A lightweight soft exosuit for gait assistance

2013 IEEE International Conference on Robotics and Automation Pub Date : 2013-05-06 DOI:10.1109/ICRA.2013.6631046

Michael F. Wehner, Brendan T. Quinlivan, P. Aubin, E. Martinez-Villalpando, Michael Baumann, L. Stirling, K. Holt, R. Wood, C. Walsh

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引用次数: 283

Abstract

In this paper we present a soft lower-extremity robotic exosuit intended to augment normal muscle function in healthy individuals. Compared to previous exoskeletons, the device is ultra-lightweight, resulting in low mechanical impedance and inertia. The exosuit has custom McKibben style pneumatic actuators that can assist the hip, knee and ankle. The actuators attach to the exosuit through a network of soft, inextensible webbing triangulated to attachment points utilizing a novel approach we call the virtual anchor technique. This approach is designed to transfer forces to locations on the body that can best accept load. Pneumatic actuation was chosen for this initial prototype because the McKibben actuators are soft and can be easily driven by an off-board compressor. The exosuit itself (human interface and actuators) had a mass of 3500 g and with peripherals (excluding air supply) is 7144 g. In order to examine the exosuit's performance, a pilot study with one subject was performed which investigated the effect of the ankle plantar-flexion timing on the wearer's hip, knee and ankle joint kinematics and metabolic power when walking. Wearing the suit in a passive unpowered mode had little effect on hip, knee and ankle joint kinematics as compared to baseline walking when not wearing the suit. Engaging the actuators at the ankles at 30% of the gait cycle for 250 ms altered joint kinematics the least and also minimized metabolic power. The subject's average metabolic power was 386.7 W, almost identical to the average power when wearing no suit (381.8 W), and substantially less than walking with the unpowered suit (430.6 W). This preliminary work demonstrates that the exosuit can comfortably transmit joint torques to the user while not restricting mobility and that with further optimization, has the potential to reduce the wearer's metabolic cost during walking.

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一个轻量级的柔软的外骨骼的步态辅助

在这篇论文中，我们提出了一种旨在增强健康个体正常肌肉功能的柔性下肢机器人外骨骼。与之前的外骨骼相比，该设备超轻，机械阻抗和惯性都很低。这套外骨骼服有定制的McKibben风格的气动执行器，可以帮助臀部、膝盖和脚踝。执行器通过软的、不可扩展的网状物连接到外服上，利用一种我们称之为虚拟锚技术的新方法与附着点形成三角形。这种方法旨在将力传递到身体上最能承受载荷的位置。最初的原型之所以选择气动驱动，是因为McKibben的执行器很软，可以很容易地由船外压缩机驱动。太空服本身(人机界面和执行器)的质量为3500g，其外围设备(不包括空气供应)的质量为7144g。为了检验外骨骼的性能，进行了一项有一名受试者的初步研究，研究了踝关节跖屈时间对穿着者行走时髋关节、膝关节和踝关节运动学和代谢力的影响。与不穿西装时的基线行走相比，在被动无动力模式下穿着西装对髋关节、膝关节和踝关节的运动学影响很小。在30%的步态周期中，在踝关节处插入致动器，持续250毫秒，对关节运动学的改变最小，代谢能力也最小。受试者的平均代谢功率为386.7 W，几乎与不穿套装时的平均代谢功率(381.8 W)相同，大大低于穿着无动力套装行走时的平均代谢功率(430.6 W)。这项初步工作表明，外骨骼服可以舒适地将关节扭矩传递给使用者，同时不限制行动能力，并且通过进一步优化，有可能降低穿着者在行走过程中的代谢成本。

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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2013 IEEE International Conference on Robotics and Automation

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