Methods, systems, and apparatus, including computer programs encoded on computer storage media, for creating exosuit interfaces using 3D printing. One of the methods includes receiving a three-dimensional data model of one or more areas of a person's body; determining exosuit position data that identifies a portion of the three-dimensional data model for which an exosuit model will be generated; determining an actuator housing location to integrate an actuator housing in a component of the exosuit model, the actuator housing location being determined to align a first movement path for an actuator received in the actuator housing with a second movement path for the person's body; and generating at least a portion of an exosuit model that includes the component having (i) a region shaped to correspond to a contour of the person's body and (ii) an actuator housing at the actuator housing location.

Various embodiments provide assemblies for manipulating a user's limb with at least one inflatable member. The assemblies comprise a first pliable planar member and a second pliable planar member overlaid atop at least a portion of the first pliable planar member, such that a two ply configuration is provided. The two ply configuration itself comprises at least a distal and a proximal portion and at least one opening configured to accept at least a portion of the user's limb. The first and second pliable planar members combine to define at least one inflatable member, the inflatable member being at least a portion of at least one of the distal and proximal portions, the inflatable member being configured to be selectively inflatable so as to provide at least one inflation force upon the user's limb, such that the joint in the user's limb is manipulated. Associated methods are also provided.

A limb rehabilitation and training system includes a horizontal position adjuster movably mounted at a bottom side of a base, an expansion rotary member mounted at the horizontal position adjuster, a shoulder joint traction mechanism linked to the expansion rotary member through a first arm segment robotic arm and a height adjuster, and an upper-limb rehabilitation device linked to the shoulder joint traction mechanism. The upper-limb rehabilitation device is able to rapidly be adjusted to fit the left arm or right arm through the horizontal position adjuster, the expansion rotary member, the first arm segment robotic arm and a shoulder positioning-lifting rotary member and. Further, by means of the shoulder joint traction mechanism, the user's stiffened shoulder joint can be timely moved for a separation distance, achieving the function of loosening the joint and facilitating performance of successive rehabilitation treatment or training.

The present invention discloses a gravity balancing device for a rehabilitation robot arm, and belongs to the field of rehabilitation robots. The gravity balancing device includes a shoulder joint connecting member, an upper arm connecting member and a gravity balancing assembly; the shoulder joint connecting member and the upper arm connecting member are pivotally connected according to the human body bionic structure to simulate the rotational movement of the upper arm of the human body around the shoulder joint; the gravity balancing assembly includes a plurality of springs, wire ropes and guide pulleys, the wire ropes connect the springs to the shoulder joint connecting member and the upper arm connecting member, the spring tension is used to balance the gravity of the arm, and the guide pulleys are used to change the force directions of the wire ropes, thereby saving space and making the device structure more compact. Further, by locking different guide pulleys, the arm gravity can be still balanced by the spring tension after switching of the rehabilitation robot between the left and right hand training modes, thereby ensuring that the robot can still work normally after the training mode is switched.

An orthotic support comprises a shoulder section for encapsulating a first shoulder of a wearer, a glove section for conforming to at least a portion of the wearer's hand, and a sleeve section for conforming to the wearer's arm, the sleeve section connecting the shoulder section to the glove section. A resilient reinforcement extends from the glove section to the shoulder section, and at least a portion of the reinforcement extends in a spiral around the sleeve section, so that the reinforcement is configured to apply a rotational force to the wearer's arm, when worn, to urge a portion of the wearer's arm to rotate in a predetermined direction. The orthotic support may be usable to treat or prevent shoulder dislocation or subluxation, arm over-pronation or over-supination, wrist flexion or elbow flexion. An orthotic support may comprise a reinforcement with a first branch extending over an anterior portion of the sleeve section, and a second branch extending over a posterior portion of the sleeve section, so that the reinforcement is configured to urge the wearer's upper arm towards a rest position.

A physiotherapeutic device is disclosed. In an embodiment a physiotherapeutic device includes an arm trainer configured to rotationally move arms of a patient, the arm trainer having a first axis and a leg trainer configured to rotationally move legs of the patient, the leg trainer having a second axis, wherein the first and second axes comprise an adjustability in height, wherein a distance of the first axis to the second axis is constant, wherein the arm and leg trainers are adjustable in height so that an adjustment in height results in different exercising positions.

Proposed is a rehabilitation exercise device for upper and lower limbs. The rehabilitation exercise device is characterized by including: a base plate; a mounting plate on which a rehabilitation exercise unit is mounted, the rehabilitation exercise unit including a first support for supporting a user's hand or foot, a second support for supporting a user's forearm or calf, a third support for supporting a user's upper arm or thigh, the mounting plate having a first side that is coupled to the base plate to be horizontally movable along a plate surface thereof; and a link member having opposite sides that are rotatably coupled to the base plate and the mounting plate, respectively, and configured to adjust an angle between the base plate and the mounting plate being rotated when the first side of the mounting plate is moved horizontally along the plate surface of the base plate.

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 coupling 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 configured to be rotated in conjunction with the third support, and to which the second support part is coupled to be rotatable relative thereto; and an angle adjustment part adjusting an angle between the second support and the third support.

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 walking assist device has a frame, a plurality of wheels, drive units, a battery, and a drive control unit that controls the drive units. The walking assist device also has: a pair of right and left movable handles that are grasped by a user and movable back and forth with respect to the frame in accordance with arm swing performed during walk of the user; handle guide units provided on the frame to guide the movable handles in a movable range that matches the arm swing performed during walk of the user; and a grasp portion state detection unit that detects the state of the movable handles. The drive control unit controls the travel speed of the walking assist device by controlling the drive units on the basis of the state of the movable handles which is detected using the grasp portion state detection unit.