Development of the Biomech-Wrist: A 3-DOF Exoskeleton for Rehabilitation and Training of Human Wrist.

Roderico Garcia-Leal, David Cruz-Ortiz, Mariana Ballesteros, Joel C Huegel
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Abstract

This work describes a three-degrees-of-freedom rehabilitation exoskeleton robot for wrist articulation movement: the Biomech-Wrist. The proposed development includes the design requirements based on the biomechanics and anthropometric features of the upper limb, the mechanical design, electronic instrumentation, software design, manufacturing, control algorithm implementation, and the experimental setup to validate the functionality of the system. The design requirements were set to achieve human wrist-like movements: ulnar-radial deviation, flexion-extension, and pronation-supination. Then, the mechanical design considers the human range of motion with proper torques, velocities, and geometry. The manufacturing consists of 3D-printed elements and tubular aluminum sections resulting in lightweight components with modifiable distances. The central aspect of the instrumentation is the actuation system consisting of three brushless motors and a microcontroller for the control implementation. The proposed device was evaluated by considering two control schemes to regulate the trajectory tracking on each joint. The first scheme was the conventional proportional-derivative controller, whereas the second was proposed as a first-order sliding mode. The results show that the Biomech-Wrist exoskeleton can perform trajectory tracking with high precision ( RMSEmax = 0.0556 rad) when implementing the sliding mode controller.

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生物力学手腕的发展:一种用于人类手腕康复和训练的三自由度外骨骼。
这项工作描述了一个用于手腕关节运动的三自由度康复外骨骼机器人:Biomech手腕。拟议的开发包括基于上肢生物力学和人体测量特征的设计要求、机械设计、电子仪器、软件设计、制造、控制算法实现以及验证系统功能的实验装置。设计要求是为了实现类似人类手腕的运动:尺骨径向偏移、屈伸和旋前-旋后。然后,机械设计考虑了具有适当扭矩、速度和几何形状的人体运动范围。该制造由3D打印元件和管状铝型材组成,从而生产出具有可更改距离的轻质组件。仪器的中心方面是由三个无刷电机和一个用于控制实现的微控制器组成的驱动系统。通过考虑两种控制方案来调节每个关节的轨迹跟踪,对所提出的装置进行了评估。第一种方案是传统的比例微分控制器,而第二种方案是作为一阶滑模提出的。结果表明,在实现滑模控制器时,Biotech腕关节外骨骼可以进行高精度的轨迹跟踪(RMSEmax=0.00556rad)。
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