A Pneumatic Soft Exoskeleton System Based on Segmented Composite Proprioceptive Bending Actuators for Hand Rehabilitation.

IF 3.4 3区 医学 Q1 ENGINEERING, MULTIDISCIPLINARY Biomimetics Pub Date : 2024-10-18 DOI:10.3390/biomimetics9100638
Kai Li, Daohui Zhang, Yaqi Chu, Xingang Zhao, Shuheng Ren, Xudong Hou
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Abstract

Soft pneumatic actuators/robotics have received significant interest in the medical and health fields, due to their intrinsic elasticity and simple control strategies for enabling desired interactions. However, current soft hand pneumatic exoskeletons often exhibit uniform deformation, mismatch the profile of the interacting objects, and seldom quantify the assistive effects during activities of daily life (ADL), such as extension angle and predicted joint stiffness. The lack of quantification poses challenges to the effective and sustainable advancement of rehabilitation technology. This paper introduces the design, modeling, and testing of pneumatic bioinspired segmented composite proprioceptive bending actuators (SCPBAs) for hand rehabilitation in ADL tasks. Inspired by human finger anatomy, the actuator's soft-joint-rigid-bone segmented structure provides a superior fit compared to continuous structures in traditional fiber-reinforced actuators (FRAs). A quasi-static model is established to predict the bending angles based on geometric parameters. Quantitative evaluations of predicted joint stiffness and extension angle utilizing proprioceptive bending are performed. Additionally, a soft under-actuated hand exoskeleton equipped with SCPBAs demonstrates their potential in ADL rehabilitation scenarios.

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用于手部康复的基于分段式复合感知弯曲执行器的气动软外骨架系统
软气动致动器/机器人因其固有的弹性和简单的控制策略而在医疗和健康领域备受关注。然而,目前的软手气动外骨骼通常表现出均匀变形,与交互对象的轮廓不匹配,而且很少量化日常生活(ADL)活动中的辅助效果,如伸展角度和预测的关节僵硬度。缺乏量化对康复技术的有效和可持续发展构成了挑战。本文介绍了气动生物启发分段式复合本体感觉弯曲致动器(SCPBAs)的设计、建模和测试,用于在 ADL 任务中进行手部康复。受人体手指解剖学启发,与传统纤维增强致动器(FRA)中的连续结构相比,该致动器的软关节-刚性骨分段结构具有更好的贴合性。根据几何参数建立了一个准静态模型来预测弯曲角度。利用本体感觉弯曲对预测的关节刚度和伸展角度进行了定量评估。此外,配备 SCPBA 的软下驱动手部外骨骼展示了其在 ADL 康复场景中的潜力。
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来源期刊
Biomimetics
Biomimetics Biochemistry, Genetics and Molecular Biology-Biotechnology
CiteScore
3.50
自引率
11.10%
发文量
189
审稿时长
11 weeks
期刊最新文献
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