Silicone-layered waterproof electrohydraulic soft actuators for bio-inspired underwater robots

IF 2.9 Q2 ROBOTICS Frontiers in Robotics and AI Pub Date : 2024-06-14 DOI:10.3389/frobt.2024.1298624
Takumi Shibuya, Shuya Watanabe, Jun Shintake
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Abstract

Electrohydraulic soft actuators are a promising soft actuation technology for constructing bio-inspired underwater robots owing to the features of this technology such as large deformations and forces, fast responses, and high electromechanical efficiencies. However, this actuation technology requires high voltages, thereby limiting the use of these actuators in water and hindering the development of underwater robots. This paper describes a method for creating bio-inspired underwater robots using silicone-layered electrohydraulic soft actuators. The silicone layer functions as an insulator, enabling the application of high voltages underwater. Moreover, bending and linear actuation can be achieved by applying the silicone layers on one or both sides of the actuator. As a proof of concept, bending and linear actuators with planar dimensions of 20 mm × 40 mm (length × width) are fabricated and characterized. Underwater actuation is observed in both types of actuators. The bending actuators exhibit a bending angle and blocked force of 39.0° and 9.6 mN, respectively, at an applied voltage of 10 kV. Further, the linear actuators show a contraction strain and blocked force of 6.6% and 956.1 mN, respectively, at an applied voltage of 10 kV. These actuators are tested at a depth near the surface of water. This ensured that they can operate at least at that depth. The actuators are subsequently used to implement various soft robotic devices such as a ray robot, a fish robot, a water-surface sliding robot, and a gripper. All of the robots exhibit movements as expected; up to 31.2 mm/s (0.91 body length/s) of locomotion speed is achieved by the swimming robots and a retrieve and place task is performed by the gripper. The results obtained in this study indicate the successful implementation of the actuator concept and its high potential for constructing bio-inspired underwater robots and soft robotics applications.
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用于生物启发式水下机器人的硅胶层防水电液软致动器
电液软致动器具有变形和受力大、响应快、机电效率高等特点,是一种很有前途的软致动技术,可用于构建生物启发的水下机器人。然而,这种致动技术需要高电压,从而限制了这些致动器在水中的使用,阻碍了水下机器人的开发。本文介绍了一种利用硅胶层电液软致动器制造生物启发式水下机器人的方法。硅胶层具有绝缘体的功能,可在水下施加高电压。此外,通过在致动器的一侧或两侧涂上硅胶层,可以实现弯曲和线性致动。作为概念验证,我们制作了平面尺寸为 20 毫米 × 40 毫米(长 × 宽)的弯曲和线性致动器,并对其进行了表征。两种致动器都能在水下致动。在 10 kV 电压下,弯曲致动器的弯曲角度和阻滞力分别为 39.0° 和 9.6 mN。此外,线性致动器在 10 kV 电压下的收缩应变和阻滞力分别为 6.6% 和 956.1 mN。这些致动器是在接近水面的深度进行测试的。这确保了它们至少能在该深度工作。这些致动器随后被用于实现各种软机器人装置,如射线机器人、鱼机器人、水面滑动机器人和抓手。所有机器人的运动都符合预期;游泳机器人的运动速度可达 31.2 毫米/秒(0.91 体长/秒),而抓手则能完成捞取和放置任务。这项研究获得的结果表明,成功地实现了致动器概念,并且在构建生物启发水下机器人和软机器人应用方面具有巨大潜力。
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来源期刊
CiteScore
6.50
自引率
5.90%
发文量
355
审稿时长
14 weeks
期刊介绍: Frontiers in Robotics and AI publishes rigorously peer-reviewed research covering all theory and applications of robotics, technology, and artificial intelligence, from biomedical to space robotics.
期刊最新文献
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