ipmc
英
美
网络 离子聚合物金属复合材料; 离子交换膜金属复合材料; 金属/离子聚合物复合材料
双语例句
- Numerical Analysis of IPMC Electro-Mechanical Properties and Its Structure Simulation
IPMC电致动特性分析及其相关结构数值模拟 - An improved model of lamination theory was used to forecast the mechanical properties of ionic polymer metal composite ( IPMC).
采用梯度功能材料力学方法,通过改进层合板理论模型来预测材料的力学性能。 - A Miniature Fish-like Robot with Infrared Remote Receiver and IPMC Actuator Fabrication and Properties of Ag Based IMPC Flexible Actuator
基于IPMC驱动器的小型遥控机器鱼的研制Ag型IPMC柔性驱动器的制备及性能 - The research conclusions are of value for mechanical modeling and failure analysis on IPMC.
本文结果可为IPMC的力学建模、失效形式等研究提供有益的参考。 - Fabrication and Properties of Ag Based IMPC Flexible Actuator
Ag型IPMC柔性驱动器的制备及性能 - Actuating response characteristics and model of artificial muscles IPMC
人工肌肉IPMC电致动响应特性及其模型 - As a novel kind of sensor and actuator materials, Ionic Polymer Metal Composite ( IPMC) has been used in more and more engineering applications fields.
提出了一种基于不可逆热力学和纯弯曲理论的力电耦合模型,以描述和预测离子聚合物金属复合材料的力电特性。 - Improved model of IPMC's elastic modulus using functionally gradient method
采用梯度功能方法的IPMC弹性模量改进模型 - Optical and electrical properties of polymer modified by Cu and Ni ion implantation Experimental Research on the IPMC Actuator's Dynamic Characters
金属离子注入聚合物光电特性研究离子金属聚合物复合材料调节器的动态特性 - Ion-exchange polymer metal composite ( IPMC) is known as a material for artificial muscle actuator. The advantages of IPMC in requiring low activation voltage and the induced large bending strain led to its consideration for various potential application, especially in bio-inspired robotics.
IPMC(ion-exchangepolymermetalcomposite)是一种人工肌肉材料,由于其较低的驱动电压能产生较大的位移变形,作为一种新型执行器非常适用于仿生机器人的开发。 - The thesis studies the displacement and force characteristics of the IPMC actuator.
本文研究了IPMC的一些重要特性,如位移特性和输出力特性。 - Property and Application of IPMC Artificial Muscle
IPMC人工肌肉的特性及其应用 - The traditional tactile display is complex, bulky, and not potable, so in this paper we use a kind of smart material IPMC as the actuator of tactile display.
现阶段国内外的触觉显示器结构复杂、体积大、不便于携带。针对这些缺点,本文采用了一种新型智能材料IPMC作为触觉显示器的致动器。 - A control strategy with better robustness is needed to ensure stability in a long time.
IPMC模型会随着使用的次数而有所改变,必须用一种鲁棒性较好的控制策略来保证控制系统在较长的时间范围内稳定。 - However, it works with complex mechanism, rigorous circumstance, and relates to the technics of preparation, which limit its development and utilization. Firstly, this thesis researches the method of IPMC fabrication.
然而IPMC工作机理复杂、对环境要求苛刻,而且受制备工艺影响较大,这种不确定性限制了它的开发与应用。本文首先研究了IPMC的制备方法,合成了IPMC人工肌肉。 - For improving the performance of IPMC actuator, this dissertation will focus on the electrical response characteristics, covering IPMC fabrication, modification, modeling, experiments and applications.
为提高IPMC薄膜电响应性能,本文围绕其电响应特性进行了详细的研究,内容涵盖材料的制备、改性、建模、实验和应用。 - The displacement of different geometry and surface structure IPMCs has been studied.
对不同几何形状和表面结构的IPMC输出位移进行了模拟研究。 - IPMC ( Ion-Exchange Polymer Metal Composite) for new actuator equipments is a kind of intelligence material. When the input voltage, which is applied on the two sides of IPMC, is small, the output displacement of IPMC is large.
一种基于IPMC(Ion-exchangepolymermetalcomposite,离子交换膜金属复合材料)新型致动器材的人工智能材料输入电压小,而输出位移大,驱动简便,获得了广泛的关注。 - Ion-exchange Polymer-Metal Composites ( IPMC) is a type of electro-deformation smart material. Because IPMC performance is similar to biologic muscle, it named as artificial muscle.
离子交换聚合体金属合成物(Ion-exchangePolymer-metalcomposites简称IPMC)是一种电致形变智能材料,其性能类似于生物肌肉,因此被称为人工肌肉。 - The problem of feed-through coupling from the actuation signal to the sensing signal, arising from the proximity of IPMC and PVDF, presents a significant challenge in real-time implementation.
由于IPMC和PVDF位置接近,激励信号和感知信号产生了馈通耦合问题,提出了一个在实时操作上的巨大的挑战。 - Ionic polymer-metal composite ( IPMC) is a new type of smart materials, which belongs to one class of electroactive polymers, and it can generate large deformation within voltage.
离子聚合物金属复合物(简称IPMC)是一种新型智能材料,属于电活性聚合物(EAP)范畴,在电压激励下可以产生大变形。 - A complete set of experimental platform is developed for IPMC to study experimentally the displacement response characteristic of stimulation signals with different types, frequencies and amplitudes.
针对这种材料开发了一套完整的IPMC实验平台,这个平台可以通过实验研究IPMC在不同的激励信号类型、频率、幅值等条件下的位移响应特性。