A friction clutch for a motor vehicle includes an adjustment mechanism compensating for wear of a friction disk. The adjustment mechanism (40) includes a first cam ring (52) rotatably fixed and a second cam ring (54) rotatable relative to the first cam ring (52). Both cam rings (52,54) have a plurality of cam surfaces configured such that rotation of the second cam ring (54) relative to the first cam ring (52) varies a height of the adjustment mechanism (40). A torsion spring (60) applies a biasing force to the second cam ring (54). A back drive prevention assembly (70) includes a back drive spring (80) attached to the pressure plate and first cam ring (52) to prevent back drive of the second cam ring (54) through a baffle (62) including a plurality of cam teeth (72) formed on a bottom surface of the baffle (62). The cam teeth (72) are formed at an angle A relative to a bottom surface of the baffle (62) decreasing displacement and loads of the back drive spring (80).

A self-adjusting clutch mechanism has a pressure plate, a wear compensation plate, a wear sensor adjusting plate, a wear sensor, a clutch cover, a first screw thread, and a second screw thread. The mechanism on the clutch pressure plate can keep clutch pedal load and clutch clamp load constant.

A clutch (100) having: a fixed hub (201), a movable hub (202), a plurality of discs (204). The fixed hub (201) and the movable hub (202) axially slide, getting farther or closer so as to transmit a variable axial load onto the discs (204). The clutch (100) has a pressure plate assembly (208) including a centrifugal assembly (210), having: a rotatable mass holder (211) and a plurality of mass elements (212) radially disposed. Each mass element (212) has a pivot (301) and is configured for a displacement (1002) by pivoting under centrifugal effects. The mass elements (212) are configured for bringing the movable hub (202) closer to the fixed hub (201), so as to increase the variable axial load and allowing the clutch (100) (automatic) engagement. Each mass element (212) has a main body (302) and a column element (303) which connects the pivot (301) with the main body (302).

A clutch (100) having: a fixed hub (201), a movable hub (202), a plurality of discs (204). The fixed hub (201) and the movable hub (202) axially slide, getting farther or closer so as to transmit a variable axial load onto the discs (204). The clutch (100) has a pressure plate assembly (208) including a centrifugal assembly (210), having: a rotatable mass holder (211) and a plurality of mass elements (212) radially disposed. Each mass element (212) has a pivot (301) and is configured for a displacement (1002) by pivoting under centrifugal effects. The mass elements (212) are configured for bringing the movable hub (202) closer to the fixed hub (201), so as to increase the variable axial load and allowing the clutch (100) (automatic) engagement. Each mass element (212) has a main body (302) and a column element (303) which connects the pivot (301) with the main body (302).

A transmission mechanism (1) for actuating a friction clutch, which can be disengaged against a spring force and is arranged between an internal combustion engine and a manual transmission, includes two lockable elements (11, 16) that are movable toward one another longitudinally to automatically change the length and compensate for clutch wear. The first element (16) consists of a spindle (16) which is coupled to a non-rotatable component of a disengagement mechanism of the friction clutch in a rotationally fixed and axially displaceable manner and has a steep-pitch external thread (19). second element (11) consists of a nut (11) having a steep-pitch internal thread (15) which is complementary thereto and into which the spindle (16) can be screwed, the pitch of the steep-pitch thread (15, 19) being dimensioned in such a way that no self-locking can occur between the two elements (11, 16).

A transmission mechanism (1) for actuating a friction clutch, which can be disengaged against a spring force and is arranged between an internal combustion engine and a manual transmission, includes two lockable elements (11, 16) that are movable toward one another longitudinally to automatically change the length and compensate for clutch wear. The first element (16) consists of a spindle (16) which is coupled to a non-rotatable component of a disengagement mechanism of the friction clutch in a rotationally fixed and axially displaceable manner and has a steep-pitch external thread (19). second element (11) consists of a nut (11) having a steep-pitch internal thread (15) which is complementary thereto and into which the spindle (16) can be screwed, the pitch of the steep-pitch thread (15, 19) being dimensioned in such a way that no self-locking can occur between the two elements (11, 16).

A dual gain friction clutch is adapted to transmit an operational range of torques from a drive member to a driven member. The dual gain friction clutch incorporates a first friction clutch pack and a second friction clutch pack, the pack being axially aligned and adapted to address one of two segments of the operational range of torques. The clutch further includes a spring-loaded skate detent unit configured to control transition between the two segments of operational ranges of torques. Each friction clutch pack may include identical respective friction discs coupled to the drive member and respective pressure plates coupled to the driven member for selectively providing torque control within either of the lower and higher segments of the operational ranges of torques. The first clutch pack is configured to operate alone and independently of the second clutch pack during the lower segment of operational range of torques, while and both friction clutch packs are configured to operate as a single combined friction clutch unit during the higher segment of operational range of torques.

A dual gain friction clutch is adapted to transmit an operational range of torques from a drive member to a driven member. The dual gain friction clutch incorporates a first friction clutch pack and a second friction clutch pack, the pack being axially aligned and adapted to address one of two segments of the operational range of torques. The clutch further includes a spring-loaded skate detent unit configured to control transition between the two segments of operational ranges of torques. Each friction clutch pack may include identical respective friction discs coupled to the drive member and respective pressure plates coupled to the driven member for selectively providing torque control within either of the lower and higher segments of the operational ranges of torques. The first clutch pack is configured to operate alone and independently of the second clutch pack during the lower segment of operational range of torques, while and both friction clutch packs are configured to operate as a single combined friction clutch unit during the higher segment of operational range of torques.

A clutch device having at least one counter-pressure plate, a contact plate that is movable relative to the counter-pressure plate to a limited extent in an axial direction of the clutch device to frictionally clamp a clutch plate between the counter-pressure plate and the contact plate, and a wear adjustment device to compensate for wearing of the clutch plate, where the wear adjustment device has at least one drive ring which is rotatable and is clampable in the axial direction and at least one ramp ring which is rotatable and is clampable in the axial direction, which is connected to the drive ring by means of a torque-transferring link which permits limited relative travel in the circumferential direction of the clutch device, where the rigidity of the connection in the circumferential direction is dependent on the direction, is provided.

An end disk of a multi-disk clutch is described, which has a ring plate, the ring plate having a central opening and at least one axial impression on a front side via which a corresponding projection is formed on the opposite front side.