执行机构
材料科学
软机器人
人工肌肉
电压
弯曲
智能材料
仿生学
机械能
可穿戴计算机
纳米技术
爬行
计算机科学
机械工程
功率(物理)
电气工程
工程类
物理
人工智能
复合材料
医学
量子力学
解剖
嵌入式系统
作者
Dipankar Barpuzary,Hyeonseong Ham,Dohyeon Park,Kyoungwook Kim,Moon Jeong Park
标识
DOI:10.1021/acsami.1c15573
摘要
To fulfill the insatiable demand for wearable technologies, ionic electroactive polymer actuators have been entrenched as promising candidates that can convert low-input-voltage energy into high mechanical throughput. However, a ubiquitous trilayer design of actuators allows exclusively bending deformation and their highly nonlinear response restricts the true potential of low-voltage actuators for next-generation technology. Herein, we report an unprecedented multilayer design for soft actuators that enables complex deformations shown by skeletal muscles, mechanoreceptors, and plant roots in response to various environmental stimuli. Hierarchically ordered pores in a stretchable interlayer provide excellent electromechanical properties and fast charging kinetics, which enable linear motion by soft actuators at 3 V and under ambient conditions. Our actuators demonstrate astonishing levels of performance, including a 6.5% linear actuation strain, 0.8 s rapid switching speed, and 5000 cycle stable performance in air, producing a 4.2 mN linear blocking force at a ±3 V alternating square-wave voltage. This actuator design demonstrating a walkable spider capable of controlled back-and-forth propelling motion at low driving voltages provides the platform to envision a complex functionality using a portable battery as a power source for soft robotics, wearable exosuits, and biomimetic technologies.
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