有源电动膝关节和踝关节假肢的设计与控制

Design and Control of an Active Electrical Knee and Ankle Prosthesis.

作者信息

Sup Frank, Varol Huseyin Atakan, Mitchell Jason, Withrow Thomas, Goldfarb Michael

机构信息

Department of Mechanical Engineering, Vanderbilt University, Nashville, TN 37235 USA.

出版信息

Proc IEEE RAS EMBS Int Conf Biomed Robot Biomechatron. 2008 Oct 19;2008:523-528. doi: 10.1109/BIOROB.2008.4762811.

DOI:10.1109/BIOROB.2008.4762811

PMID:20648239

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2906131/

Abstract

This paper presents an overview of the design and control of an electrically powered knee and ankle prosthesis. The prosthesis design incorporates two motor-driven ball screw units to drive the knee and ankle joints. A spring in parallel with the ankle motor unit is employed to decrease the power consumption and increase the torque output for a given motor size. The device's sensor package includes a custom load cell to measure the sagittal socket interface moment above the knee joint, a custom sensorized foot to measure the ground reaction force at the heel and ball of the foot, and commercial potentiometers and load cells to measure joint positions and torques. A finite-state based impedance control approach, previously developed by the authors, is used and experimental results on level treadmill walking are presented that demonstrate the potential of the device to restore normal gait. The experimental power consumption of the device projects a walking distance of 5.0 km at a speed of 2.8 km/hr with a lithium polymer battery pack.

摘要

本文概述了一种电动膝关节和踝关节假肢的设计与控制。该假肢设计包含两个电机驱动的滚珠丝杠单元，用于驱动膝关节和踝关节。在踝关节电机单元并联一个弹簧，以降低功耗，并在给定电机尺寸下增加扭矩输出。该装置的传感器套件包括一个定制的测力传感器，用于测量膝关节上方矢状窝接口力矩；一个定制的传感足部，用于测量足跟和脚掌处的地面反作用力；以及用于测量关节位置和扭矩的商用电位器和测力传感器。采用了作者之前开发的基于有限状态的阻抗控制方法，并给出了在水平跑步机上行走的实验结果，证明了该装置恢复正常步态的潜力。该装置的实验功耗表明，使用锂聚合物电池组时，以2.8公里/小时的速度可行走5.0公里的距离。

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