RESUMEN
Objective:A novel four-degree-of-freedom upper limb rehabilitation robot was designed to overcome the shortcomings of the structure of the most of serial robots. Methods:The shoulder and elbow joint drive system and the information detection system were placed in the base. The synchronous belt drive system and the spiral bevel gear transmission system were designed to transmit power from the base to the shoulder and elbow joint of the arm. The cubic polynomial trajectory planning method based on the joint space was selected to accomplish the trajectory planning of the recovery movements of taking objects and drawing quadrilaterals, and the single-degree-of-freedom motion control experiment and multi-degree-of-freedom trajectory planning experiment were designed to verify the rationality and feasibility of the design. Results:Each joint of the rehabilitation robot reached the designed range of motion at the designed speed, and well completed the planned rehabilitation training movements. Conclusion:This robot can effectively reduce the volume and mass of the mechanical arm, overcome the influence of motor noise and radiation on patients' rehabilitation training, and assist patients to complete a variety of rehabilitation exercises.
RESUMEN
Objective:To propose a new type of lightweight wearable lower extremity exoskeleton assisted robot system, and explore the feasibility of walking and posture change rehabilitation training for patients with gait disorder and with paraplegia under T4 spinal cord injury (exclusion of lower extremity muscle spasm and obvious pain). Methods:The active and passive hybrid wearable lower extremity exoskeleton assisted robot structure of the hip joint with two-motor active drive and the knee joint passive four-link simulating the instantaneous movement of the human body was designed. Based on modular control, the STM32F767IGT6 and peripheral circuits, attitude acquisition, power supply and crutches module control system were proposed. The exoskeleton robot was worn by a normal person to perform the experiment of leveling, slope and posture transformation and analyze hip/knee /ankle joint angles during exercise, and compare the myoelectric signals of the lateral femoral and medial femoral muscles. Results:The wearer could realize the sitting-standing posture change and the flat/slope walking only based on the exoskeleton robot system, and the hip/knee/ankle angles were basically consistent with the normal walking and the electromyographic signals of the lateral femoral, medial femoral muscle significantly decreased when the robot was worn while walking. Conclusion:The active-passive hybrid lower exoskeleton assisted robot system can still achieve the rehabilitation of walking and posture change while reducing the weight. This verified the feasibility of the assisted robot system with the active dual-motor of the hip joint and the passive four-link structure of the knee joint to help the patients with paraplegia and gait disorder to walk and recover.