这类电活性聚合物能大幅弯曲,加载电压时会产生大幅度运动。
This kind of EAP can bend a lot, producing a large movement when a voltage is applied.
移除加载电压后,离子型电活性聚合物便会立即回复到初始形状。
And ionic EAPs revert to their original shape as soon as the applied voltage is removed.
帕西尼公司对不同的变形材料进行了研究,包括一种叫电活性聚合物的材料。
Pacinian has researched different deformable materials, including one called electroactive polymers.
另外,多组电介质型电活性聚合物用极少的电能就能产生极大的力量。
Moreover, a stack of several dielectric EAPs can generate substantial forces using little power.
介绍了电活性聚合物过充保护机制的原理,详细描述了其工作过程。
The function mechanism of the electroactive polymer as the overcharge protection was introduced and its working process was described.
材料科学:电活性聚合物,又称人造肌肉,可在某些应用环境下替代电动机。
Materials science: Electroactive polymers, also known as artificial muscles, could replace electric motors in some applications.
这些旋转电机形似自行车车轮(见下图),辐条换成了黑色电活性聚合物薄片。
These rotary motors (see picture) resemble bicycle wheels that have had their spokes replaced with thin, black slivers of EAP.
通过大量的实验研究,分析实验数据和现象,结果证实了电活性聚合物发电的原理。
Quantitative experiments and research as well as detailed analysis show that the DEAP can generate the electric energy harvesting from the environmental sources.
安德森博士的团队除了致力于转动研究,还在探索将电活性聚合物做发电机使用的方法。
As well as working on rotary motion, Dr Anderson's group is also investigating the use of EAPs as electrical generators.
研究人员几十年来一直在研究人造肌肉,这是一种电活性聚合物,加载电压时会膨胀或收缩。
Researchers have been experimenting with artificial muscles-electroactive polymers that can expand or contract when a voltage is applied-for decades.
电活性聚合物(EAP)主要有两种类型,那就是我们通常所说的离子型和电介质型(见下图)。
There are two main types of electroactive polymer (EAP), which are usually referred to as ionic and dielectric (see diagram).
2005年,拜科恩博士决定找到这个问题的答案,在一场扳手腕比赛中,他让一个人与三支电活性聚合物材质的机器人手臂进行较量。
In 2005 Dr Bar-Cohen decided to find out by pitting a human against a trio of robotic arms, based on EAPs, in an arm-wrestling contest.
用红外吸收光谱法表征了聚邻氨基酚薄膜,认为该聚合物具有梯形结构,其中吩恶嗪环作为电活性点。
The characterization of the PAP film by infrared spectroscopy suggested that the PAP is a ladder polymer with phenoxazine rings as electroactive sites.
用红外吸收光谱法表征了聚邻氨基酚薄膜,认为该聚合物具有梯形结构,其中吩恶嗪环作为电活性点。
The characterization of the PAP film by infrared spectroscopy suggested that the PAP is a ladder polymer with phenoxazine rings as electroactive sites.
应用推荐