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一种用于额状面和矢状面辅助的具有并联驱动的轻型动力髋关节外骨骼。

A Lightweight Powered Hip Exoskeleton With Parallel Actuation for Frontal and Sagittal Plane Assistance.

作者信息

Archangeli Dante, Ortolano Brendon, Murray Rosemarie, Gabert Lukas, Lenzi Tommaso

机构信息

Department of Mechanical Engineering and the Robotics Center, University of Utah, Salt Lake City, UT 84112 USA.

Department of Mechanical Engineering and the Robotics Center, University of Utah, Salt Lake City, UT 84112 USA, and also with the Rocky Mountain Center for Occupational and Environmental Health, Salt Lake City, UT 84111 USA.

出版信息

IEEE Trans Robot. 2025 Feb;41:1-17. doi: 10.1109/tro.2025.3539172.

DOI:10.1109/tro.2025.3539172
PMID:40123650
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11926883/
Abstract

Wearable robots and powered exoskeletons may improve ambulation for millions of individuals with poor mobility. Powered exoskeletons primarily assist in the sagittal plane to improve walking efficiency and speed. However, individuals with poor mobility often have limited mediolateral balance, which requires torque generation in the frontal plane. Existing hip exoskeletons that assist in both the sagittal and frontal planes are too heavy and bulky for use in the real world. Here we present the kinematic model, mechatronic design, and benchtop and human testing of a powered hip exoskeleton with a unique parallel kinematic actuator. The exoskeleton is lightweight (5.3 kg), has a slim profile, and can generate 30 N·m and 20 N·m of torque during gait in the sagittal and frontal planes. The exoskeleton torque density is 5.7 N·m/kg-53% higher than previously possible with series kinematic design. Testing with five healthy subjects indicate that frontal plane torques applied during stance or swing can alter step width, while sagittal plane torque can assist with hip flexion and extension. A device with these characteristics may improve both gait economy and balance in the real world.

摘要

可穿戴机器人和动力外骨骼可以改善数百万行动不便者的行走能力。动力外骨骼主要在矢状面提供助力,以提高行走效率和速度。然而,行动不便的人往往中外侧平衡能力有限,这就需要在额状面产生扭矩。现有的在矢状面和额状面都能提供助力的髋部外骨骼过于沉重和庞大,无法在现实世界中使用。在此,我们展示了一种带有独特并联运动执行器的动力髋部外骨骼的运动学模型、机电一体化设计以及台式测试和人体测试。该外骨骼重量轻(5.3千克),外形纤薄,在矢状面和额状面行走时可分别产生30牛·米和20牛·米的扭矩。该外骨骼的扭矩密度为5.7牛·米/千克,比之前串联运动设计所能达到的扭矩密度高出53%。对五名健康受试者的测试表明,在站立或摆动过程中施加的额状面扭矩可以改变步幅宽度,而矢状面扭矩可以辅助髋部屈伸。具有这些特性的设备可能会在现实世界中改善步态经济性和平衡能力。

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Design, Characterization, and Preliminary Assessment of a Two-Degree-of-Freedom Powered Ankle-Foot Prosthesis.一种两自由度动力脚踝足假肢的设计、特性分析与初步评估
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Effect of hip abduction assistance on metabolic cost and balance during human walking.
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Sci Robot. 2023 Oct 25;8(83):eade0876. doi: 10.1126/scirobotics.ade0876.
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Abduction/Adduction Assistance From Powered Hip Exoskeleton Enables Modulation of User Step Width During Walking.动力髋外骨骼的外展/内收辅助可调节行走时用户的步宽。
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