verified that the electric-mechanical actuator model in this paper well expressed the characteristics of the IPMC actuators under a step DC voltage,which proved that the method is correct and feasible.
作者 于敏 丁海涛 郭东杰 何青松 戴振东
机构地区 南京航空航天大学仿生结构与材料防护研究所
出处 《功能材料》 EI CAS CSCD 北大核心 2011年第8期1436-1440,共5页 Journal of Functional Materials
基金 国家自然科学基金资助项目(50705043 50805076 50975140)
关键词 离子聚合物金属复合材料 IPMC 致动模型 数值模拟 ionic polymer-metal composites IPMC actuator model numerical simulation
分类号 TB381 [一般工业技术—材料科学与工程]
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  • 1罗玉元,李朝东,张国贤.基于离子聚合物金属复合结构(IPMC)的柔性致动器研究[J].中国机械工程,2006,17(4):410-413. 被引量:14
  • 2Shahinpoor M, Bar-cohen Y, Simpson J O, et al. Ionic polymer-metal composites (IPMC) as a biomimetric sensors, actuators and artificial muscles: a review[J]. Smart Material and Structures, 1998, 7: 15-30.
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功能材料
2011年 第8期

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