Prototype design and performance tests of Beijing's astronaut robot

Zeyuan Sun; Hui Li; Zhihong Jiang; Zhenzi Song; Yang Mo; Marco Ceccarelli

doi:10.3390/app8081342

Prototype design and performance tests of Beijing's astronaut robot

Zeyuan Sun, Hui Li^*, Zhihong Jiang, Zhenzi Song, Yang Mo, Marco Ceccarelli

^*Corresponding author for this work

School of Mechatronical Engineering

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

This paper proposes a novel chameleon-like astronaut robot that is designed to assist, or even substitute, a human astronauts in a space station to complete dangerous and prolonged work, such as maintenance of solar panels, and so on. The robot can move outside the space station freely via the hundreds of aluminum handrails, which are provided to help astronauts move. The robot weighs 30 kilograms, and consists of a torso, three identical 4-degree of freedom (DOF) arms, three end effectors, and three monocular vision system on each end effector. Via multi-arm associated motion, the robot can realize three kinds of motion modes: walking, rolling, and sliding. Numerous experiments have been conducted in a simulation environment and a ground verification platform. Experimental results reveal that this robot has excellent motion performance.

Original language	English
Article number	1342
Journal	Applied Sciences (Switzerland)
Volume	8
Issue number	8
DOIs	https://doi.org/10.3390/app8081342
Publication status	Published - 10 Aug 2018

Keywords

Chameleon
End effector
Hybrid bionic robot
Space robot

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10.3390/app8081342

Cite this

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abstract = "This paper proposes a novel chameleon-like astronaut robot that is designed to assist, or even substitute, a human astronauts in a space station to complete dangerous and prolonged work, such as maintenance of solar panels, and so on. The robot can move outside the space station freely via the hundreds of aluminum handrails, which are provided to help astronauts move. The robot weighs 30 kilograms, and consists of a torso, three identical 4-degree of freedom (DOF) arms, three end effectors, and three monocular vision system on each end effector. Via multi-arm associated motion, the robot can realize three kinds of motion modes: walking, rolling, and sliding. Numerous experiments have been conducted in a simulation environment and a ground verification platform. Experimental results reveal that this robot has excellent motion performance.",

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AU - Li, Hui

AU - Jiang, Zhihong

AU - Song, Zhenzi

AU - Mo, Yang

AU - Ceccarelli, Marco

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AB - This paper proposes a novel chameleon-like astronaut robot that is designed to assist, or even substitute, a human astronauts in a space station to complete dangerous and prolonged work, such as maintenance of solar panels, and so on. The robot can move outside the space station freely via the hundreds of aluminum handrails, which are provided to help astronauts move. The robot weighs 30 kilograms, and consists of a torso, three identical 4-degree of freedom (DOF) arms, three end effectors, and three monocular vision system on each end effector. Via multi-arm associated motion, the robot can realize three kinds of motion modes: walking, rolling, and sliding. Numerous experiments have been conducted in a simulation environment and a ground verification platform. Experimental results reveal that this robot has excellent motion performance.

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Prototype design and performance tests of Beijing's astronaut robot

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Keywords

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