A torque transmitting device for transmitting torque between a first drive element and an output element, having a torque transmitting unit with a housing delimiting a first fluid chamber filled with a liquid, and a separating clutch arranged outside of the torque transmitting unit and the first fluid chamber in a second fluid chamber separated from the first chamber and which selectively transmits torque between the first drive element and the torque transmitting unit. The separating clutch has a clutch output that is connectable to a clutch input via a friction device and a clutch actuator that comprises a pressing element and an actuation element to which fluid pressure can be applied to move the actuation element. The pressing element is arranged within the second fluid chamber, and the actuation element is at least partly arranged within the first fluid chamber so that pressure is applied thereto by fluid pressure.

A method of making a wet friction material includes coating a first outer surface of a cellulose layer with a friction coating; placing a matrix of fibers and filler particles on a second outer surface of the cellulose layer; and saturating the matrix of fibers and filler particles with a binder and curing the binder to join the matrix of fibers and filler particles together to form a wet friction material base layer and to join wet friction material base layer to the second outer surface of the cellulose layer.

A torque converter includes a cover, an impeller including an impeller shell connected to the cover, a turbine including a turbine shell and at least one turbine blade fixed to the turbine shell, a seal plate, wherein the seal plate located axially between the cover and the turbine shell, and a pilot hub connected to the seal plate utilizing a spline connection.

The present invention discloses a clutch with torque converter clearance that prevents internal interference with the components of the torsional vibration filtering device, and also allows an easy and quick evaluation of the clutch clearance around 360° of the piston when the clutch is engaged. To achieve the above, a normally coupled clutch with torque converter clearance comprising a piston cap; at least one friction disc; and a piston is implemented; the piston in turn comprises a pressure plate and a cover core, where the cover core comprises a mechanical stop or retainer as main element.

A hybrid powertrain for an automobile includes a transmission adapted to provide power to wheels of the automobile, an engine adapted to provide power to an input shaft of the transmission, and an electric motor-generator unit adapted to provide power to the input shaft of the transmission, wherein the electric motor-generator is positioned within the transmission, coaxial with the transmission input shaft, the electric motor-generator being supported by and enclosed within a pump support of the transmission.

A torque converter having a shell formed by a front cover assembly and a rear cover. The front cover assembly further includes a front cover and a front boss, with the front boss being fixedly mounted to the front cover. The torque converter further including an impeller, a turbine located within the shell, a lock-up clutch and a piston. The piston being axially moveable relative to the front cover assembly along a central axis of the torque converter. A leaf spring, positioned between the piston and the front cover assembly, connects the piston to the front cover assembly.

A torque converter including: a cover arranged to receive torque; an impeller; a turbine in fluid communication with the impeller; a stator assembly; a lock-up clutch including an axially displaceable piston plate; a vibration damper including an output flange, a retainer plate, and a spring directly engaged with the output flange and retainer plate; a first combination component having a first single unified structure including a first section forming a pilot hub located radially inward of the cover and non-rotatably connected to the cover, and a second section forming a seal plate of the lock-up clutch; and a second combination component having a second single unified structure including a third section forming a shell of the turbine, and a fourth section forming a cover plate of the vibration damper, the fourth section directly engaged with the spring and non-rotatably connected to the retainer plate.

A torque converter assembly is disclosed herein. The assembly can include a torque converter cover having a first axially extending flange, a reaction plate having a second axially extending flange, and a torque converter pump having a third axially extending flange. The first axially extending flange, the second axially extending flange, and the third axially extending flange are connected to each other via a single connection. In one aspect, the single connection comprises a weld.

A hydrodynamic torque converter is provided with a converter housing and a converter torus with a pump impeller, a turbine wheel which is driven hydrodynamically by the pump impeller by a converter fluid. In order to bridge the hydrodynamic drive, a converter lock-up clutch which is connected between the pump impeller and the turbine wheel by pressure loading of the converter fluid is arranged radially between an outer circumference of the converter housing and the converter torus. In order to provide the converter lock-up clutch with an increased transmission capacity, the turbine wheel is assigned at least one friction disc which can be prestressed axially between a pressure-loaded annular piston, which is hooked in an axially movable manner into the converter housing, and a mating friction surface of a converter housing section radially outside the converter torus.

An automatic transmission (1) includes a transmission housing, a hydrodynamic torque converter (5), a first brake, a second brake, an intermediate plate (6) fixedly connected to the transmission housing and with ducts for supplying the hydrodynamic torque converter (5) and the two brakes (A, B) with oil. An oil guide shell (7) is arranged between the hydrodynamic torque converter (5) and the intermediate plate (6). The oil guide shell (7) has an inflow opening (40), which is arranged above a tank, and an oil ejection opening, which is arranged above the inflow opening (40). Oil coming from the two brakes sinks via oil ducts (39.1, 39.2, 39.3) in the transmission housing and the intermediate plate (6) and reaches the hydrodynamic torque converter (5) via the inflow opening (40) in the oil guide shell (7). The hydrodynamic torque converter (5), via rotation, conveys the oil to the elevated oil ejection opening in the oil guide shell (7), from where the oil sinks into the tank (8) via a gap (52) delimited by the oil guide shell (7) and the intermediate plate (6).