2D-Compliant, Diamagnetic Levitating Micro-Robots for Operation on Non-Flat, Non-Clean Tracks

2022 International Conference on Manipulation, Automation and Robotics at Small Scales (MARSS) Pub Date : 2022-07-25 DOI:10.1109/MARSS55884.2022.9870462

A. Hsu, R. Pelrine, Rui de Gouvea Pinto, E. Schaler

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引用次数: 2

Abstract

We demonstrate techniques for fabricating 2D-compliant, magnetic micro-robots able to diamagnetically levitate and controllably maneuver over a non-flat and non-clean surfaces. These capabilities were first demonstrated in simulation–identifying passively-stable configurations of magnetic dipole arrays linked by compliant flexures, computing levitation force versus height, and exploring the design space of robot compliance and track curvature versus levitation height. A viable compliant micro-robot design was then fabricated and operated on curved graphite surfaces that are not traversable by rigid micro-robots. Separately, a non-compliant micro-robot was used to demonstrate partial abrasive particle clearing on a dirty track and then subsequent operation for >50,000 cycles / >600 m with no signs of wear. These advancements in diamagnetic micro-robot capabilities will enable applications of the technology in a broader range of environments (including beyond Earth) and size-scales (to support larger payloads).

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在非平坦、非清洁轨道上运行的二维抗磁悬浮微型机器人

我们展示了制造2d兼容的磁性微型机器人的技术，这些机器人能够在非平坦和非清洁的表面上抗磁悬浮和可控地机动。这些能力首先在仿真中得到了证明——识别由柔性挠性连接的磁偶极子阵列的被动稳定构型，计算悬浮力与高度的关系，以及探索机器人顺应性和轨道曲率与悬浮高度的设计空间。然后制作了一个可行的柔性微机器人设计，并在刚性微机器人无法穿越的弯曲石墨表面上运行。另外，一个不符合要求的微型机器人在肮脏的轨道上演示了部分磨粒的清除，然后进行了>50,000次/ >600米的后续操作，没有磨损迹象。这些抗磁微型机器人能力的进步将使该技术应用于更广泛的环境(包括地球以外)和尺寸(以支持更大的有效载荷)。

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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2022 International Conference on Manipulation, Automation and Robotics at Small Scales (MARSS)

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