通过动力下肢假肢装置的初步台架测试形成概念
Concept Through Preliminary Bench Testing of a Powered Lower Limb Prosthetic Device.
作者信息
Bergelin Bryan J, Mattos Javier O, Wells Joseph G, Voglewede Philip A
机构信息
Department of Mechanical Engineering, Marquette University, Milwaukee, WI 53233,
出版信息
J Mech Robot. 2010 Nov;2(4):41005-41013. doi: 10.1115/1.4002205.
Abstract
This paper outlines the design and testing of a powered ankle prosthesis, which utilizes a four-bar mechanism in conjunction with a spring and motor that mimics nonamputee (normal) ankle moments. This approach would enable transtibial (below the knee) amputees to walk at a normal speed with minimal energy input. The design takes into account the energy supplied by the wearer required to achieve many of the desired characteristics of a normal gait. A proof-of-concept prototype prosthesis was designed, optimized, fabricated, and tested with the purpose of demonstrating its ability to match crucial ankle moments during the stance phase of gait. Testing of this prosthesis proved crucial in determining the prosthesis' capabilities and in evaluating this approach.
摘要
本文概述了一种动力踝关节假肢的设计与测试,该假肢利用四杆机构结合弹簧和电机来模拟非截肢者(正常)的踝关节力矩。这种方法将使胫骨截肢者(膝盖以下)能够以最小的能量输入以正常速度行走。该设计考虑了穿戴者为实现正常步态的许多期望特征而提供的能量。设计了一个概念验证原型假肢,进行了优化、制造和测试,目的是证明其在步态站立阶段匹配关键踝关节力矩的能力。对该假肢的测试对于确定假肢的性能以及评估这种方法至关重要。
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