A linkage (100, 200) having a plurality of small angle links (114, 116; 208, 212) with axes of rotation directed to a single point to allow movement of an recipient object without moving the point of action of an applied force (F).

Provided herein are devices and methods for analysis and/or exercise of a body region of a subject. Such devices may include a guide arm supported by a support frame; a receiving surface supported by the guide arm, the receiving surface for receiving input force from the subject; and a motor assembly in communication with the guide arm, the motor assembly controlling movement of the receiving surface based on received input force. Exercise and/or analysis methods described herein may include steps of instructing the subject to apply an input force to a receiving surface; sensing the applied input force over time; and controlling movement of the receiving surface based on the received input force using a motor assembly, whereby the motor assembly moves the receiving surface in a pre-determined direction, so long as the input force remains within an allowable tolerance, until a pre-set end position is reached.

An exoskeleton apparatus includes a base unit, a support unit, and upper and lower arm units. The support unit is rotatable about a vertical first axis relative to the base unit. The upper arm unit includes a linking axle, a main arm that has a connecting end rotatable about a horizontal second axis, and a linkage mechanism for rotating the linking axle relative to the main arm about a horizontal third axis. The lower arm unit is rotatable relative to the upper arm unit, and includes a lower arm set co-rotatably coupled to the linking axle, a hand-receiving seat rotatably connected to the lower arm set, and a lower arm receiving seat connected to the hand-receiving seat, and a drive member for rotating the hand-receiving seat about a horizontal fourth axis.

Embodiments of the invention are directed to devices for manipulating a hand of a user to provide pronation or supination assistance. Embodiments include an anchor; a hand engagement member operatively attached to the anchor and configured to receive and engage the hand of the user; a force applicator comprising a member portion and an anchor portion opposite the member portion, the force applicator attached to the hand engagement member proximate its member portion and attached to the anchor proximate its anchor portion; and a force application mechanism attached to the anchor and configured to cause a force to be applied to the force applicator causing the hand engagement member to manipulate the hand of the user to provide pronation or supination assistance. In some embodiments, the force application mechanism includes a non-incremental rotary mechanism. In some embodiments, a flexible tethering member attaches the anchor to the hand engagement member.

In one aspect, an orthosis for increasing range of motion of a body joint generally includes first and second dynamic force mechanisms for simultaneously applying a dynamic force to body portions on opposite sides of a body joint.

A wearable multifunctional powered exoskeleton for cervical vertebra rehabilitation, and relates to the field of man-machine interaction rehabilitation aids, comprises an active drive motor module, a fixed supporting module and a movable joint component; wherein the active drive motor module is connected to the fixed supporting module, and comprises a left shoulder push rod motor, a right shoulder push rod motor, a cervico-thoracic vertebra left front side push rod motor, a cervico-thoracic vertebra left rear side push rod motor, a cervico-thoracic vertebra right front side push rod motor, and a cervico-thoracic vertebra right rear side push rod motor; wherein the active drive motor module and the movable joint component are combined to Jointly form a six-connecting rod power-driven structure.

Embodiments of the invention are directed to devices for manipulating a hand of a user to provide pronation or supination assistance. Embodiments include an anchor; a hand engagement member operatively attached to the anchor and configured to receive and engage the hand of the user; a force applicator containing a member portion and an anchor portion opposite the member portion, the force applicator attached to the hand engagement member proximate its member portion and attached to the anchor proximate its anchor portion; and a force application mechanism attached to the anchor and configured to cause a force to be applied to the force applicator causing the hand engagement member to manipulate the hand of the user to provide pronation or supination assistance. In some embodiments, the force application mechanism includes a non-incremental rotary mechanism. In some embodiments, a flexible tethering member attaches the anchor to the hand engagement member.

An upper arm module of a wearable muscular strength assisting apparatus is provided. The upper arm module includes a base part configured to be connected to a wearer's body, and an upper arm part having a first end thereof coupled to the base part to be rotatable about a fixed point. The upper arm part is coupled to the wearer's upper arm to apply a torque thereto. The upper arm module further includes an elastic body having a first end thereof fixedly coupled to the upper arm part and generating an elastic force by deformation. In particular, the upper arm module also includes a first link having a first end thereof rotatably coupled to the base part at a point of application, and a second link rotatably coupled to the second end of the first link at a first point.

A rehabilitation training apparatus for an ankle joint is disclosed. The rehabilitation training apparatus comprises a working platform, a Z-axis rotating mechanism, a Y-axis rotating mechanism, an X-axis rotating mechanism, and a pedal. The Y-axis rotating mechanism includes an annular bracket vertically fastened to a driving arm of the Z-axis rotating mechanism, an annular sliding cover slidably disposed on one side wall of the annular bracket, a Y-axis driving mechanism for driving the annular sliding cover to rotate around the axis of the annular bracket, and a sliding block for locating the annular sliding cover. The Y-axis driving mechanism synchronously rotates with the annular sliding cover and the X-axis rotating mechanism is fastened to one side of the annular sliding cover.

A frame includes a front segment extending across an anterior side of a human and a back segment extending across a posterior side of the human in a fixed spatial relationship. A clamp bar extends between the front segment and the back segment to interface with a first lateral side of the human at a location between an ilium bone structure and a thoracic cage of the human. A lateral restraint is positioned between the front segment and the back segment and is configured to interface with a second lateral side of the human over an engagement area corresponding to a portion of the thoracic cage of the human. A downward treatment force is applied to the frame at a location opposite the clamp bar from the lateral restraint. The human works to laterally translate their spinal column toward the lateral restraint to maintain the frame in a near-level orientation.