A torque transfer device mountable rotatably around an axis of rotation to transfer a drive torque between an input side and an output side, having a converter wheel of a hydrodynamic converter and a centrifugal force pendulum, which has a pendulum flange extending in an at least partially radial direction and at least one pendulum mass, where the pendulum mass is positioned on a long side of the pendulum flange and is coupled with the pendulum flange by means of a sliding block guide. A first coupling device is designed to provide a connection for transferring torque between the pendulum flange and the converter wheel, where the first coupling device is connected to the pendulum flange at least partially radially to the outside of the pendulum mass to provide an exchange of torque between the converter wheel and the pendulum flange radially to the outside of the pendulum mass.

An impeller for a torque converter is provided. The impeller includes an impeller shell including an inner circumference, an outer circumference and a radial extension extending radially outward from the inner circumference. The radial extension includes an axially extending groove formed therein. The impeller also includes an impeller hub welded to the impeller shell by a weld. The weld is radially inside of the axially extending groove. A method of forming an impeller for a torque converter is also provided.

A hydrokinetic torque coupling device for coupling together a driving shaft and a driven shaft features a casing including a casing shell and an impeller casing shell, an impeller including the impeller shell, a turbine-piston including a turbine-piston shell, and an elastic element slidably engaging the turbine-piston and being connected to the casing. The elastic element is configured to bias the turbine-piston toward the impeller. The casing is rotatable about a rotational axis so that the impeller shell is disposed axially opposite to and fixedly connected to the casing shell. The turbine-piston is coaxially aligned with and hydro-dynamically drivable by the impeller.

A hydrokinetic torque coupling device features a casing (12) including an impeller shell (18), a casing shell (20), and an intermediate casing component (22) connecting the impeller and casing shells. The intermediate casing component (22) includes a casing wall portion and a piston engagement portion (26) extending inward from and being non-rotatable relative to the casing wall portion. The device further features an impeller (30) including the impeller shell (20). The turbine-piston (32) is coaxially aligned with and hydrodynamically drivable by the impeller (30), and includes a turbine-piston shell (35) having a turbine-piston flange (38) with an engagement surface that is movable axially toward and away from an engagement surface of the piston engagement portion to position the hydrokinetic torque coupling device respectively into and out of a lockup mode.

A torque converter incorporating a case having a rotation axis; an impeller within the case, the impeller being mounted for co-rotation with the case; a turbine mounted within the case for rotation with respect to the case; radially inner and outer walls within the case, the walls defining an annulus having axial and oppositely-axial ends, the walls being mounted for co-rotation with the case or the walls being mounted for co-rotation with the turbine; a piston slidably received within the annulus; a plurality of race and roller combinations mounted at the annulus's oppositely axial end, the race and roller combinations being adapted for centrifugally driving and for axially pressing their rollers against the piston; and a friction surface within the case, the friction surface being positioned for, upon the axial pressings of the rollers against the piston, frictionally engaging and resisting rotation of the piston.

A torque converter, including: an axis of rotation; a cover arranged to receive torque; an impeller including a shell non-rotatably connected to the cover; a turbine in fluid communication with the impeller and including a turbine shell including a radially outermost segment including a radially outermost end of the turbine shell, at least one blade connected to the turbine shell and an entirety of which is located radially inward of the radially outermost segment; a vibration damper including at least one spring and at least one tab directly engaged with at least one circumferential end of the at least one spring and non-rotatably connected to the turbine shell; at least one rivet passing though the radially outermost segment and fixedly connected to the radially outermost segment; and a torque converter clutch arranged to transmit torque from the cover to the damper when the torque converter clutch is closed.

A hydrokinetic torque coupling device comprises a casing rotatable about a rotation axis, a torque converter including an impeller wheel and a turbine wheel disposed in the casing coaxially with the rotation axis, a locking piston including an annular piston body and a plurality of drive teeth unitary with the piston body, and a torsional vibration damper comprising a input member non-rotatably coupled to the drive teeth of the locking piston, elastic members and an output member elastically coupled to the input member trough the elastic members. The locking piston is axially moveable so as to selectively engage the locking piston against the casing. The input member has window-shaped mating openings complementary to each of the drive teeth. The drive teeth drivingly engage the mating openings of the input member so as to non-rotatably couple the locking piston and the input member.

A hydrokinetic torque converter for coupling driving and driven shafts. The torque converter comprises an impeller wheel rotatable around a rotational axis, a turbine wheel rotatable coaxially aligned with the impeller wheel, a stator situated axially between the impeller wheel and the turbine wheel, and a one-way turbine clutch permitting rotational movement of the turbine wheel in one circumferential direction only. The one-way turbine clutch includes an outer ring non-rotatably connected to the turbine shell, an inner ring disposed radially within the outer ring and a plurality of engagement components positioned radially between the outer and the inner rings. The turbine wheel includes a turbine shell and at least one coupling member extending axially outwardly from the turbine shell in the direction toward the one-way turbine clutch. The at least one coupling member of the turbine wheel is non-rotatably coupled to the outer ring of the one-way turbine clutch.

A hydrokinetic torque converter comprises a casing, an impeller wheel, a turbine wheel coaxially aligned with the impeller wheel, a stator situated between the impeller and turbine wheels, a one-way turbine clutch permitting rotational movement of the turbine wheel in one circumferential direction only, and a torsional vibration damper. The one-way turbine clutch includes an outer ring non-rotatably coupled to the turbine wheel, an inner ring and engagement components positioned between the outer and the inner rings. The torsional vibration damper comprises an input member, circumferentially acting elastic members, and an output member elastically coupled to the input member through the elastic members. The output member of the torsional vibration damper is non-rotatably coupled to the outer ring of the one-way turbine clutch. The turbine wheel is non-rotatably coupled to one of the outer ring of the one-way turbine clutch and the output member of the torsional vibration damper.

A lock-up device includes a clutch disc, a piston, a temperature detection member and a gap adjustment mechanism. The clutch disc is disposed between a front cover and a turbine. The piston is disposed in opposition to the front cover through the clutch disc so as to be movable in an axial direction, and presses the clutch disc toward the front cover. The deformation amount of the temperature detection member is adjusted in accordance with surrounding temperatures. In accordance with the deformation amount, the gap adjustment mechanism adjusts a gap between the front cover and the piston to be a first gap at a first temperature. Further, in accordance the deformation amount, the gap adjustment mechanism adjusts the gap between the front cover and the piston to be a second gap narrower than the first gap at a second temperature higher than the first temperature.