Characterizing Swimming Locomotions of an Asymmetrical Soft Millirobot in a Rotating Magnetic Field

Volume 5: Dynamics, Vibration, and Control Pub Date : 2022-10-30 DOI:10.1115/imece2022-95285

Jake T. Bagley, Graham B. Quasebarth, Dalhyung Kim

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Abstract

Millimeter-scale robots have many applications in bioengineering fields due to their ability to be actuated remotely. Certain forms of locomotion allow them to achieve high swim speeds while maintaining controllability. The corkscrew locomotions have been achieved in previous soft robot studies, but their swim speeds were much lower than those exhibited by soft robots of different locomotions. In this paper, a corkscrew swimming motion with a high swim speed was achieved with a 3D rotating magnetic field by designing an asymmetrical soft robot made of flexible polymer embedded with magnetic particles and magnetized at a specific orientation. While this robot exhibited a rolling and transient locomotion at magnetic field frequencies lower than 40 Hz, at frequencies above 40 Hz, the robot exhibited corkscrew swimming locomotion. The swimming speed peaked at a velocity of about 30 mm/s at a magnetic field frequency of 49 Hz. Beyond this frequency, the swim speed of the soft robot decreased because the rotational frequency of the robot could not match the frequency of the actuating magnetic field.

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旋转磁场下非对称软微机器人游泳运动特性研究

毫米级机器人由于其远程驱动的能力，在生物工程领域有许多应用。某些形式的运动使它们在保持可控性的同时达到很高的游泳速度。在以往的软机器人研究中已经实现了螺旋运动，但其游泳速度远低于不同运动的软机器人。本文设计了一种以柔性聚合物为材料，嵌入磁性颗粒并按特定方向磁化的非对称软机器人，在三维旋转磁场下实现了高游动速度的螺旋游泳运动。在磁场频率低于40 Hz时，机器人表现出滚动和瞬态运动，而在磁场频率高于40 Hz时，机器人表现出螺旋游泳运动。在49赫兹的磁场频率下，游动速度达到峰值，约为30毫米/秒。在此频率之外，由于机器人的旋转频率与驱动磁场的频率不匹配，软体机器人的游动速度下降。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 5: Dynamics, Vibration, and Control

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