A transmission includes an input shaft coupled to a prime mover, a countershaft, main shaft, and an output shaft, with gears between the countershaft and the main shaft. A shift actuator selectively couples the input shaft to the main shaft by rotatably coupling gears between the countershaft and the main shaft. The shift actuator is mounted on an exterior wall of a housing including the countershaft and the main shaft. An integrated actuator housing is operationally coupled to the shift actuator and a linear clutch actuator. The linear clutch actuator is a self-adjusting actuator, and the transmission includes a self-adjusting clutch.

A clutch device has a friction transmission element which has a base with at least one friction surface, at least one control element for acting on a damping device, and at least one radial support which cooperates with a stop and has a plurality of lugs which extend at least substantially radially in direction toward the stop and which are at least substantially brought closer to the stop up to a gap before the stop when the friction transmission element is stationary, while, at speed, at least a portion of the lugs comes in contact with the stop. The lugs are connected to the base via a bend which causes an axial offset with respect to the base, the bend allows a displacement of the lugs in direction toward the energy accumulators, and the lugs are completely covered by the stop in an axial extension direction.

A clutch device has a friction transmission element which has a base with at least one friction surface, at least one control element for acting on a damping device, and at least one radial support which cooperates with a stop and has a plurality of lugs which extend at least substantially radially in direction toward the stop and which are at least substantially brought closer to the stop up to a gap before the stop when the friction transmission element is stationary, while, at speed, at least a portion of the lugs comes in contact with the stop. The lugs are connected to the base via a bend which causes an axial offset with respect to the base, the bend allows a displacement of the lugs in direction toward the energy accumulators, and the lugs are completely covered by the stop in an axial extension direction.

The friction clutch comprises: a driving part comprising at least one first friction element; a driven part comprising a hub and at least one second friction element drivingly connected for rotation with the hub; at least one spring configured to press the friction elements of the driving part and of the driven part against each other by applying an elastic force on these friction elements; and an actuation unit arranged to bring about opening of the friction clutch by applying directly or indirectly on the at least one spring an actuating force directed in the opposite direction to the elastic force so as to move the friction elements away from each other. The actuation unit comprises a thrust bearing, at least one force transmission member and a hollow actuating member arranged to apply the actuating force on the at least one spring via the thrust bearing and the at least one force transmission member. The hollow actuating member is arranged on the opposite side of the hub to the at least one spring. The at least one force transmission member extends through the hub.

The friction clutch comprises: a driving part comprising at least one first friction element; a driven part comprising a hub and at least one second friction element drivingly connected for rotation with the hub; at least one spring configured to press the friction elements of the driving part and of the driven part against each other by applying an elastic force on these friction elements; and an actuation unit arranged to bring about opening of the friction clutch by applying directly or indirectly on the at least one spring an actuating force directed in the opposite direction to the elastic force so as to move the friction elements away from each other. The actuation unit comprises a thrust bearing, at least one force transmission member and a hollow actuating member arranged to apply the actuating force on the at least one spring via the thrust bearing and the at least one force transmission member. The hollow actuating member is arranged on the opposite side of the hub to the at least one spring. The at least one force transmission member extends through the hub.

A wedge clutch, including: a hub; a ring located radially outward of the hub; a wedge plate radially between the hub and the ring; and a displacement assembly including an element and an engagement arm. To transition from a disconnect mode for the wedge clutch, in which the hub and the ring are relatively rotatable, to a connect mode for the wedge clutch, the engagement arm is arranged to pivot in a first rotational direction to displace the hub in a first axial direction. To transition from the connect mode to the disconnect mode, the engagement arm is arranged to pivot in a second rotational direction, opposite the first rotational direction and the element is arranged to displace the hub in a second axial direction, opposite the first axial direction.

A wedge clutch, including: a shaft; a hub radially disposed about the shaft; an outer ring located radially outward of the hub; a wedge plate radially disposed between the hub and the outer ring; and a displacement assembly including a first element and a plunger assembly at least partly disposed within the hub. To transition from a disconnect mode to a connect mode, the displacement assembly is arranged to displace the hub in a second axial direction and a portion of the plunger assembly is arranged to displace radially inward to block axial displacement of the hub in the first axial direction. To transition from the connect mode to the disconnect mode, the portion of the plunger assembly is arranged to displace radially outward through the hub and the first element is arranged to displace the hub in the first axial direction.

A wedge clutch, including: a shaft; a hub radially disposed about the shaft; an outer ring located radially outward of the hub; a wedge plate radially disposed between the hub and the outer ring; and a displacement assembly including a first element and a plunger assembly at least partly disposed within the hub. To transition from a disconnect mode to a connect mode, the displacement assembly is arranged to displace the hub in a second axial direction and a portion of the plunger assembly is arranged to displace radially inward to block axial displacement of the hub in the first axial direction. To transition from the connect mode to the disconnect mode, the portion of the plunger assembly is arranged to displace radially outward through the hub and the first element is arranged to displace the hub in the first axial direction.

A hybrid module for a drive train of a motor vehicle includes an electrical machine, a dry friction clutch for coupling the electrical machine with the drive train, an input shaft arranged to be coupled to an internal combustion engine of the motor vehicle, and an output shaft arranged to be coupled to a vehicle transmission of the motor vehicle. The dry friction clutch is designed to lead away or secure wear debris of the dry friction clutch. The hybrid module may be arranged as a P2 hybrid module within the drive train between an internal combustion engine side of the motor vehicle and a vehicle transmission side of the motor vehicle. The dry friction clutch may be a dry multi-disk clutch.

A clutch structure that includes a motor to directly drive a rotary disc of an actuation unit, and the actuation unit further directly act on a push unit, so as to achieve reduction of size. Further, the push unit has a spring holder that drives a push bracket to press against a clutching unit, and the push bracket and the clutching unit are rotatably in synchronization with each other and a group of balls is arranged between the push bracket and the spring holder, such that smooth rotation can be maintained even during the process of pressing to thereby effectively reduce pause and setback incurring in coupling and connection and also to efficiently establish a transmission clutching force to have the operability not affected by the delay.