Design and Driving Performance Study of Soft Actuators for Hand Rehabilitation Training.

IF 1.3 Q4 ENGINEERING, BIOMEDICAL
Medical Devices-Evidence and Research Pub Date : 2024-06-26 eCollection Date: 2024-01-01 DOI:10.2147/MDER.S476464
Zhilin Zhang, Aldrin D Calderon, Xingyu Huang, Guixian Wu, Chuanjian Liang
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引用次数: 0

Abstract

Purpose: To address the application requirements of soft actuators in rehabilitation training gloves, and in combination with ergonomic requirements, we designed a segmented soft actuator with bending and elongation modules. This actuator can achieve independent or coupled movements of the finger joints.

Methods: A finite element model of the joint actuator was established to compare the driving performance of actuators with different structural forms. Numerical calculations were used to analyze the effects of structural size parameters on the bending characteristics and end output force of the actuator. The design was then refined based on these analyses.

Results: The joint actuator designed in this study demonstrated a 71% increase in bending angle compared to the standard fast pneumatic network structure. Key factors affecting the driving performance include the thickness of the constraint layer, the inner wall thickness of the chamber, chamber height, chamber width, chamber spacing, chamber length, and the number of chambers. After improvements, the bending angle of the joint actuator increased by 60.6%, and the output force increased by 145.9%, indicating significant improvement.

Conclusion: This study designed and improved a soft actuator for hand rehabilitation training, achieving independent and coupled joint movements. The bending angle, bending shape, and joint driving force of the soft actuator meet the requirements for finger rehabilitation training.

用于手部康复训练的软促动器的设计和驾驶性能研究
目的:为了满足软推杆在康复训练手套中的应用要求,并结合人体工程学要求,我们设计了一种带有弯曲和伸长模块的分段式软推杆。该推杆可实现手指关节的独立或耦合运动:方法:建立了关节致动器的有限元模型,以比较不同结构形式的致动器的驱动性能。数值计算用于分析结构尺寸参数对致动器弯曲特性和末端输出力的影响。然后在这些分析的基础上对设计进行了改进:结果:与标准快速气动网络结构相比,本研究中设计的关节致动器的弯曲角度增加了 71%。影响驱动性能的关键因素包括约束层厚度、腔室内壁厚度、腔室高度、腔室宽度、腔室间距、腔室长度和腔室数量。改进后,关节致动器的弯曲角度增加了 60.6%,输出力增加了 145.9%,改进效果显著:本研究设计并改进了一种用于手部康复训练的软推杆,实现了独立和耦合的关节运动。软推杆的弯曲角度、弯曲形状和关节驱动力均符合手指康复训练的要求。
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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来源期刊
Medical Devices-Evidence and Research
Medical Devices-Evidence and Research ENGINEERING, BIOMEDICAL-
CiteScore
2.80
自引率
0.00%
发文量
41
审稿时长
16 weeks
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