Soft Electromagnetic Actuator and Oscillator

IF 6.4 3区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Advanced Materials Technologies Pub Date : 2024-12-19 DOI:10.1002/admt.202400982

Noah D. Kohls, Yi Chen Mazumdar

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Abstract

Soft actuators are critical for enabling soft robots, medical devices, and haptic systems. Many soft actuators, however, require power to hold a configuration and rely on hard circuitry for control, limiting their potential applications. In this work, the first soft electromagnetic system is demonstrated for externally-controlled bistable actuation or self-regulated astable oscillation. This novel bellows-shaped actuator uses liquid metal encased in silicone as a compliant conductor that is capable of force generation, integrated sensing, and self-reconnecting. In the bistable configuration, the actuator can hold positions with no power. By utilizing a unique soft kinking mechanism, the actuator can generate feedback for self-regulated oscillation. The construction, sensing, and feedback mechanisms for this actuator are first discussed. Then, the force output, thermal performance, and dynamics are characterized. The bistable version has a stroke of 6 mm and can compress/expand with only 15 W of power for 30 ms. The astable version has a stroke of 3 mm and can oscillate at 27 Hz with 18 W of power. Several applications are demonstrated including bistable crawling, hopping, pulsing, and swimming. By adding a 20 V battery, self-regulated astable vibrational locomotion is also demonstrated. Overall, this work shows how these actuators and oscillators can bridge the gap between conventional and soft robots.

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软电磁致动器和振荡器

软致动器对于实现软机器人、医疗设备和触觉系统至关重要。然而，许多软执行器需要电源来保持配置，并依赖硬电路进行控制，限制了它们的潜在应用。在这项工作中，第一个软电磁系统证明了外部控制的双稳态驱动或自调节的不稳定振荡。这种新颖的波纹形致动器使用包裹在硅胶中的液态金属作为兼容导体，能够产生力，集成传感和自重新连接。在双稳态配置中，执行器可以在没有电源的情况下保持位置。通过采用独特的软扭结机构，驱动器可以产生自调节振荡的反馈。首先讨论了该驱动器的结构、传感和反馈机制。然后，对其力输出、热性能和动力学特性进行了表征。双稳态版本的行程为6毫米，可以在30毫秒内仅用15瓦的功率压缩/扩展。不稳定版本的行程为3毫米，可以在18w的功率下以27 Hz的频率振荡。演示了几种应用，包括双稳态爬行、跳跃、脉冲和游泳。通过添加20v电池，还演示了自调节的不稳定振动运动。总的来说，这项工作显示了这些致动器和振荡器如何弥合传统机器人和软机器人之间的差距。

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来源期刊

Advanced Materials Technologies Materials Science-General Materials Science

CiteScore

10.20

自引率

4.40%

发文量

566

期刊介绍： Advanced Materials Technologies Advanced Materials Technologies is the new home for all technology-related materials applications research, with particular focus on advanced device design, fabrication and integration, as well as new technologies based on novel materials. It bridges the gap between fundamental laboratory research and industry.