Design and Modeling of a Spherical Robot Actuated by a Cylindrical Drive

2022 International Conference on Robotics and Automation (ICRA) Pub Date : 2022-05-23 DOI:10.1109/icra46639.2022.9812148

Bruno Belzile, D. St-Onge

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引用次数: 1

Abstract

Rolling spherical robots have been studied in the past few years as an alternative to legged and wheeled robots in unstructured environments. These systems are of uttermost interest for space exploration: fast, robust to collision and able to handle various terrain topologies. This paper introduces a novel barycentric spherical robot, dubbed the Autonomous Robotic Intelligent Explorer Sphere (ARIES). Equipped with an actuated cylindrical joint acting as a pendulum with two degrees-of-freedom (DoF), the ARIES has a continuous differential transmission to allow simultaneous rolling and steering. This mechanism allows an unprecedented mass allocation optimization, notably to provide a low center of mass. Kinematics and dynamics of this novel system are detailed. An analysis of the steering mechanism proves that it is more efficient than a more conventional 2-DoF tilting mechanism, while also retaining more space for a payload, for instance to host sensors for simultaneous localization and mapping, in the upper part of the sphere. Moreover, the kinematic input/output equations obtained significantly simplify the device's control. Finally, we present a first complete prototype with preliminary experimental tests.

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圆柱驱动球形机器人的设计与建模

在过去的几年里，滚动球形机器人作为腿式和轮式机器人在非结构化环境中的替代方案得到了研究。这些系统对太空探索至关重要:速度快，抗碰撞能力强，能够处理各种地形拓扑。本文介绍了一种新型质心球形机器人——自主机器人智能探测球(ARIES)。ARIES配备了一个驱动的圆柱形关节，作为一个具有两个自由度(DoF)的钟摆，它有一个连续的差动传动，可以同时滚动和转向。这种机制允许前所未有的质量分配优化，特别是提供低质心。详细介绍了该系统的运动学和动力学特性。对转向机构的分析证明，它比传统的2-DoF倾斜机构更有效，同时还为有效载荷保留了更多空间，例如，在球体的上部容纳用于同时定位和绘图的传感器。此外，所得到的运动输入/输出方程大大简化了设备的控制。最后，我们提出了一个完整的原型和初步的实验测试。

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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2022 International Conference on Robotics and Automation (ICRA)

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