Power transmission systems including clutch arrangement and control systems are adapted to be used in numerous different operational environments. Such power transmission systems may include clutch arrangements that provide more effective power transmission capabilities, reduced vibration, greater durability and longer life. Control arrangements are provided to more effectively control and monitor clutch operation in ways that provide for greater system flexibility and drive options. Structures that minimize vibrations may be included in a clutch housing as well as in clutch and separator discs of a disc pack.

A lock-up device of a torque converter consisting of a lock-up clutch, a lock-up piston, an input side clutch supporter, etc., and a lock-up device with excellent assemblability while simultaneously reducing mutual rotation between a lock-up piston and an input side clutch supporter, which increases a response of the lock-up piston, is provided.

The lock-up device of a torque converter includes an input side clutch supporter fixed to a front cover for transmitting a power from a drive side; a plurality of clutch plates supported by the input side clutch supporter; a lock-up piston to pressurize the clutch plate to make the clutch connected; a piston guide supporting the end portion of the lock-up piston; a spring pack fixed to the lock-up piston, installed between the lock-up piston and the input side clutch supporter and including an elastic body that presses the lock-up piston in the direction of releasing the clutch; and an mutual rotation prevention mechanism that prevents a mutual rotation between the lock-up piston and the input side clutch supporter.

A twin plate separation system, comprising a pressure plate, an intermediate plate facing the pressure plate, and a spring separator assembly. The spring separator assembly comprises a mounting extending out from the intermediate plate towards the pressure plate. A spring surrounds the mounting, and the spring is biased to push the pressure plate and the intermediate plate apart. The mounting or another fixture can secure at least one drive strap to the intermediate plate. Alternatively, the mounting extends out of the pressure plate towards the intermediate plate, and the spring surrounds the mounting and is biased to push the pressure plate and the intermediate plate apart. In this alternative, the intermediate plate does not comprise a hole for receiving the mounting.

A twin plate separation system, comprising a pressure plate, an intermediate plate facing the pressure plate, and a spring separator assembly. The spring separator assembly comprises a mounting extending out from the intermediate plate towards the pressure plate. A spring surrounds the mounting, and the spring is biased to push the pressure plate and the intermediate plate apart. The mounting or another fixture can secure at least one drive strap to the intermediate plate. Alternatively, the mounting extends out of the pressure plate towards the intermediate plate, and the spring surrounds the mounting and is biased to push the pressure plate and the intermediate plate apart. In this alternative, the intermediate plate does not comprise a hole for receiving the mounting.

The present disclosure provides a wet friction engaging device. The device includes: a plate group engaged with two connecting members and including two groups of friction plates housed in a plate housing chamber and alternately arranged in an axial direction with surfaces facing each other; and a piston configured to apply a pressing force to the plate group. The plate group is switched between an engaged state in which the friction plates are in close contact with each other, and a disengaged state in which the friction plates are separable from each other. One of end plates at respective ends of the plate group is a movable end plate movable in the axial direction, and the other is a stationary end plate immovable in the axial direction. The movable end plate is biased by a spring.

The present disclosure provides a wet friction engaging device. The device includes: a plate group engaged with two connecting members and including two groups of friction plates housed in a plate housing chamber and alternately arranged in an axial direction with surfaces facing each other; and a piston configured to apply a pressing force to the plate group. The plate group is switched between an engaged state in which the friction plates are in close contact with each other, and a disengaged state in which the friction plates are separable from each other. One of end plates at respective ends of the plate group is a movable end plate movable in the axial direction, and the other is a stationary end plate immovable in the axial direction. The movable end plate is biased by a spring.

A multi-plate clutch includes an outer plate mounted on a radial outside and axially displaceable, an inner plate mounted on a radial inside and axially displaceable, and a plurality of leaf springs. The plurality of leaf springs is distributed around an outer circumference of the outer plate to mount the outer plate in a torque-transmitting manner on a rotor pot, or the plurality of leaf springs is distributed in an inner circumference of the inner plate to mount the inner plate in a torque-transmitting manner on a driving ring. In an example embodiment, the multi-plate clutch is a dry multi-plate clutch for a hybrid drivetrain. In an example embodiment, the multi-plate clutch includes a plurality of outer plates and a plurality of inner plates.

A multi-plate clutch includes an outer plate mounted on a radial outside and axially displaceable, an inner plate mounted on a radial inside and axially displaceable, and a plurality of leaf springs. The plurality of leaf springs is distributed around an outer circumference of the outer plate to mount the outer plate in a torque-transmitting manner on a rotor pot, or the plurality of leaf springs is distributed in an inner circumference of the inner plate to mount the inner plate in a torque-transmitting manner on a driving ring. In an example embodiment, the multi-plate clutch is a dry multi-plate clutch for a hybrid drivetrain. In an example embodiment, the multi-plate clutch includes a plurality of outer plates and a plurality of inner plates.

The lock-up device of a torque converter includes an input side clutch supporter fixed to a front cover for transmitting a power from a drive side; a plurality of clutch plates supported by the input side clutch supporter; a lock-up piston to pressurize the clutch plate to make the clutch connected; a piston guide supporting the end portion of the lock-up piston; a spring pack fixed to the lock-up piston, installed between the lock-up piston and the input side clutch supporter and including an elastic body that presses the lock-up piston in the direction of releasing the clutch; and an mutual rotation prevention mechanism that prevents a relative rotation between the lock-up piston and the input side clutch supporter.

The lock-up device of a torque converter includes an input side clutch supporter fixed to a front cover for transmitting a power from a drive side; a plurality of clutch plates supported by the input side clutch supporter; a lock-up piston to pressurize the clutch plate to make the clutch connected; a piston guide supporting the end portion of the lock-up piston; a spring pack fixed to the lock-up piston, installed between the lock-up piston and the input side clutch supporter and including an elastic body that presses the lock-up piston in the direction of releasing the clutch; and an mutual rotation prevention mechanism that prevents a relative rotation between the lock-up piston and the input side clutch supporter.