Disclosed are a sexual massage apparatus, an engine assembly, and a massage machine. The sexual massage apparatus includes: an engine assembly, including an outer shell and a first driving unit, wherein the outer shell has a hollow cavity defined therein, and the first driving unit is arranged in the hollow cavity; a massage machine, capable of being at least partly inserted into the hollow cavity of the engine assembly and being separated from the engine assembly, wherein the massage machine includes a first sexual stimulation unit, when the massage machine is at least partly inserted into the hollow cavity, the first sexual stimulation unit is controlled by the first driving unit, to apply a first sexual stimulation for a human body part, and the first sexual stimulation is a compression sexual stimulation generated along a radial direction for the human body part.

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 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.

Driving modules, motion assistance apparatuses including at least one of the driving modules, and methods of controlling at least one of the motion assistance apparatuses may be provided. For example, a driving module including a driving source on one side of a user and configured to transmit power, an input side rotary body coupled to the driving source and configured to rotate, first and second decelerators configured to operate using the power respectively received from the driving source through the input side rotary body, and a first stopper and a second stopper configured to selectively enable or disable a transmission of the power between the input side rotary body and respective output terminals of the first and second decelerators may be provided.

A sex toy comprising a body housing a motor; a shaft coupled to the motor; a massaging member mounted over the shaft; and a controller coupled to control the motor to drive the massaging member in a reciprocating motion along the length of the shaft is described. The reciprocating motion results in a change in length of the sex toy. The change in length may comprise about 20 mms to about 100 mms; about 25 mm to about 90 mm; or about 30 mm to about 85 mm. One full stroke of the reciprocating motion may be performed in about 0.5 to about 2.0 about seconds; about 0.6 to about 1.5 seconds; or about 0.7 to about 1.0 seconds.

A back massaging device includes a seat back, a linear rack gear, a frame body, a main gear, a massage member, two motor assemblies and a control unit. The linear rack gear and the frame body are on the seat back. The main gear is pivoted at the frame body through a gear shaft. One of the motor assemblies is meshed with the main gear for rotating a massage protrusion of the massage member by an angle. Another motor assembly is meshed with the linear rack gear for driving the massage protrusion to vertically move. The control unit is electrically connected to the motor assemblies for calculating rotation angle values and vertical movements of the massage protrusion, and controlling the motor assemblies to operate synchronously to outline a trajectory pattern corresponding to one of trajectory scripts by the massage protrusion.

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.

A palm-supported finger rehabilitation training device comprises a mounting base, a finger rehabilitation training mechanism mounted on the mounting base, and a driving mechanism for driving the finger rehabilitation training mechanism; wherein the finger rehabilitation training mechanism comprises four independent and structurally identical combined transmission devices for finger training corresponding to a forefinger, a middle finger, a ring finger and a little finger of a human hand, respectively, and the mounting base is provided with a supporting surface capable of supporting a human palm; wherein each combined transmission device for finger training comprises an MP movable chute, a PIP fingerstall, a DIP fingerstall and a connecting rod transmission mechanism; a force sensor is provided to acquire force feedback information to determine and control force stability, and a space sensor is provided to acquire space angle information to control space positions of fingers in real time.

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.

An exemplary embodiment of the present invention provides an exosuit support system, comprising first and second orthotic interfaces, first and second members, and first and second actuators. The first and second orthotic interfaces can be configured to attach to left and right legs of a user, respectively. The first member can comprise a first end connected to the first orthotic interface and a second end connected to a portion of the system configured to be positioned proximate a right shoulder of the user. The second member can comprise a first end connected to the second orthotic interface and a second end connected to a portion of the system configured to be positioned proximate a left shoulder of the user. The first actuator can be configured to apply a first tension to the first member. The second actuator can be configured to apply a second tension to the second member.