High strength bubble artificial muscles for walking assistance

2018 IEEE International Conference on Soft Robotics (RoboSoft) Pub Date : 2018-04-24 DOI:10.1109/ROBOSOFT.2018.8404950

R. S. Diteesawat, T. Helps, M. Taghavi, J. Rossiter

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引用次数: 14

Abstract

We present a high strength artificial muscle for inclusion in an orthotic device that can deliver power at the knee joint with the aim of improving knee flexion in people with reduced mobility. The bubble artificial muscle (BAM) was developed by adapting traditional pleated pneumatic artificial muscles to achieve high contraction and tensile force. Initial gravimetric evaluation of a single BAM was performed, achieving a contraction of 23.7% while lifting a mass of 2.5 kg (over 100 times the mass of the actuator). To demonstrate the actuator's suitability for an orthosis, a device consisting of three parallel BAMs was tested with a physical pendular leg model based upon a human leg. A maximum knee flexion of 47.25 degrees was achieved, about 70% of the peak knee flexion of the average of young healthy subjects (68 degrees). 8.19 Nm of torque was delivered during testing, which is approximately 33% of the knee flexion moment during swing phase of a gait cycle. This high moment is achieved despite the low mass of the device (206.6 g). This work shows the suitability of BAMs for wearable orthotic devices such as soft assistive suits, where softness, lightness and high stress and strain are essential.

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高强度气泡人造肌肉，辅助行走

我们提出了一种高强度的人造肌肉，用于矫形装置，可以在膝关节处提供力量，目的是改善行动不便者的膝关节屈曲。气泡人工肌肉(BAM)是在传统的打褶气动人工肌肉的基础上发展起来的，具有较高的收缩力和拉伸力。对单个BAM进行了初步的重力评估，在提升2.5 kg(超过驱动器质量的100倍)的同时，实现了23.7%的收缩。为了证明该驱动器适用于矫形器，采用基于人腿的物理摆腿模型测试了由三个平行bam组成的装置。最大膝关节屈曲度为47.25度，约为年轻健康受试者平均膝关节屈曲度峰值(68度)的70%。测试过程中产生的扭矩为8.19 Nm，约为步态周期摆动阶段膝关节屈曲力矩的33%。尽管该设备的质量很低(206.6 g)，但仍实现了这一高力矩。这项工作表明，bam适用于柔软辅助服等可穿戴矫形设备，在这些设备中，柔软、轻盈和高应力和应变是必不可少的。

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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2018 IEEE International Conference on Soft Robotics (RoboSoft)

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