A coupling arrangement is provided with a vibration reduction device and with a clutch device. The vibration reduction device has at least one torsional vibration damper, an input connected to a drive, and an output connected to the clutch device by which a connection between the vibration reduction device and a driven end is at least substantially produced in a first operating state, and this connection is at least substantially cancelled in a second operating state. The vibration reduction device has a mass damper system that cooperates with the torsional vibration damper and is connected to the output of the vibration reduction device.

A torque converter includes a front cover arranged to receive a torque and a lock-up clutch. The lock-up clutch includes a leaf spring, a piston, a first clutch plate, a second clutch plate, and an intermediate clutch plate. The leaf spring includes a base non-rotatably connected to the front cover and two legs extending from the base. The piston is non-rotatably connected to one of the legs. The first clutch plate and the second clutch plate are connected to each other. The first and second clutch plates each being disposed between the piston and front cover. The intermediate clutch plate is disposed between the first and second clutch plates and is non-rotatably connected to the other of the legs.

A clutch that includes a friction plate; a separator plate; a clutch hub; and a piston that presses the friction plate and the separator plate, wherein the clutch hub includes a hub on which an inner peripheral portion of the friction plate or the separator plate is fitted, a tubular shaft that movably supports the piston, and an engagement oil chamber defining wall that together with the piston defines an engagement oil chamber to which an engagement oil pressure is supplied, the hub is spline-fitted on a gear of a planetary gear so as to rotate with the gear, and the tubular shaft is rotatably supported by a central shaft and is fitted by a spigot joint in the gear.

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 washer having such a thickness t that a value (L3(L1+L2+t)) obtained by subtracting the sum of a first distance L1 in an axial direction between a leading end face of a friction member and a face of a lockup piston, a second distance L2 in the axial direction between a shell-side abutting face of a pump shell and a face of an outside extended portion of an output hub, and the thickness t in the axial direction of the washer, from a third distance L3 in the axial direction between an opposed face of a front cover and a cover-side abutting face of a tubular portion, is in a predetermined range larger than zero, is selected and placed between the lockup piston and the outside extended portion of the output hub.

A torque transferring transmission-drive system includes a first friction surface. A second friction surface is directed toward the first friction surface. A reaction plate is positioned between the first friction surface and the second friction surface. A piston is actuated by a fluid pressure to displace the first friction surface toward the second friction surface, frictionally engaging the reaction plate between the first friction surface and the second friction surface. At least one strap spring in a clutch engaged condition elastically compresses to allow the reaction plate to be frictionally engaged between the first friction surface and the second friction surface, and in a clutch disengaged condition the at least one strap spring elastically expands to create a clearance between the reaction plate and each of the first friction surface and the second friction surface.

A torsional vibration damper (70) with a damping device which has an input (67) and an output (72) which is operatively connected to a driven side (73). The output is connected to a mass damper system (1) and also to a mass arrangement (100). One of the two subassembliesi.e., mass damper system (1) and mass arrangement (100)which are connected to the output (72) of the damping device (70) engages at the respective other subassembly comprising mass damper system or mass arrangement which is in turn connected to the output by a connection arrangement (77).

The present invention provides a lock-up clutch for a torque converter. The lock-up clutch includes an outer carrier, an inner carrier, a first friction plate, a rotation of which is restricted by the outer carrier, and a second friction plate, a rotation of which is restricted by the inner carrier. All key grooves of the outer and inner carriers are opened in two radial opposite directions, and flow path grooves defined between friction members attached to the friction plate are aligned with circumferential positions of keys of the friction plate. Therefore, oil for cooling a clutch pack may smoothly flow through the inner carrier, the flow path grooves, and the outer carrier.

In a lock-up clutch of a starting device, a one-sided friction plate is adopted as a first friction engagement plate fitted with a clutch hub on the power input side and a second friction engagement plate fitted with a clutch drum on the power output side; an engagement oil chamber is defined between a lock-up piston and a flange member; a supply oil passage through which working oil is supplied to the first and second friction engagement plates and is defined between the lock-up piston and a front cover; a return oil passage for the working oil which has passed through the first and second friction engagement plates and is defined on the side of the flange member opposite to the lock-up piston; and the return oil passage communicates with the supply oil passage.

A torque converter, including: a cover; a lock-up clutch with a piston plate; an output hub; a first hub including a through-bore; a chamber bounded by the turbine; an apply chamber bounded by the piston plate; a release chamber bounded by the cover, the first hub, and the piston plate; a first flow path; a through-bore through the first hub; and a second flow path. The second flow path: is sealed from the first chamber; passes through the through-bore; and includes a portion circumferentially aligned with the first flow path. A line in an axial direction passes through the through-bore without intersecting the first hub. For a lock-up mode, pressurized fluid in the apply chamber displaces the piston plate in a first axial direction. For a torque converter mode, pressurized fluid in the release chamber displaces the piston plate in a second axial direction.