一种可穿戴机器人相互作用力的量化方法*

2018 7th IEEE International Conference on Biomedical Robotics and Biomechatronics (Biorob) Pub Date : 2018-08-01 DOI:10.1109/BIOROB.2018.8487701

Anna-Maria Georgarakis, R. Stämpfli, P. Wolf, R. Riener, Jaime E. Duarte

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引用次数: 9

摘要

由于运动障碍而导致的不动会导致许多对人的健康和生活质量构成威胁的继发性疾病。可穿戴的机器人移动辅助设备，如外骨骼和外骨骼，是解决不动问题的一种很有前途的技术。这些装置用手铐绑在人身上。然而，人机界面的物理交互尚未得到很好的理解。软组织的错位和压迫降低了机器人的工作效率和人体的舒适度。我们开发了一种测量方法，使我们能够同时测量袖带在法向和切向的相互作用力。在摩擦试验台对测量装置进行了验证。测试-重测可靠性是在一个孤立的附着袖带安装在人类前臂评估。力测量是可重复的，误差范围可达28.7%或7.8牛在法向，28.7%或2.3牛在切向。我们的方法是第一个同时测量可穿戴机器人物理界面上的法向力和切向力的方法。重测信度在仅评估法向力的方法范围内。

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A Method for Quantifying Interaction Forces in Wearable Robots*

Immobility due to movement impairments causes many secondary conditions that are a threat to a person's health and quality of life. Wearable robotic mobility aids such as exoskeletons and exosuits are a promising technique to tackle immobility. These devices are attached to the human with cuffs. However, the physical interaction at the human-robot interface is not yet well understood. Misplacement and compression of soft tissue diminish the efficiency of the robot and the comfort for the human. We developed a measurement method that allows us to simultaneously measure cuff interaction forces in normal and tangential direction. The measurement setup was validated in a friction test bench. The test-retest reliability was evaluated in an isolated attachment cuff mounted on a human forearm. Force measurements were repeatable, with error ranges up to 28.7% or 7.8 N in normal, 28.7% or 2.3 N in tangential direction. Our method is the first approach that simultaneously measures normal and tangential forces at the physical interface of wearable robots. The test-retest reliability is within the range of methods that assess only normal forces.

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来源期刊

2018 7th IEEE International Conference on Biomedical Robotics and Biomechatronics (Biorob)

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