A torque converter (10) including a lock-up clutch, the lock-up clutch (20) having an axially displaceable and/or axially elastic actuating element (26) for actuating the lock-up clutch, the actuating element being designed as a component different from the turbine and being mounted on the turbine.

A torsional vibration damper assembly for a hydrokinetic torque coupling device, comprises a torsional vibration damper and a dynamic absorber operatively connected to the torsional vibration damper. The torsional vibration damper comprises a driven member rotatable about a rotational axis, a first retainer plate rotatable relative to the driven member coaxially with the rotational axis, and a plurality of damper elastic members interposed between the first retainer plate and the driven member. The damper elastic members elastically couple the first retainer plate to the driven member. The dynamic absorber includes an inertial member. The dynamic absorber is mounted to the torsional vibration damper and is rotationally guided and centered relative to the rotational axis by one of the first retainer plate and the driven member of the torsional vibration damper.

In a starting device including a centrifugal-pendulum vibration absorbing device, while lock-up is released, a flow of working oil directed from a lock-up piston side toward a damper mechanism is produced in a clutch engagement chamber. A thrust force in the axial direction directed from the lock-up piston toward the damper mechanism is applied to a weight, of a mass body of the centrifugal-pendulum vibration absorbing device, disposed on the lock-up piston side. A support member of the centrifugal-pendulum vibration absorbing device is provided with weight support protrusions that project in the axial direction of an input shaft of a speed change device toward the weight disposed on the lock-up piston side.

A hybrid drive module, including: a torque converter with an output shaft, a cover for connection to a flex plate for an internal combustion engine, an impeller non-rotatably connected to the cover, a turbine, and a torsional damper including an input part non-rotatably connected to the turbine, an output part non-rotatably connected to the output shaft, and at least one circumferentially aligned coil spring engaged with the input part and output parts; an output hub arranged to non-rotatably connect to a transmission input shaft; and a disconnect clutch assembly including a first clutch component non-rotatably connected to the output hub and arranged to non-rotatably connect to an electric motor and a second clutch component non-rotatably connected to the output shaft. A torque path from the cover to the output hub passes through in sequence: the turbine, the damper, the output shaft, the second clutch component, and the first clutch component.

A hydrokinetic torque coupling device features an impeller including an impeller shell and impeller blades, and a turbine-piston including a turbine-piston shell and turbine blades. The turbine-piston is movable axially toward and away from the impeller shell to position the torque converter (or a hydrokinetic torque coupling device containing the torque converter) into and out of lockup mode. The impeller shell comprises a toroidal impeller shell portion that terminates at a first distal end clutch surface. The turbine-piston shell comprises a toroidal turbine-piston shell portion and a folded-over portion folded over onto the toroidal turbine-piston shell portion so as to engage the toroidal turbine-piston shell portion of the turbine-piston shell. The turbine-piston shell terminates at a second distal end clutch surface defined by the toroidal turbine-piston shell portion and the folded-over portion so that the second distal end clutch surface faces the first distal end clutch surface.

An axial-direction space can be made more compact while widening a damper twisting angle of a lockup device such that a damper characteristic can be further improved. This torque converter comprises a torque converter main body and a lockup device. The lockup device has a plurality of outer peripheral-side torsion springs and a plurality of inner peripheral side torsion springs. The outer peripheral-side torsion springs are arranged along a circumferential direction at an attachment diameter. The inner peripheral-side torsion springs are arranged along a circumferential direction at a second attachment diameter radially inward of the outer peripheral torsion springs and operate in series with the outer peripheral torsion springs. Also, the attachment diameter is equal to or larger than an outer diameter of a torus, and the attachment diameter is equal to or smaller than an inner diameter of the torus.

A method for manufacturing a fluid power transmission includes a first step of assembling a blade/core provisional assembly having a plurality of blades movably linked to a core, involving aligning the plurality of blades on a blade alignment jig, laying the core over a group of blades while extending a projecting piece provided on each blade through a latching hole provided in the core, and bending an extremity part of the projecting piece thus preventing the projecting piece from coming out of the latching hole, a second step of setting the blade/core provisional assembly at a predetermined position on an inside face of the shell, and a third step of carrying out brazing between the projecting piece and the latching hole and between the blade and the shell. Such method provides a high quality impeller of a fluid power transmission by joining a shell, a blade, and a core.

A starter element for a drivetrain of a motor vehicle having a housing, the housing being mounted on at least one shaft and the housing being coupled by means of an elastic element to a component located in a power stream of the starter element.

A vehicular fluid power transmitting device includes a pump impeller, a turbine runner, a damper device, a set member, and a centering member. The pump impeller has a pump shell to which torque from a drive source is input. The damper device has a damper input member and a damper output member. The damper input member is connected to an output shaft of the drive source. The damper output member is connected to the pump shell. The set member is fixed to the pump shell, and is connected to the damper output member. Also, the centering member is provided protruding toward the pump shell from the output shaft of the drive source, and is fitted together with the damper input member.

A drive assembly of a torque converter is provided. The drive assembly includes a piston having at least one tab, and a damper assembly. The piston is fixed to the damper assembly by the at least one tab. A method of forming a drive assembly for a torque convert is also provided. The method of forming a drive assembly for a torque converter includes fixing a piston and a damper assembly together by a plurality of piston tabs forming a riveted connection. A torque converter is also provided.