In some embodiments, a torque damper apparatus can achieve reduced stiffness as well as sufficient vibration absorbing property while increasing the dampening ratio of the torque variation. In some embodiments, a torque damper apparatus comprises an input member to which an engine torque is inputted; damper springs able to absorb variation of torque inputted from the input member; and/or a driving power of the engine configured to be transmitted to an output shaft of a vehicle via the input member and the damper springs. The damper springs can comprise a plurality of coil springs arranged along the circumference of the input member. The torque damper apparatus can further comprise a plurality of separate members interposed between the damper springs and configured to be independently rotated with respect to each other when the engine torque is transmitted thereto.

A torsional vibration reduction device that is provided inside of a fluid power transmitting device that has a driving side member that generates a fluid flow, and a driven side member that is driven by the fluid flow, includes a rolling element configured to move in a reciprocating manner according to a variation in torque; a retaining member that has a rolling chamber configured to house the rolling element in a manner that enables the rolling element to move in a reciprocating manner; and a housing configured to shield the rolling element and the rolling chamber from fluid inside of the fluid power transmitting device. The retaining member is enclosed and fixed inside the housing, and the housing is fixed to the driven side member.

The present invention relates to a lockup apparatus for a torque converter and aims to obtain a smooth relative movement of a equalizer plate with respect to a deformation of a drive plate. The drive plate 26 as an inlet sided rotating member is connected to a driven plate 22 as an outlet sided rotating member by means of damper springs 28 in a rotating direction. The damper spring 28 is constructed by a pair of divided parts 28A and 28B. An equalizer plate as an intermediate member 29 is arranged so as to slide rotatably on bearing parts 26-1 of the drive plate 26 and supporting parts 40 fixed to the equalizer plate 29 are arranged between the divided parts 28A and 28B of the damper springs 28. The bearing part 26-1 of the drive plate 26 has an outer peripheral surface 26-1a, of which arc shape has a center C of a curvature which is offset from the center C of the arc shape of the inner peripheral surface 29a of the equalizer plate 29.

A damper device where the first and second elastic bodies are arranged side by side in a circumferential direction of the damper device, and the third and fourth elastic bodies are placed outside the first and second elastic bodies in a radial direction of the damper device so as to be arranged side by side in the circumferential direction.

A thrust washer for a torque converter is provided. The thrust washer includes an inner circumferential surface, an outer circumferential surface and a first axial surface extending from the inner circumferential surface to the outer circumferential surface. The axial surface includes a plurality of arcuate sections and a plurality of grooves circumferentially between the arcuate sections. Each of the arcuate sections includes an arcuate axial surface including a first section, a second section and a third section. The first and third sections extend circumferentially away from the second section in opposite directions and extend axially inward from the second section. A torque converter and a method for forming at least one torque converter are also provided.

A damper device that includes a first torque transmission path including a first elastic body that transmits torque between the input element and the output element; and a second torque transmission path disposed in parallel with the first torque transmission path and including first and second intermediate elements, a second elastic body that transmits the torque between the input element and the first intermediate element, a third elastic body that transmits the torque between the first intermediate element and the second intermediate element, and a fourth elastic body that transmits the torque between the second intermediate element and the output element.

A torque converter comprising a torque input element (19), an impeller wheel (3) rotationally coupled to the torque input element (19) and able to hydrokinetically drive a turbine wheel (4), a torque output element (8), clutch means (10, 38) movable between an engaged position in which the torque input element (19) and the torque output element (8) are rotationally coupled through damping means (12, 43, 44, 45), and a disengaged position in which the torque input element (19) and the torque output element (8) are rotationally coupled through the impeller wheel (3) and the turbine wheel (4), with a first bearing (31) being axially mounted between the impeller wheel (3) and the reactor (5), with a second bearing (31) being axially mounted between the reactor (5) and the turbine wheel (4).

A piston plate assembly for a torque converter comprising: an aperture including a chamfer portion; and, a bushing installed in the aperture and including a radius portion proximate the chamfer portion, wherein the bushing is arranged to seal the piston directly to a transmission input shaft and the radius portion is arranged to ease assembly of the bushing onto the input shaft.

A hydrokinetic torque coupling device for a motor vehicle comprises an impeller wheel intended to be coupled to a crankshaft and adapted to hydrokinetically rotate a turbine wheel. The impeller wheel rotationally coupled to a cover at least partially accommodating the impeller wheel, the turbine wheel and the reactor. The turbine wheel is axially moves between an engaged position in which the turbine wheel and the impeller wheel are axially moved closer to each other and rotationally coupled together, and a disengaged position in which the turbine wheel and the impeller wheel are axially moved away from each other and rotationally uncoupled. The device comprises a bracing member axially extending between the turbine wheel and a part of the cover, with the bracing member being adapted to limit the axial motion of the turbine wheel toward the above-mentioned part of the cover, opposite the turbine wheel.

A hydrokinetic torque converter comprises an impeller rotatable about a rotational axis, a coaxial turbine, and a stator disposed between the impeller and the turbine. The stator includes an annular stator hub, an annular radially outer stator rim, a plurality of stator blades radially outwardly extending between the stator hub and the stator rim, and an annular outer stator flange extending radially outwardly from the stator rim thereof and disposed between an impeller core ring and a turbine core ring. The stator further includes a plurality of hydraulic pressure grooves provided on at least one of axially opposite impeller and turbine side surfaces of the stator flange. The hydraulic pressure grooves face at least one of the impeller and turbine core rings so as to create a hydrodynamic lift between the stator and at least one of the impeller and turbine core rings in the axial direction.