[Structural Design and Analysis of Portable Intelligent Wheelchair for Knee Rehabilitation].

Q4 Medicine
Dongmei Ma, Jingyan Wang, Liming Pan, Jinshi Chen, Tianyue Chu, Lei Huang, Baoyue Yin, Xin Xu
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引用次数: 0

Abstract

Objective: In order to address the issues of inconvenience, high medical costs, and lack of universality associated with traditional knee rehabilitation equipment, a portable intelligent wheelchair for knee rehabilitation was designed in this study.

Methods: Based on the analysis of the knee joint's structure and rehabilitation mechanisms, an electric pushrod-driven rehabilitation institution was developed. A multi-functional module was designed with a modular approach, and the control of the wheelchair body and each functional module was implemented using an STM32 single-chip microcomputer. A three-dimensional model was established using SolidWorks software. In conjunction with Adams and Ansys simulation software, kinematic and static analyses were conducted on the knee joint rehabilitation institution and its core components. A prototype was constructed to verify the equipment's actual performance.

Results: According to the prototype testing, the actual range of motion for the knee joint swing rod is 15.1°~88.9°, the angular speed of the swing rod ranges from -7.9 to 8.1°/s, the angular acceleration of the swing rod varies from -4.2 to 1.6°/s², the thrust range of the electric pushrod is -82.6 to 153.1 N, and the maximum displacement of the load pedal is approximately 1.7 mm, with the leg support exhibiting a maximum deformation of about 1.5 mm.

Conclusion: The intelligent knee joint rehabilitation wheelchair meets the designed functions and its actual performance aligns with the design criteria, thus validating the rationality and feasibility of the structural design.

[膝关节康复用便携式智能轮椅的结构设计与分析]。
目的针对传统膝关节康复设备使用不便、医疗费用高昂、缺乏普及性等问题,本研究设计了一种用于膝关节康复的便携式智能轮椅:方法:在分析膝关节结构和康复机理的基础上,开发了一种电动推杆驱动的康复机构。采用模块化方法设计了多功能模块,并使用 STM32 单片微型计算机实现了对轮椅主体和各功能模块的控制。使用 SolidWorks 软件建立了三维模型。结合 Adams 和 Ansys 仿真软件,对膝关节康复机构及其核心部件进行了运动学和静力学分析。为了验证设备的实际性能,还制作了一个原型:根据样机测试,膝关节摆动杆的实际运动范围为 15.1°~88.9°,摆动杆的角速度范围为-7.9~8.1°/s,摆动杆的角加速度变化范围为-4.2~1.6°/s²,电动推杆的推力范围为-82.6~153.1 N,负重踏板的最大位移约为 1.7 mm,腿部支撑的最大变形约为 1.5 mm:结论:智能膝关节康复轮椅满足设计功能,实际性能符合设计标准,验证了结构设计的合理性和可行性。
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来源期刊
中国医疗器械杂志
中国医疗器械杂志 Medicine-Medicine (all)
CiteScore
0.40
自引率
0.00%
发文量
8086
期刊介绍:
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