Design and Experimental Evaluation of a Non-anthropomorphic Passive Load-carrying Exoskeleton

2021 6th IEEE International Conference on Advanced Robotics and Mechatronics (ICARM) Pub Date : 2021-07-03 DOI:10.1109/ICARM52023.2021.9536203

Zhijie Zhou, Wenbin Chen, Hao Fu, Xiang Fang, C. Xiong

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引用次数: 2

Abstract

Soldiers are often required to carry heavy loads during long distance march. Such load carriage can easily induce joint injuries and foot blisters, which further reduce the wearer’s task performance. To assist human walking with load carriage, various types of robotic devices are proposed, such as powered exoskeletons, supernumerary robotic limbs and suspended backpacks. However, these devices have individual shortcomings. This paper proposes a non-anthropomorphic passive load-carrying exoskeleton, which can dynamically support the carried load during the walking rhythm via a passive legged structure. This exoskeleton can reduce the load borne by human without energy input. The simple and passive structure design brings the highest robustness and flexibility. The simulation based on the mathematic model shows that the exoskeleton can reduce the foot pressure of the users. Such analysis results are also verified by the walking experiment. The experiment results show that the exoskeleton can transfer on average 68.0% of the load to the ground while standing, and 24.6% of the load while walking. The maximum load is reduced by 22.1% during walking.

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非拟人化被动负重外骨骼的设计与实验评价

在长途行军中，士兵经常被要求搬运重物。这样的负重很容易引起关节损伤和足部起泡，进一步降低了穿着者的工作表现。为了辅助人类负重行走，提出了多种类型的机器人装置，如动力外骨骼、附加机械臂和悬挂式背包。然而，这些设备都有各自的缺点。提出了一种非拟人化被动负重外骨骼，该外骨骼通过被动腿结构在行走节奏中动态支撑负重。这种外骨骼可以在没有能量输入的情况下减轻人体所承受的负荷。简单被动的结构设计带来了最高的坚固性和灵活性。基于数学模型的仿真结果表明，该外骨骼能够减轻使用者的足部压力。该分析结果也通过步行实验得到了验证。实验结果表明，站立时外骨骼平均能将68.0%的载荷传递给地面，行走时平均能将24.6%的载荷传递给地面。行走时最大负荷减少22.1%。

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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2021 6th IEEE International Conference on Advanced Robotics and Mechatronics (ICARM)

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