Proposed is a rehabilitation exercise device for upper and lower limbs. The rehabilitation exercise device is characterized by including: a first support supporting a user's hand or foot; a second support supporting a user's forearm or calf; a pair of first hinges rotatably connecting the first support and the second support to each other; a third support supporting a user's upper arm or thigh; a pair of second hinges rotatably connecting the second support and the third support to each other; and a drive module selectively mounted on any one of the pair of first hinges and the pair of second hinges, and configured to pivot the first support or the second support.

A multimodal human-robot interaction system for compensation movement of a hemiplegic upper limb includes a compensation monitoring module, a compensation evaluation module and a compensation reducing module. The compensation reducing module includes a robot and a virtual reality system. The robot assists the hemiplegic upper limb in performing rehabilitation training, and adjusts a training action according to a compensation monitoring result and evaluation of compensation to realize passive reducing of compensation movement of the hemiplegic upper limb. The compensation monitoring module acquires data during a rehabilitation therapy. The compensation evaluation module processes and analyzes comprehensive data of the hemiplegic upper limb to obtain the evaluation of compensation. The virtual reality system displays a rehabilitation training scene, a real-time movement posture of the hemiplegic upper limb and the evaluation of compensation and instructs a patient to reduce the compensation movement using visual display and voice feedback.

An actuator-damper unit for use in orthotic or prosthetic devices. The actuator-damper unit includes a housing which may be fastened on the orthotic or prosthetic device and in which a cylinder is formed. A first piston is displaceably mounted in the cylinder and is coupled to a piston rod. The piston rod is disposed, via a first end, on the first piston and may be coupled, via a second end, to the orthotic or prosthetic device. The first piston separates two fluid chambers in the cylinder from each other and forms a piston-cylinder unit, wherein at least one further piston is coupled to the first piston in order to form at least one further, variable-volume fluid chamber.

An exosuit includes a first structure including a series of link elements joined together by joints. The series of link elements extends along a length of the first structure. The joints are configured to flex such that, when the exosuit is worn by a user, the first structure at least partially conforms to a shape of the user's anatomy at a first side of the first structure that extends along the length. The joints restrict flexing that would deform a second side of the first structure extending along the length of the first structure. The exosuit includes a second structure and an actuator coupled to the first structure and the second structure. The actuator causes movement of the first structure relative to the second structure. The exosuit includes an attachment portion to attach the exosuit to the user with the first side of the first structure facing toward the user.

Exercise robot suitable for rehabilitation and methods of its operation are provided. In particular a method in which the exercise robot learns an exercise movement on the basis of movements conducted by the aid of a human assistant holding the leg of a patient and moving the leg with muscular form to conduct an exercise movement. The rehabilitation robot actively accompanies the exercise movement in an active compliance mode and records the movement so as to determine an exercise movement stored in the control unit of the device. The rehabilitation robot can then produce the determined exercise in an exercise mode.

An interactive upper limb rehabilitation training system includes an interactive display screen, a host computer control center, a dual-arm rehabilitation robot, a movable space adjustable dual-arm robot base, and a position tracker. The dual-arm rehabilitation robot is mounted on the movable space adjustable dual-arm robot base, and drives an arm of a patient to move through two end effectors. The movable space adjustable dual-arm robot base adjusts an operating space of the dual-arm rehabilitation robot. The position tracker is used for real-time collecting position and posture information of the arm, and transmitting it to the host computer control center and the interactive display screen. The interactive display screen is used for synchronous operating a game by the position and posture information. The host computer control center is used to store patient information, and is used to provide a quantitative index after evaluating a rehabilitation process of the patient.

A wearable upper limb rehabilitation training robot with precise force control includes a wearable belt, a multi-degree-of-freedom robot arm, and a control box. The robot is worn on the waist of a person by using a belt, and driven by active actuators, to implement active and passive rehabilitation training in such degrees of freedom as adduction/abduction/anteflexion/extension of left and right shoulder joints and anteflexion/extension of left and right elbow joints. In addition, a force/torque sensor is mounted on a tip of the robot arm, to obtain a force between the tip of the robot arm and the human hand during rehabilitation training as a feedback signal, to adjust an operating state of the robot, thereby realizing the precise force control during the rehabilitation training.

Proposed is a rehabilitation exercise device for upper and lower limbs. The rehabilitation exercise device is characterized by including: a first support supporting a user's hand or foot; a second support supporting a user's forearm or calf; a pair of first hinges rotatably connecting the first support and the second support to each other; a third support supporting a user's upper arm or thigh; a pair of second hinges rotatably connecting the second support and the third support to each other; a drive module selectively mounted on any one of the pair of first hinges and the pair of second hinges, and configured to pivot the first support or the second support; and a mounting position detecting part detecting a mounting position where the drive module is mounted from among the pair of first hinges and the pair of second hinges.

A device for supporting and relieving a load on an arm of a user includes an upper subregion, a lower subregion, and a joint that has a horizontal axis of rotation where the upper subregion and the lower subregion are connected by the joint such that the upper subregion is pivotable in an upper spatial direction and a lower spatial direction about the horizontal axis of rotation of the joint. The joint is pivotable in the upper spatial direction and the lower spatial direction in a first state and is pivotable only in the upper spatial direction in a second state.

A robot structure and a rehabilitation device have multiple elements and joints connecting the elements. At least one of the elements includes a first tubular piece with a first outer lateral surface wall, and a second tubular piece with a second outer lateral surface wall. The second tubular piece is arranged such that the length thereof is at an angle to the length of the first tubular piece so that the second tubular piece is inserted into two opposing tubular sections of the first tubular piece, and the second tubular piece passes through the first outer lateral surface wall of the first tubular piece at opposite sides. The second tubular piece is rigidly connected to the first tubular piece by a first connection element and a second connection element.