执行机构
电压
机器人
机器人学
稳健性(进化)
软机器人
人工肌肉
伏特
人工智能
计算机科学
功率密度
功率(物理)
控制理论(社会学)
工程类
控制工程
电气工程
物理
控制(管理)
生物化学
化学
量子力学
基因
作者
Stephan-Daniel Gravert,Elia Varini,Amirhossein Kazemipour,Mike Y. Michelis,Thomas Büchner,Ronan Hinchet,Robert K. Katzschmann
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2024-01-05
卷期号:10 (1): eadi9319-eadi9319
被引量:54
标识
DOI:10.1126/sciadv.adi9319
摘要
Rigid robots can be precise but struggle in environments where compliance, robustness to disturbances, or energy efficiency is crucial. This has led researchers to develop biomimetic robots incorporating soft artificial muscles. Electrohydraulic actuators are promising artificial muscles that perform comparably to mammalian muscles in speed and power density. However, their operation requires several thousand volts. The high voltage leads to bulky and inefficient driving electronics. Here, we present hydraulically amplified low-voltage electrostatic (HALVE) actuators that match mammalian skeletal muscles in average power density (50.5 watts per kilogram) and peak strain rate (971% per second) at a 4.9 times lower driving voltage (1100 volts) compared to the state of the art. HALVE actuators are safe to touch, are waterproof, and exhibit self-clearing properties. We characterize, model, and validate key performance metrics of our actuator. Last, we demonstrate the utility of HALVE actuators on a robotic gripper and a soft robotic swimmer.
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