The present invention is a modular exercise system made up of two handles, a segmented track, and two or more sliding carriages. The invention allows a user to safely and incrementally practice front and side split exercises by providing specific and adjustable stability and support. The invention can be extended to accommodate taller users and can also be fully disassembled and packed into a compact travelling configuration.

A rehabilitation assisting apparatus has a main body, a waist assisting unit mounted above the main body, and two leg assisting units separately disposed side by side above the main body. Each of the leg assisting units is pivotally connected with the waist assisting unit. An upper rocking plate of the waist assisting unit can be driven to roll leftward and rightward to rehabilitate or train a waist of a user. A leg lifting bracket of each of the leg assisting unit can be driven to pitch upward and downward to rehabilitate or train a leg of the user.

A portable modular stretching apparatus has a basic structure of a base, central rod, pulley, cable system, and two legs jointed at the central rod and alongside the base. Attachments are then added for customized stretching. Attachments provide for hamstring, hips, quadriceps, knees, gastrocnemius, ankle, and metatarsal stretching, limberness, and extension, and hyperflexion. A person adds and removes the attachments based on the desired stretch routine, controls the tension, and removes the attachments, and folds the apparatus when complete.

A method of controlling a mobility device and related device including at least one actuator component that drives at least one joint component is described. The control method may include executing a control application with an electronic controller to perform: receiving a command in the control system of the mobility device for initiating an automated assessment and adjustment protocol; controlling one or more mobility device components to perform the automated assessment; electronically gathering user performance data associated with the automated assessment and determining user performance metrics; and electronically controlling one or more of the mobility device components in accordance with the performance metrics. The automated assessment includes controlling mobility device components to perform a predetermined assessment activity related to performance of the mobility device and/or user. Automatic adjustments to the device components, including adjusting tension and resistance levels of the joint components, may then be made based the performance metrics.

A stretching machine includes a table having a surface for supporting a patient and a first leg rest for supporting and moving a first leg of the patient. The first leg rest has a first vertical frame operable to rotate around a first horizontal pivot point at an end of the table and a first horizontal frame operable to rotate around a first vertical pivot point on the first vertical frame. A first vertical actuator is for rotating the first vertical frame around the first horizontal pivot point to move the first leg rest in a vertical direction relative to the surface of the table, and a first horizontal actuator is for rotating the first horizontal frame around the first vertical pivot point to move the first leg rest in a horizontal direction relative to the first vertical frame.

A reduced friction massage and exercise device, which includes a base frame and at least one anchoring arrangement for anchoring a first body part of a user. A reduced friction surface is mounted onto the base frame, and includes a plurality of ball transfer units arranged such that adjacent ball transfer units engage one another. The device further includes at least one cable column including a weight stack. Each of the motion transfer balls is adapted for omnidirectional rotation relative to a corresponding housing element and independently of other the motion transfer balls. The reduced friction surface is adapted to have a second body part of the user placed thereon during performing of a physical activity applying force to the second body part, while reducing friction between the second body part and the surface.

A joint actuator assembly incudes a motor, a rotating driving member driven by the motor for driving a driven component, and a transmission assembly located between the motor and the rotating driving member that provides speed reduction from the motor to the rotating driving member. The rotating driving member includes a magnetic/electrical coupling comprising a magnetic coupling component configured to magnetically couple with an opposing magnetic coupling of the driven component, and an electrical element configured to provide an electrical connection to an opposing electrical element of the driven component. The actuator and driven component may be combined into a mobility device including a magnetic/electrical coupling system comprising a first magnetic/electrical coupling on the actuator assembly that magnetically and electrically couples to a second magnetic/electrical coupling on the driven component. The magnetic coupling system includes a plurality of magnetic elements located on the first and/or second magnetic/electrical couplings and opposing electrical elements for electrical connection when the actuator assembly and the driven component are joined together.

An actuating device for orthosis includes a transmission that is operatively connected to a motor such that the motor provides power to the transmission. The transmission includes a first stage, a second stage, and a third stage. Each of these stages includes at least two sprockets and a drive belt tensioned between the two sprockets. The transmission also includes a first shaft and a second shaft. A sprocket of each of the first, second, and third stages of the transmission is attached to the first shaft. An actuating arm is operatively connected to the third stage of the transmission such that the power provided to the transmission by the motor causes the actuating arm to provide an output torque.

A joint actuator assembly includes a motor, a rotating driving member driven by the motor for driving a driven component, and a transmission assembly located between the motor and the rotating driving member that provides speed reduction from the motor to the rotating driving member. The rotating driving member comprises a magnetic coupling including a plurality of magnetic elements that are configured to magnetically couple with an opposing magnetic coupling of the driven component. The actuator and driven component may be combined into a mobility device including a magnetic coupling system having a first magnetic coupling on the actuator that magnetically couples to a second magnetic coupling on the driven component. The magnetic coupling system includes plurality of magnetic elements located as part of one or both of the first and second magnetic couplings. The first and second couplings have opposing mating surfaces that join together in a coupled position.

An exercise assist device transitively moves a sacroiliac joint in a lateral decubitus position. The following description is provided in the context of a left lateral decubitus position. The upper right leg is placed on a stand in the lateral decubitus position, and the upper right leg is then extended transitively backward with a sacral area supported by a sacrum support pad. Since a posterior side of a lower left sacroiliac joint is slightly opened, a sacrum slides backward via a right hip joint. This improves mobility of the lower left sacroiliac joint.