A hybrid module for arranging between an internal combustion engine, an electric machine and a transmission, wherein the hybrid module has an input shaft which is connectible to a torsional damper mounted at the internal combustion engine, wherein a starting element is provided, wherein a transmission shaft is connectible to the output side of the starting element, wherein the electric machine is arranged axially parallel to the input shaft, and wherein the electric machine is connected to the starting element by a traction mechanism drive, characterized in that a bearing plate is provided which is arranged directly adjacent the torsional damper, in that a disconnect clutch is provided between the input shaft and the starting element, and in that the disconnect clutch is constructed as dog clutch. The invention is further directed to a motor vehicle having such a hybrid module.

A centrifugal pendulum includes a first support plate, being able to rotate around a rotation axis; a second support plate, facing the first support plate in the axial direction and fixed to the first support plate. A mass is disposed between the first support plate and the second support plate in the axial direction. The first support plate has a first protrusion extending axially, and the first protrusion is integrally formed with the first support plate and defines a first track. The mass has a through hole extending axially, and the through hole defines a second track. The first protrusion extends into said through hole such that the first track faces the second track in the radial direction. A roller is disposed between the first track and the second track in the radial direction, and is capable of rolling against the first track and the second track, such that the mass is able to move relative to the first and second support plates and apply a torque onto the first and second support plates. The present invention also discloses a torque transmitting device comprising the centrifugal pendulum and a vehicle.

A damper device includes rotating elements including an input element and an output element, first elastic bodies that each transmit torque between the input element and the output element, a plurality of second elastic bodies that act in parallel with the plurality of first elastic bodies when torque transmitted between the input element and the output element is greater than or equal to a predetermined value, and a rotary inertia mass damper. The rotary inertia mass damper includes a sun gear, a carrier that rotatably supports a plurality of pinion gears, and a ring gear that meshes with the plurality of pinion gears and that serves as a mass body. The plurality of second elastic bodies are located at a different position than the plurality of first elastic bodies in a radial direction of the rotating elements and are circumferentially aligned with the plurality of pinion gears.

A damper device includes rotating elements including an input element and an output element, first elastic bodies that each transmit torque between the input element and the output element, a plurality of second elastic bodies that act in parallel with the plurality of first elastic bodies when torque transmitted between the input element and the output element is greater than or equal to a predetermined value, and a rotary inertia mass damper. The rotary inertia mass damper includes a sun gear, a carrier that rotatably supports a plurality of pinion gears, and a ring gear that meshes with the plurality of pinion gears and that serves as a mass body. The plurality of second elastic bodies are located at a different position than the plurality of first elastic bodies in a radial direction of the rotating elements and are circumferentially aligned with the plurality of pinion gears.

A hydrodynamic torque converter (1) with a lock-up clutch (6) in the form of a disk clutch in a clutch space (9) and with a piston (7) for actuating the lock-up clutch (6). The lock-up clutch (6) has an end disk (63) and a first disk carrier (61), on which the end disk (63) is radially and axially supported. The end disk (63) is arranged on the side of the lock-up clutch (6) remote from the piston (7). The lock-up clutch (6) has a second disk carrier (62). A sealing element (64) is provided, on the second disk carrier (62), a sealing gap (12) is formed between the end disk (63) and the sealing element (64).

A hydrodynamic torque converter (1) with a lock-up clutch (6) in the form of a disk clutch in a clutch space (9) and with a piston (7) for actuating the lock-up clutch (6). The lock-up clutch (6) has an end disk (63) and a first disk carrier (61), on which the end disk (63) is radially and axially supported. The end disk (63) is arranged on the side of the lock-up clutch (6) remote from the piston (7). The lock-up clutch (6) has a second disk carrier (62). A sealing element (64) is provided, on the second disk carrier (62), a sealing gap (12) is formed between the end disk (63) and the sealing element (64).

An apparatus and methods for a double coast engagement diaphragm spring for a torque converter are provided. The double coast engagement diaphragm spring includes first and second coast engagement diaphragm springs. The first coast engagement diaphragm spring exerts a first, continuous axial thrust onto a turbine comprising the torque converter. The second coast engagement diaphragm spring applies a second axial thrust onto the turbine only during coasting conditions. A drive flange includes ramps for engaging the second coast engagement diaphragm spring during coasting conditions and causing the second coast engagement diaphragm spring to apply the second axial thrust onto the turbine. A retainer plate disengages the second coast engagement diaphragm spring during drive conditions. A spacer ring between the first coast engagement diaphragm spring and the second coast engagement diaphragm spring causes the first and second coast engagement diaphragm springs to operate in series.

An apparatus and methods for a double coast engagement diaphragm spring for a torque converter are provided. The double coast engagement diaphragm spring includes first and second coast engagement diaphragm springs. The first coast engagement diaphragm spring exerts a first, continuous axial thrust onto a turbine comprising the torque converter. The second coast engagement diaphragm spring applies a second axial thrust onto the turbine only during coasting conditions. A drive flange includes ramps for engaging the second coast engagement diaphragm spring during coasting conditions and causing the second coast engagement diaphragm spring to apply the second axial thrust onto the turbine. A retainer plate disengages the second coast engagement diaphragm spring during drive conditions. A spacer ring between the first coast engagement diaphragm spring and the second coast engagement diaphragm spring causes the first and second coast engagement diaphragm springs to operate in series.

A torque transmitting device that can be rotatably mounted about an axis of rotation includes a series damper having a first damper unit, a second damper unit and a coupling unit. The first damper unit has a damper output side and the second damper unit has a damper input side. The coupling unit is arranged between the damper output side of the first damper unit and the damper input side of the second damper unit. The coupling unit has a first coupling part and a second coupling part, wherein the first coupling part and the second coupling part are arranged axially offset in relation to one another. The first coupling part connects the damper output side of the first damper unit to the second coupling part. The second coupling part connects the first coupling part to the damper input side of the second damper unit.

A torque transmitting device that can be rotatably mounted about an axis of rotation includes a series damper having a first damper unit, a second damper unit and a coupling unit. The first damper unit has a damper output side and the second damper unit has a damper input side. The coupling unit is arranged between the damper output side of the first damper unit and the damper input side of the second damper unit. The coupling unit has a first coupling part and a second coupling part, wherein the first coupling part and the second coupling part are arranged axially offset in relation to one another. The first coupling part connects the damper output side of the first damper unit to the second coupling part. The second coupling part connects the first coupling part to the damper input side of the second damper unit.