A medical apparatus for standing aid comprising a backrest (4) that has at least one side thereof provided with a crank rocker mechanism that comprises a crank mechanism (1), a triangular linkage mechanism (2), and a rocker mechanism (3), the crank mechanism (1) being rotatably connected to the triangular linkage mechanism (2) such that an included angle between a second driven link (BE) of the triangular linkage mechanism (2) and the crank mechanism (1) is always smaller than 90°, and the crank mechanism (1) driving the triangular linkage mechanism (2), the rocker mechanism (3) and the backrest (4) connected to the triangular linkage mechanism (2) to perform interactive movement repeatedly along a predetermined curve trajectory in response to a driving force coming from a drive effect of a driving unit (100), so that the backrest (4) connected to the second driven link (BE) assists a trainee in standing up repeatedly by obliquely supporting the trainee's waist.

A wearable device may include a proximal support configured to support a proximal part (e.g., waist) of a user, a distal support configured to support a distal part (e.g., thigh) of the user, a driving assembly which is connected to the proximal support and configured to generate power, and a driving frame configured to transmit the force from the driving assembly to the distal support. The driving assembly may include a housing which is connected to the proximal support, an actuator including a stator which is fixed to the housing and has a ring shape and a rotor which is located inside the stator and rotatable relative to the stator, a speed reducer which is inserted inside the rotor and includes an input end which is connected to an output end of the actuator, and a supporting part configured to support the speed reducer and connected detachably to the housing.

An interface system in an exoskeleton includes a base support, a strap assembly, and posterior strut. The posterior strut has a vertical member defining a lower end connecting to the base support, and an upper end connecting to first and second transverse members extending in opposed directions from the vertical member. The first and second transverse members connect to the strap assembly. The interface system is adapted to receive and support an assistive device adapted to augment a user’s performance and mitigate repetitive strain injuries.

A walking support apparatus supports the walking movement of a walking person. The walking person may be an elderly person, a disabled person, an invalid, an athlete, a learner, or the like. A measurement unit measures walking information with respect to the walking person, and generates data that represents the walking information. An attachment applies an action to the arm of the walking person according to the walking information data measured by the measurement unit. Such an arrangement provides improved walking movement via the effect on the arm movement when the walking person is walking.

A support device comprises a first band secured to a second band in a cross pattern. A proximal end of the first band and a proximal end of the second band can also be configured to fasten around a waist of a user. Further, a distal end of the first band can be configured to fasten around a first leg of the user, and a distal end of the second band can be configured to fasten around a second leg of the user. The support device may prevent improper and dangerous misalignment of the back, hips and knees while squatting.

Disclosed is a rehabilitation training apparatus including a pair of first tracks that are arranged in parallel at an interval, a second track that is perpendicular to the pair of first tracks and is movably connected to the pair of first tracks, a hand holder that is movably provided in the second track and on which a hand of the user is held, a holder driving unit that reciprocally moves the hand holder along the second track, and a track driving unit that reciprocally moves the second track along the pair of first tracks.

A pneumatic exomuscle system and methods for manufacturing and using same. The pneumatic exomuscle system includes a pneumatic module; a plurality of pneumatic actuators each operably coupled to the pneumatic module via at least one pneumatic line, a portion of the pneumatic actuators configured to be worn about respective body joints of a user; and a control module operably coupled to the pneumatic module, the control module configured to control the pneumatic module to selectively inflate portions of the pneumatic actuators.

A shoulder range of motion machine includes a stationary base frame and a shoulder-manipulation mechanism including a movable base frame supported on the stationary base frame for at least pivoting motion about a main vertical axis. A horizontal linear actuator is configured to drive the movable base frame in at least pivoting motion with respect to the stationary base frame about the main vertical axis. A vertical support is mounted on the movable base frame. An arm-carrier support is mounted on the vertical support for at least pivoting motion about a main horizontal axis. An arm-carrier-angle linear actuator is configured to drive the arm-carrier support in at least pivoting motion with respect to the vertical support about the main horizonal axis. An arm carrier is mounted on the arm-carrier support. A controller is operatively connected to at least one of the horizontal linear actuator or the arm-carrier-angle linear actuator.

An exoskeleton apparatus driven by a pneumatic artificial muscle with functions of upper limb assist and rehabilitation training includes an upper limb frame, a shoulder joint mechanism, and an elbow joint mechanism which are driven by utilizing a processing unit, a first angle sensing unit, a second angle sensing unit, a first proportional pressure valve, a pressure sensing unit and a pneumatic muscle device. The exoskeleton apparatus can be independently used as an upper limb exoskeleton assistive device or can be combined to form an upper limb exoskeleton rehabilitation training system to simulate the upper limb movements in daily life through the upper limb frame to assist with the movements of the wearer's upper limbs, accomplishing the rehabilitation training of each upper and lower arm joint and neurological function.

A textile actuator and harness system can include a harness configured to be worn with a portion extending across a wearer's joint. The harness comprises a substantially inextensible section and at least two mounting locations spaced for positioning across the joint, with at least one located along the substantially inextensible section of the harness. A textile envelope defines a chamber and is made fluid-impermeable by (a) a fluid-impermeable bladder contained in the textile envelope and/or (b) a fluid-impermeable structure incorporated into the textile envelope. The textile envelope is secured to the harness at each mounting location, and the textile envelope has a pre-determined geometry configured to produce assistance to the joint due to inflation of the textile envelope during a relative increase in pressure inside the chamber.