A percussive massage device includes a motor including a rotor, a push rod operatively connected to the motor and configured to reciprocate in response to activation of the motor, a massage attachment coupled to a distal end of the push rod, a sensor configured to detect a rotor position of the rotor, and a controller configured to receive the rotor position, determine a rotational speed of the motor therefrom, and compare the rotational speed to a predetermined speed, wherein the controller is configured to increase operating power of the motor when the rotational speed is lower than the predetermined speed.

A stimulating mechanism for an adult toy is disclosed. The stimulating mechanism includes a first elongate cavity having a first end and a second end. The stimulating mechanism also includes a first magnet having a north pole side and a south pole side, and arranged inside the first elongate cavity. The stimulating mechanism further includes a second magnet having a north pole side and a south pole side, and arranged with respect to the first magnet. Herein, the second magnet is caused to recurrently change the magnetic orientation with respect to the first magnet such that the north pole side and the south pole side of the second magnet are alternatively facing one of the north pole side and the south pole side of the first magnet, causing the first magnet to linearly translate inside the first elongate cavity.

An orthosis includes a first portion and a second portion configured to attach on opposite sides of a joint. An actuator is configured to apply a force between the first and second portions. The actuator includes a first spool and a second spool rotatably mounted to the first portion. An output pulley is mounted to the second portion. A belt has a first end wrapped around the first spool, a second end wrapped around the second spool, and a mid-portion wrapped around the output pulley. The actuator is configured to rotate the first and second spools. The rotation of the first spool pulls the belt a given length, and the rotation of the second spool feeds the belt less than the given length, so as to pull the output pulley towards the first portion to pull the second portion towards the first portion.

A mechanical actuator system has variable and controllable mechanical impedance. Such a mechanical actuator system may be used to effectuate a degree of freedom in a robot, i.e., to control speed, output torque and direction of movement of a robotic component, such as a joint, wheel, arm, wrist or grabber. Mechanical impedance, i.e., an amount of “resistance” the robot presents to a human user, can be controlled for safety and rehabilitation purposes. The mechanical actuator system includes a mechanical differential and two adjustable-engagement clutches driven by motor. Advantageously, the motor may turn at a constant speed and direction, yet the mechanical actuator system can be controlled to turn in either direction and at a desired speed. The adjustable-engagement clutches may be electrorheological (ER) fluid clutches, magnetorheological (MR) fluid clutches, conventional dry friction clutches or any other type of clutch whose degrees of engagement can be controlled.

A mechanical actuator system has variable and controllable mechanical impedance. Such a mechanical actuator system may be used to effectuate a degree of freedom in a robot, i.e., to control speed, output torque and direction of movement of a robotic component, such as a joint, wheel, arm, wrist or grabber. Mechanical impedance, i.e., an amount of “resistance” the robot presents to a human user, can be controlled for safety and rehabilitation purposes. The mechanical actuator system includes a mechanical differential and two adjustable-engagement clutches driven by motor. Advantageously, the motor may turn at a constant speed and direction, yet the mechanical actuator system can be controlled to turn in either direction and at a desired speed. The adjustable-engagement clutches may be electrorheological (ER) fluid clutches, magnetorheological (MR) fluid clutches, conventional dry friction clutches or any other type of clutch whose degrees of engagement can be controlled.

Various implementations include a device for assisting with and controlling stretching of a limb of a patient. The device includes a limb support for receiving the limb, a base, and a coupling that rotatably couples the limb support and the base. The coupling allows the limb support to rotate through various axes of rotation individually, depending on the range of motion expected for the limb. For example, for a device designed for the foot, the coupling allows a foot support to rotate about a first axis, a second axis, and a third axis, wherein the three axes are orthogonal to each other. In other implementations, the device may be designed for other portions of limbs, such as the hand, the forearm, the upper arm, the lower leg, and the upper leg.

A robotic device for operation in association with an appendage of a user, wherein the appendage of the user has an endpoint, the robotic device including: a base; and a robotic arm attached to the base and having an endpoint, the robotic arm having at least two active degrees of freedom relative to the base and being configured so that when the base is appropriately positioned relative to a user, the reference frame of the robotic device is oriented generally similarly to the reference frame of the user and motions of the endpoint of the appendage of the user are mimicked by motions of the endpoint of the robotic arm.

The movable apparatus includes a holding body and a movable body. The holding body includes a first opening portion and an internal space, and is constituted of one part. The movable body includes an internal body and a first movable shaft portion. The internal body is stored in the internal space of the holding body, and has such a size that the internal body is prevented from exiting the first opening portion even if the first opening portion is elastically deformed. The first movable shaft portion is capable of being moved integrally with the internal body, and is exposed to outside of the holding body from inside of the holding body through the first opening portion.

Provided is a spinal traction device and a spinal traction method for spinal traction, and the spinal traction device includes: an upper body support unit configured to support an upper body of a person and having at least one spine pressing unit installed on one surface thereof; a lower body support unit configured to support a lower body of the person and having a moving means so as to move away from or close to the upper body support unit; and a controller configured to adjust a movement of the lower body support unit. The spinal traction device has a technical feature in which at least one spine pressing unit is in close contact with and supports the spine of the upper body when the lower body support unit moves.

An assist device includes a first harness, a second harness, a belt body, a mechanical unit and an attachment-detachment portion. The first harness is configured to be fitted to at least one of a shoulder region and a breast region of a user. The second harness is configured to be fitted to a leg region or a waist region of the user. The belt body is provided so as to extend to the first harness and to the second harness along a back side of the user. The mechanical unit includes an actuator provided in one harness of the first harness and the second harness and configured to wind and unwind a part of the belt body. The attachment-detachment portion is provided in the harness and the mechanical unit and is configured to detachably attach the mechanical unit to the harness.