HubRobo: A Lightweight Multi-Limbed Climbing Robot for Exploration in Challenging Terrain

2020 IEEE-RAS 20th International Conference on Humanoid Robots (Humanoids) Pub Date : 2021-07-19 DOI:10.1109/HUMANOIDS47582.2021.9555799

Kentaro Uno, Naomasa Takada, T. Okawara, Keigo Haji, Arthur Candalot, Warley F. R. Ribeiro, K. Nagaoka, Kazuya Yoshida

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引用次数: 11

Abstract

This study presents the design and sequential control strategies of a novel lightweight climbing robot. The quadruped robot with a left–right and front–hind symmetric insect-type configuration has three degrees of freedom (3-DOF) actuated joints in each limb, a 3-DOF passive compliant spine gripper at each foot, and an actuator to open/close the gripper. First, we present the mechanical design and minimal hardware integration of the robot, which have helped successfully reduce the entire mass of the robot to 3 kg with a base height of 0.16 m. Next, a sequential strategy to process stable climbing locomotion is introduced. The implemented software architecture that realizes climbing motion is described. With the successful result of a teleoperation experiment on an indoor test field simulating the Martian uneven slalom (local max. inclination: 45°), we proved that the proposed sequential control strategy enables the robot to stably climb challenging terrain.

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HubRobo:一种用于挑战地形探索的轻型多肢攀爬机器人

研究了一种新型轻型攀爬机器人的设计和顺序控制策略。该四足机器人具有左右前后对称的昆虫型结构，每个肢体有三个自由度(3-DOF)驱动关节，每只脚有一个3-DOF被动柔性脊柱夹持器，以及一个打开/关闭夹持器的驱动器。首先，我们介绍了机器人的机械设计和最小的硬件集成，这有助于成功地将机器人的整体质量降低到3千克，基座高度为0.16米。其次，介绍了一种处理稳定爬坡运动的顺序策略。描述了实现攀爬运动的软件体系结构。在模拟火星不均匀回转的室内试验场上进行了远程操作实验，取得了成功的结果。倾角为45°)，我们证明了所提出的顺序控制策略能够使机器人稳定地爬上具有挑战性的地形。

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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来源期刊

2020 IEEE-RAS 20th International Conference on Humanoid Robots (Humanoids)

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