缆索驱动踝关节康复机器人的设计优化与综合仿真分析

IF 1.7 Q2 REHABILITATION
Norsyakina Husain, M. N. Shah, K. Basaruddin, M. Ijaz, H. Takemura, S. Basah
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引用次数: 0

摘要

踝关节扭伤是医疗保健提供者最常见的诊断损伤,预计占运动医学损伤的30%,其中踝关节外侧扭伤是最常见的类型。踝关节损伤需要运动辅助来恢复活动能力,但物理治疗师通常只能在每次治疗中为一名患者提供康复治疗。近年来提出了许多机器人康复策略;然而,大多数设计都有一些局限性,比如要求病人坐着或站着不动。因此,本研究旨在开发一种紧凑型可穿戴机器人的概念设计和仿真,以帮助康复和训练目的的踝关节运动。该缆索驱动踝关节康复机器人的结构采用缆索驱动并联结构,使人体踝关节的活动范围(ROM)得到最大化的锻炼。通过形态图分析,探索踝关节康复装置设计发展的可能解决方案,并采用Pugh法确定最终设计方案。在SolidWorks中建立了该设计的三维可视化模型,进行了反运动学分析、轨迹仿真和电缆长度分析。通过仿真验证了踝关节康复机器人的可行性,发现该机器人能够满足踝关节康复进行有效ROM训练的要求。所提出的设计可能潜在地用于特定ROM的被动踝关节康复锻炼,特别是对于卧床不起的患者。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design Optimization and Integrated Simulation Analysis of a Cable-Driven Ankle Rehabilitation Robot
Sprained ankles are the most commonly diagnosed injury seen by healthcare providers and are projected to account for up to 30% of sports medicine injuries, with lateral ankle sprain being the most common type. Ankle injuries necessarily involve motion assistance to regain mobility, but physiotherapists are typically able to provide rehabilitation only for one patient at each session. Numerous robotic rehabilitation strategies have been proposed in recent years; however, most of the designs have some limitations such as requiring the patient to sit or stand still. Hence, this study aims to develop a conceptual design and simulation of a compact wearable robot in aiding ankle motion for rehabilitation and training purposes. The cable-driven parallel architecture used in the construction of the cable-driven ankle rehabilitation robot allows for the exercise of the human ankle’s range of motion (ROM) to be maximized. The morphological chart analysis was created to explore the possible solutions to the design development for the ankle rehabilitation device, and the final design was decided using the Pugh method. A three-dimensional model of the proposed design was visualized in SolidWorks to analyze the inverse kinematics, trajectory simulation and cable length analysis. The feasibility of the ankle rehabilitation robot was examined against the simulation and was found to meet the requirements for performing effective ROM exercises for ankle rehabilitation. The proposed design could potentially be used for passive ankle joint rehabilitation exercise in specific ROM, particularly for bedridden patients.
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来源期刊
CiteScore
3.20
自引率
0.00%
发文量
13
审稿时长
16 weeks
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