Locomotion Analysis and Experiment for Climbing Motion of RPRS

Proceedings of the 2005 IEEE International Conference on Robotics and Automation Pub Date : 2005-04-18 DOI:10.1109/ROBOT.2005.1570422

Liping Zhang, Shugen Ma, Bin Li, Guowei Zhang, Xinyuan He, Minghui Wang, Zhengyu Zhang, Bing-gang Cao

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引用次数: 4

Abstract

A new Reconfigurable Planetary Robot System (RPRS) is introduced in this paper. The locomotion mechanism, especially the static force analysis and the climbing ability for different configurations of the multiple child-robots are presented in detail. The basic configurations of two child-robots systems were given in three modes: connecting in series with arm in front or back and combining to a loop with grasper. The simulation results of these three configurations based on static analysis demonstrate that the climbing ability is closely correlated to their configurations. Compared the results, the conclusion can be obtained that the loop configuration has the best effect than others on slope climbing. The actual experiments of the child-robots system have illustrated the simulating results, and an exciting phenomenon has emerged, which shows that all the configurations can climb bigger gradient than the simulating results. The phenomenon rightly discloses the characteristic of the novel architecture of the child-robot.

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RPRS攀爬运动分析与实验

介绍了一种新的可重构行星机器人系统(RPRS)。详细介绍了多个子机器人在不同构型下的运动机理，特别是静力分析和攀爬能力。给出了两个子机器人系统的基本结构，分别采用臂前后串联和手握环组合三种方式。基于静力分析的三种构型的仿真结果表明，爬坡能力与其构型密切相关。结果表明，环形结构对爬坡效果最好。子机器人系统的实际实验验证了仿真结果，并出现了一个令人兴奋的现象，即所有构型都能比仿真结果爬升更大的梯度。这一现象正确地揭示了子机器人的新架构的特点。

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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Proceedings of the 2005 IEEE International Conference on Robotics and Automation

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