A Cable Driven Robotic System to Train Finger Function After Stroke

2007 IEEE 10th International Conference on Rehabilitation Robotics Pub Date : 2007-06-13 DOI:10.1109/ICORR.2007.4428430

L. Dovat, O. Lambercy, V. Johnson, B. Salman, S. Wong, R. Gassert, E. Burdet, T. C. Leong, T. Milner

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引用次数: 27

Abstract

This paper presents a novel robotic interface to train intrinsic finger movements. The mechanical design, base on a cable system interacting with the fingers, offers the possibility of adapting the interface to accommodate various hand sizes and finger orientation. A main feature of the device is a clutch system, which consists of five clutches, one for each finger, that can be switched to three different modes: ( rest mode: the fingers are mechanically maintained at a fixed position, (ii) passive (from the view of the interface) mode: the finger is free to move along the path defined by the cable, and (iii) active mode: the force generated by the motor is applied to the finger.) With this mechanism, it is possible to train hand muscle function using only one actuator. The interaction wit the subject is measured by means of a position encoder an five force sensors located close to the output. We describe the human-oriented design of our underactuated robotic interface based on measured biomechanics. We detail the redundant safety mechanisms, the actuation, sensing and control system and report the performance and preliminary results obtained with this interface.

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用缆绳驱动的机器人系统训练中风后的手指功能

本文提出了一种新的机器人界面来训练手指的内在运动。机械设计基于与手指交互的电缆系统，提供了调整界面以适应不同手的大小和手指方向的可能性。该装置的一个主要特点是离合器系统，它由五个离合器组成，每个手指一个，可以切换到三种不同的模式:(休息模式:手指机械地保持在固定位置，(ii)被动(从界面的角度来看)模式:手指沿着电缆定义的路径自由移动，(iii)主动模式:由电机产生的力应用于手指。)有了这个机制，就可以只用一个执行器来训练手部肌肉功能。通过位置编码器和靠近输出端的五个力传感器来测量与受试者的相互作用。我们描述了基于测量生物力学的欠驱动机器人界面的人性化设计。我们详细介绍了冗余安全机构、驱动、传感和控制系统，并报告了该接口的性能和初步结果。

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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2007 IEEE 10th International Conference on Rehabilitation Robotics

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