Design of a novel above-knee prosthetic leg with a passive energy-saving mechanism

Q2 Materials Science

Engineering Solid Mechanics Pub Date : 2023-01-01 DOI:10.5267/j.esm.2023.5.009

A. Imran, M. Haghjoo, B. Beigzadeh

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引用次数: 1

Abstract

The push-off phase is a critical part of initiating movement during walking, and it requires a significant amount of energy. Recent research has shown that the passive use of springs in parallel with the leg can harvest the push-off energy and reduce the total metabolic energy of walking for healthy subjects. In this study, we present the design of a prosthetic leg with a passive-based mechanism to reduce walking energy consumption for above-knee amputees. The mechanism stores energy during the stance phase of the gait cycle and releases it to support the prosthetic leg during locomotion. The known polycentric knee joint 3R36 and the ankle-foot joint ESAR were chosen and adopted for this study. We also utilized a ratchet clutch that connects with a spring and rope from the pylon to the foot which regulates movement and saves energy. Our simulations demonstrate that the spring stores elastic energy from approximately 22% of the gait cycle and reaches its maximum energy storage at approximately 50% of the walking cycle. The energy is then released at approximately 58% of the stride cycle during the push-off phase. The motion of the proposed prosthetic leg for individuals with transfemoral amputations mimics the normal walking pattern of healthy individuals well.

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一种新型被动节能机构膝上假腿的设计

蹬离阶段是步行过程中开始运动的关键部分，它需要大量的能量。最近的研究表明，对于健康的人来说，与腿平行被动使用弹簧可以收获推离能量，减少行走的总代谢能量。在这项研究中，我们设计了一种基于被动机制的假肢，以减少膝盖以上截肢者的行走能量消耗。该机构在步态周期的站立阶段储存能量，并在运动期间释放能量以支持假肢。本研究选择已知的多中心膝关节3R36和踝足关节ESAR。我们还使用了棘轮离合器，它连接着从塔到脚的弹簧和绳子，以调节运动并节省能量。我们的仿真表明，弹簧存储了大约22%的步态周期的弹性能量，并在大约50%的步行周期达到最大能量存储。在推离阶段，能量在步幅周期的58%左右释放。拟建的经股截肢患者假腿的运动很好地模仿了健康人的正常行走模式。

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

Engineering Solid Mechanics Materials Science-Metals and Alloys

CiteScore

3.00

自引率

0.00%

发文量

期刊介绍： Engineering Solid Mechanics (ESM) is an online international journal for publishing high quality peer reviewed papers in the field of theoretical and applied solid mechanics. The primary focus is to exchange ideas about investigating behavior and properties of engineering materials (such as metals, composites, ceramics, polymers, FGMs, rocks and concretes, asphalt mixtures, bio and nano materials) and their mechanical characterization (including strength and deformation behavior, fatigue and fracture, stress measurements, etc.) through experimental, theoretical and numerical research studies. Researchers and practitioners (from deferent areas such as mechanical and manufacturing, aerospace, railway, bio-mechanics, civil and mining, materials and metallurgy, oil, gas and petroleum industries, pipeline, marine and offshore sectors) are encouraged to submit their original, unpublished contributions.