微型管道机器人的设计与验证

2020 IEEE International Conference on Artificial Intelligence and Information Systems (ICAIIS) Pub Date : 2020-03-01 DOI:10.1109/ICAIIS49377.2020.9194827

Kai-Lung Bai, Chaodong Li, Lexian Li, Cong Xi

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引用次数: 0

摘要

本文提出了一种外径为46mm，重量为28.6g的微型管道机器人。微管机器人主要由本体、电磁螺线管、弹簧、导向支撑脚等组成。通过对微管机器人的步态分析、虚拟样机的多体动力学仿真和惯性冲击原理的实验验证，验证了惯性冲击驱动原理和直接作用电磁铁驱动的可行性。在单电磁铁无负载驱动下进行的实验表明，微管道机器人在内径为51mm、锯齿波频率为10Hz的水平管道中最高速度可达60.290mm/s。

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Design and verification of a micro pipe robot

This paper proposes a micro pipe robot with an outer diameter of 46mm and a weight of 28.6g. The micro pipe robot is mainly composed of a body, an electromagnetic solenoid, a spring, and a guide support foot. The principle of inertial impact driving and the feasibility of a direct-acting electromagnet drive are all proved by the gait analysis of the micro pipe robot, multi-body dynamics simulation of the virtual prototype and the experiment verification of the inertial impact principle. Experiments with a single electromagnet is driven without a load show that the micro pipe robot can achieve a maximum speed of 60.290mm/s in a horizontal pipe with a 10Hz sawtooth wave and an inner diameter of 51mm.

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2020 IEEE International Conference on Artificial Intelligence and Information Systems (ICAIIS)

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