Small Parallel Cable-Driven Robot Based on TCPF Design and Control Research

2022 IEEE International Conference on Real-time Computing and Robotics (RCAR) Pub Date : 2022-07-17 DOI:10.1109/RCAR54675.2022.9872245

C. Liu, Chuxiong Hu, Zhanguang Liu, Haoge Han, Ze Wang

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Abstract

Thanks to the stable and precision control characteristics of parallel cable-driven mechanisms, cable-driven parallel robots have an extremely wide range of industrial applications. These advantages can also be used to describe a millimeter-sized cable-driven parallel mechanism, therefore, we can develop a miniature cable-driven parallel robot to undertake stable and precise processing or operation beneath small scale. In this paper, a cable-driven robot "MicroCable" that operates in millimeter-scale dimensions is introduced, with detailed design and manufacturing process. This $45\times 50\times 90mm$ robot has a total mass of 28g, a payload of $\geq$50g, and an operating accuracy of $\leq$lmm in a working space of $20mm\times 23mm\times 16mm$. It is driven by three 60mm-long artificial muscles with a maximum deformation of $\geq$33% for a single artificial muscle, a payload of $\geq$50g, and a self-weight of only 0. 5g. We have verified the controllability of the cable-driven mechanism with artificial muscles at millimeter dimensions, and look forward to its potential applications in future microassembly, micromedicine, microprinting, etc.

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基于TCPF的小型并联缆索驱动机器人设计与控制研究

由于并联缆索驱动机构稳定、精确的控制特性，使得缆索驱动并联机器人在工业上有着极其广泛的应用。这些优点也可以用来描述毫米级的电缆驱动并联机构，因此，我们可以开发一种微型电缆驱动并联机器人，在小尺度下进行稳定和精确的加工或操作。本文介绍了一种以毫米尺度为工作尺度的缆索驱动机器人“MicroCable”，并给出了详细的设计和制造过程。这个$45\times 50\times 90mm$机器人的总质量为28g，有效载荷为$\geq$ 50g，在$20mm\times 23mm\times 16mm$的工作空间内的操作精度为$\leq$ lmm。由3块60mm长的人造肌肉驱动，最大变形量$\geq$ 33% for a single artificial muscle, a payload of $\geq$50g, and a self-weight of only 0. 5g. We have verified the controllability of the cable-driven mechanism with artificial muscles at millimeter dimensions, and look forward to its potential applications in future microassembly, micromedicine, microprinting, etc.

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2022 IEEE International Conference on Real-time Computing and Robotics (RCAR)

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