An autonomous, underactuated exoskeleton for load-carrying augmentation

2006 IEEE/RSJ International Conference on Intelligent Robots and Systems Pub Date : 2006-10-01 DOI:10.1109/IROS.2006.281932

C. Walsh, K. Pasch, H. Herr

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引用次数: 166

Abstract

Metabolic studies have shown that there is a metabolic cost associated with carrying load (T. M. Griffen, et al., 2003). In previous work, a lightweight, underactuated exoskeleton has been described that runs in parallel to the human and supports the weight of a payload (C. J. Walsh, et al., 2006). A state-machine control strategy is written based on joint angle and ground-exoskeleton force sensing to control the joint actuation at this exoskeleton hip and knee. The joint components of the exoskeleton in the sagittal plane consist of a force-controllable actuator at the hip, a variable-damper mechanism at the knee and a passive spring at the ankle. The control is motivated by examining human walking data. Positive, non-conservative power is added at the hip during the walking cycle to help propel the mass of the human and payload forward. At the knee, the damper mechanism is turned on at heel strike as the exoskeleton leg is loaded and turned off during terminal stance to allow knee flexion. The passive spring at the ankle engages in controlled dorsiflexion to store energy that is later released to assist in powered plantarflexion. Preliminary studies show that the state machines for the hip and knee work robustly and that the onset of walking can be detected in less than one gait cycle. Further, it is found that an efficient, underactuated leg exoskeleton can effectively transmit payload forces to the ground during the walking cycle

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一种自主的、欠驱动的外骨骼，用于增强负载

代谢研究表明，携带负荷存在代谢成本(T. M. Griffen, et al.， 2003)。在以前的工作中，已经描述了一种轻量级的、欠驱动的外骨骼，它与人体并行运行，并支持有效载荷的重量(C. J. Walsh等人，2006)。设计了一种基于关节角度和地面外骨骼力传感的状态机控制策略来控制外骨骼髋关节和膝关节的关节驱动。矢状面外骨骼的关节组件包括髋关节的力可控致动器，膝关节的可变阻尼机构和脚踝的被动弹簧。控制的动机是通过检查人类的行走数据。在步行周期中，臀部增加了积极的，非保守的力量，以帮助推动人体质量和有效载荷向前。在膝关节，当外骨骼腿被加载时，阻尼器机制在脚跟撞击时开启，在终端站立时关闭，以允许膝关节屈曲。踝关节处的被动弹簧参与控制背屈来储存能量，这些能量随后被释放以辅助动力跖屈。初步研究表明，髋关节和膝关节的状态机工作稳健，并且可以在不到一个步态周期内检测到步行的开始。此外，研究发现，一个高效的、欠驱动的腿部外骨骼可以在步行周期中有效地将有效载荷力传递到地面

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

2006 IEEE/RSJ International Conference on Intelligent Robots and Systems

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