An electric motor rotor for a hybrid module includes a rotor carrier, a piston carrier, and a tapered snap ring. The rotor carrier includes a first inner circumferential surface with an inner spline for receiving a first plurality of clutch plates, a second inner circumferential surface, radially outside of the first inner circumferential surface, a radial wall connecting the first inner circumferential surface to the second inner circumferential surface, and a groove with a conical wall. The piston carrier includes a radial outer ring installed between the groove and the radial wall. The tapered snap is ring installed in the groove and urges the piston carrier into contact with the radial wall.

A drive member of a damper device includes a first input plate member and a second input plate member that rotatably support a plurality of pinion gears of a planetary gear of a rotary inertia mass damper. A driven member includes an outer teeth gear portion that meshes with the pinion gear in an outer circumferential portion thereof and is disposed between the first and the second input plate members in an axial direction so as to work as a sun gear of the planetary gear. A stopper is configured to restrict the relative rotation between the drive member and the driven member and includes a contact portion arranged in the outer circumferential portion of the driven member so as to contact with the first input plate member.

A hybrid drive module for a motor vehicle having an input shaft, an electric machine with a stator fixed with respect to relative rotation and a rotatable rotor, a disconnect clutch in the power flow between the input shaft and the rotor, and a torque converter with a lockup clutch, the housing of the torque converter being connected to the rotor so as to be fixed with respect to rotation relative to it. The disconnect clutch is actuatable in closing direction by pressurization of a first pressure space. The lockup clutch is actuatable in closing direction through pressurization of a second pressure space. The two pressure spaces are defined at least partially by the housing of the torque converter. The housing of the torque converter separates the first pressure space directly from the second pressure space.

An electric motor includes a rotor rotatable about a center axis; and a rotor carrier including an outer circumferential surface having a varying diameter defined by radially inner surface sections and radially outer surface sections. The radially outer surface sections are bonded to an inner circumferential surface of the rotor by an adhesive. A hybrid module configured for arrangement in the torque path upstream from a transmission and downstream from an internal combustion engine includes the electric motor and a torque converter including a front cover. The rotor carrier is fixed to the front cover.

Sealed piston apparatus and related systems for use with vehicle torque converters are disclosed. A disclosed vehicle torque converter includes a housing and a clutch including a piston in the housing. The piston has a first side partially defining a first chamber and a second side, opposite the first side, partially defining a second chamber. The vehicle torque converter also includes a first seal operatively coupled to the piston and a second seal operatively coupled to the piston. The vehicle torque converter also includes an orifice positioned on the piston radially inward relative to a clutch pack of the clutch. The orifice is configured to provide a flow of a fluid between the first and second chambers during a lockup on operation of the vehicle torque converter to lubricate the clutch. The first seal is a one-way seal.

A torque transmission arrangement is provided with a clutch device which has a clutch input and output, and a vibration damping device having at least two vibration damping units arranged at a radial offset with respect to one another, an input of the vibration damping device operatively connected to the clutch output, and an output of the radially outermost vibration damping unit being operatively connected by an intermediate transmission element to an input of the radially innermost vibration damping unit operatively connected via an output of the vibration damping device to an output unit, the clutch device partially axially overlapping with one of the vibration damping units, and being connected radially between the two vibration damping units to the intermediate transmission of the vibration damping device. The intermediate transmission is connected to an absorber mass carrier of an absorber system likewise assigned to the vibration damping device.

A torque converter assembly configured to be connected between an engine and a transmission in a vehicle. The torque converter assembly comprises a cover plate, a pump, a turbine, a stator, and a clutch assembly operably connected between the cover plate and the turbine. The clutch assembly comprises a coverside plate, a turbine-side plate, and a piston located at least partially between the coverside plate and the turbine-side plate. A charge circuit is configured at least partially between the cover plate and the coverside plate, a compensation circuit is configured at least partially between the coverside plate and the piston, and an apply circuit is configured at least partially between the piston and the turbine-side plate.

A K0 clutch includes a housing, a piston, and an apply chamber. The housing includes an axial wall and a port extending radially outward from the axial wall. The piston includes a seal engaged with the axial wall. The piston is axially slidable relative to the axial wall. The apply chamber is disposed between the piston and the housing. The apply chamber is selectively fluidly communicable with the port based on a pressure in the apply chamber.

A launch device for coupling a rotary output of a prime mover to a rotary input of a transmission. The launch device includes a front cover connected to the rotary output member of the prime mover and an output hub connected to the rotary input of the transmission. A rear cover cooperates with the front cover to define a chamber in which an impeller and a turbine are located. A damper is coupled between the turbine and the output hub and a lock-out clutch is coupled to the damper to releasably lock the damper for rotation with one of the front and rear covers. Connecting the clutch assembly to the damper is a clutch plate in which a clutch drum of the clutch assembly is unitarily formed with the input members of the damper.

The present invention relates to a lock-up clutch of a torque converter. A cover (10) is separated to a pilot (48) and includes an opening (10-1) for installing the pilot (48). Before assembling a clutch driving portion such as a piston, a separator, drive plates, a seal ring, and driven plates, to the pilot (48), rivets (53) are press-fitted into the pilot (48), the cover (10) is abutted to respective head portions of the rivets (53), and the pilot (48) is installed in the cover (10) and is fixed to the cover (10) by welding. Thereafter, the piston, the drive plates and the driven plates are disposed between the separator and the cover (10), the seal ring is contact with the separator, the separator is press-fitted into projection ends of the rivets (53), and then projection portions (53-2) of the rivets (53) are crimped.