4.7 Article

Low-resistance, high-force, and large-ROM fabric-based soft elbow exosuits with adaptive mechanism and composite bellows

Journal

SCIENCE CHINA-TECHNOLOGICAL SCIENCES
Volume 66, Issue 1, Pages 24-32

Publisher

SCIENCE PRESS
DOI: 10.1007/s11431-022-2233-3

Keywords

wearable robots; rehabilitation robots; soft robot applications; soft actuators design

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Fabric-based pneumatic exosuits have the potential to assist and rehabilitate elbow impairments. However, existing exosuits often have mechanical resistance issues that limit their performance. In this study, we develop a fabric-based soft elbow exosuit with an adaptive mechanism and composite bellows to address these challenges. Experimental results show that the exosuit with the adaptive mechanism and composite bellows significantly reduces mechanical resistance and increases output torque, providing improved range of motion and comfortability.
Due to the lightweight and compliance, fabric-based pneumatic exosuits are promising in the assistance and rehabilitation of elbow impairments. However, existing elbow exosuits generally suffer from remarkable mechanical resistance on the flexion of the elbow, thus limiting the output force, range of motion (ROM), and comfortability. To address these challenges, we develop a fabric-based soft elbow exosuit with an adaptive mechanism and composite bellows in this work. With the elbow kinesiology considered, the adaptive mechanism is fabricated by sewing the interface of the exosuit into spring-like triangle pleats, following the profile of the elbow to elongate or contract when the elbow flexes or extends. The composite bellows are implemented by further sealing a single blade of bellows into two branches to enhance the output force. Based on these structural features, we characterize the mechanical performance of different soft elbow exosuits: exosuit with normal bellows-NB, exosuit with adaptive mechanism and normal bellows-AMNB, exosuit with adaptive mechanism and composite bellows-AMCB. Experimental results demonstrate that by comparing with NB, the mechanical resistance of AMNB and AMCB decreases by 80.6% and 78.6%, respectively; on the other hand, the output torque of AMNB and AMCB increases to 120.3% and 207.0%, respectively, at 50 kPa when the joint angle is 120 degrees. By wearing these exosuits on a wooden arm model (1.25 kg), we further verify that AMCB can cover a full ROM of 0 degrees-130 degrees at the elbow with 500 g weight. Finally, the application on a health volunteer with AMCB shows that when the volunteer flexes the elbow to lift a weight of 500 g, the sEMG activity of the biceps and triceps is markedly reduced.

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