Enikov Eniko T, Seo Geon S
Department of Aerospace and Mechanical Engineering, The University of Arizona, 1130 N. Mountain, Tucson, Arizona 85721, USA.
Biotechnol Prog. 2006 Jan-Feb;22(1):96-105. doi: 10.1021/bp050170l.
Ionic polymers are a promising material for the development of muscle-like actuators. These materials are capable of undergoing significant deformation when structured as metal-polymer-metal composite sheets. The mechanical characteristics of these sheets, such as flexibility, softness, and ability to undergo large deformation in direct contact with water, have led some to consider these as possible artificial muscles. This paper describes the numerical analysis of an electrochemical model of the deformation of muscle-like polymers. A general continuum model describing the transport and deformation processes of these actuators is briefly presented, along with a detailed description of the simulation scheme used to predict deformation, current, and mass transport. The predictions of the model are compared with experimental data, indicating a significant role of water transport in the large-scale deformation. The model is also used to draw a comparison between the performance of natural muscles and muscle-like polymer actuators.
离子聚合物是用于开发类肌肉致动器的一种很有前景的材料。当被构造成金属-聚合物-金属复合片时,这些材料能够发生显著变形。这些片材的机械特性,如柔韧性、柔软性以及在与水直接接触时能够发生大变形的能力,使得一些人将其视为可能的人造肌肉。本文描述了类肌肉聚合物变形的电化学模型的数值分析。简要介绍了一个描述这些致动器的传输和变形过程的通用连续介质模型,以及用于预测变形、电流和质量传输的模拟方案的详细描述。将该模型的预测结果与实验数据进行了比较,表明水传输在大规模变形中起着重要作用。该模型还用于比较天然肌肉和类肌肉聚合物致动器的性能。