A driving device for a washing machine includes: a shaft including an inner shaft and an outer shaft surrounding the inner shaft; a motor assembly including a stator, a rotor that surrounds the stator, a modulator that surrounds the rotor, and a magnetic gear rotating body that surrounds the modulator; a first fixation body that connects between the inner shaft and the magnetic gear rotating body; a second fixation body having one end connected to the stator and the other end connected to a tub; and an electronic clutch that disconnects the outer shat and the rotor or connects the inner shaft and the rotor according to an operation mode of the washing machine. The modulator adjusts a speed and torque of the magnetic gear rotating body. The driving device may make a motor drive area highly efficient and may reduce electric consumption.

A washing machine and a driver (e.g., a drive unit) suitable for the washing machine are provided. The driver includes a motor to rotate a shaft supported by a unit base, and a reducer interposed between the shaft and the motor. The motor and the reducer are integrally formed to be aligned in a line along a direction perpendicular to a rotation axis.

A rotational coupling device includes an armature configured for coupling to a shaft for rotation with the shaft about an axis, but axially movable relative to the shaft. An electromagnet assembly is disposed on one side of the armature and fixed against rotation. A collar is disposed on the opposite side of the armature. The collar is configured for rotation with the shaft, but fixed against axial movement relative to the shaft and includes a permanent magnet. When a current having a first polarity is provided to the electromagnet assembly, the armature moves in one axial direction into engagement with a member of the coupling device to transmit a torque between the member and the armature. The permanent magnet urges the armature in the opposite axial direction to disengage the armature from the member when the current is not provided to the electromagnet assembly.

A drivetrain module for a motor vehicle having a clutch with an input area and an output area. A mutual rotational driving of the input area and output area is influenceable by the action of the clutch. The clutch has a clutch housing with a clutch space formed therein. The input area and the output area are arranged at least partially in the clutch space. The clutch space is filled and is closed to be tight against fluid relative to a surrounding area of the clutch space. The clutch has a pressure compensation device for compensation of a pressure difference acting between the clutch space and the surrounding area.

A drive motor in which a torque sensor is arranged on an outer circumference of a shaft, includes a rotor, a rotor shaft arranged inside the rotor, and an output shaft that is joined to the rotor shaft by a spline joint and outputs rotational force of the rotor shaft to the output side. The torque sensor is arranged on an output side of the spline joint in a range not overlapping with the spline joint.

An electric actuator comprises a housing and an output shaft reciprocatingly received by the housing. There is a screw assembly disposed within the housing and coupled to the output shaft. The screw assembly includes a plurality of annular rollers and a central screw received by the annular rollers. The annular rollers are rotatable about the central screw. There is a motor which includes a stator and a rotor. The rotor has an inner bore which engages the annular rollers. Rotation of the rotor causes the central screw to translate axially relative to the rotor and the output shaft to reciprocate relative to the housing.

A power system having two motors includes: a first motor transmitting power to an output shaft of an engine or receiving power from the output shaft of the engine; a first clutch selectively connecting a first rotor of the first motor to the output shaft and mounted on a first power transmitting member that operably connects the output shaft and the first rotor of the first motor; a second motor outputting power to an input shaft of a transmission; and a second clutch selectively connecting the output shaft to a second rotor of the second motor and mounted on a second power transmitting member that operably connects the output shaft and the second rotor of the second motor.

The present invention relates to a linear guide system having: at least a first rail element and a second rail element, the first rail element and the second rail element being mounted linearly displaceably relative to each other in and counter to a extraction direction; an electric motor; an input shaft, the input shaft being operatively coupled to the electric motor such that the electric motor sets the input shaft in rotation during operation of the linear guide system; a linear drive, the linear drive having an output shaft, and the linear drive being designed such that a rotary movement of the output shaft effects a linear movement of the first and second rail elements relative to each other in or counter to the extraction direction; and a clutch, the clutch connecting the input shaft and the output shaft to each other such that the clutch transmits a torque from the input shaft to the output shaft, the clutch being a magnetic clutch. The magnetic clutch has a first and a second clutch element, the first clutch element being connected in a torque-resistant manner to the input shaft, and the second clutch element being connected in a torque-resistant manner to the output shaft.

An electric actuator comprises a housing and an output shaft reciprocatingly received by the housing. There is a screw assembly disposed within the housing and coupled to the output shaft. The screw assembly includes a plurality of annular rollers and a central screw received by the annular rollers. The annular rollers are rotatable about the central screw. There is a motor which includes a stator and a rotor. The rotor has an inner bore which engages the annular rollers. Rotation of the rotor causes the central screw to translate axially relative to the rotor and the output shaft to reciprocate relative to the housing.

A driving apparatus for a vehicle is disclosed. The driving apparatus is used for transmitting drive force to a first output shaft. The driving apparatus includes a housing, a motor, a torque converter and an oil reservoir unit. The housing includes a first oil chamber and a second oil chamber. The motor is disposed in the first oil chamber. The torque converter forms the second oil chamber and transmits drive force of the motor to the first output shaft. The oil reservoir unit is disposed radially inward of the torque converter. The torque converter guides hydraulic oil from the oil reservoir unit to the second oil chamber by centrifugal force.