R2poweR: The Proof-of-Concept of a Backdrivable, High-Ratio Gearbox for Human-Robot Collaboration*

2022 International Conference on Robotics and Automation (ICRA) Pub Date : 2022-05-23 DOI:10.1109/icra46639.2022.9811923

Pablo López-García, Stein Crispel, A. Varadharajan, Elias Saerens, T. Verstraten, B. Vanderborght, D. Lefeber

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引用次数: 2

Abstract

Robotic engineers face major challenges to solve the complex actuation needs of Human-Robot Collaboration with existing act robotic gearboxes. Available technologies comprise high-ratio Planetary Gearheads, Cycloid Drives and Harmonic Drives, inherited from conventional industrial robotics. Alternative approaches include Direct-Drive and Quasi Direct-Drive actuation strategies, which propose to cancel or substantially reduce gear ratio, in order to minimize reflected inertia and attain enough backdrivability for collaborative tasks. This paper presents the proof-of-concept validation of a novel high-ratio, Wolfrom-based, gearbox technology that follows a different approach to attain the same objective. Testing five different gearbox prototypes, we confirm the ability of the R2poweR technology to improve efficiency and backdrivability while retaining the weight and control advantages derived from the use of high reduction ratios. The result is a highly efficient, backdrivable, high-ratio gearbox with exciting Huma-Robot Collaboration potential.

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R2poweR:用于人机协作的反向驱动、高传动比变速箱的概念验证*

机器人工程师面临的主要挑战是如何利用现有的动作机器人齿轮箱来解决人机协作的复杂驱动需求。现有的技术包括高比率行星齿轮箱，摆线传动和谐波传动，从传统的工业机器人继承。替代方法包括直接驱动和准直接驱动驱动策略，它们建议取消或大幅降低传动比，以最大限度地减少反射惯性，并获得足够的反向驾驶能力来执行协作任务。本文介绍了一种基于wolfrom的新型高比率变速箱技术的概念验证，该技术采用不同的方法来实现相同的目标。通过测试五种不同的变速箱原型，我们证实了R2poweR技术在提高效率和反驾驶性能的同时，保留了高减速比带来的重量和控制优势。其结果是一个高效率、可反向驱动、高传动比的变速箱，具有令人兴奋的人-机器人协作潜力。

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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