Abstract: A torque converter includes an impeller, a turbine, and a variable-pitch stator adjacent the turbine. The stator includes a hub and blades circumferentially arranged around the hub and pivotal between open and closed positions. The stator further includes an annular carrier connected to the blades and configured to rotate relative to the hub in response to pivoting of the blades, and a thrust disk engageable with the carrier to inhibit rotation of the carrier relative to the hub to maintain positions of the blades.

Abstract: The invention relates to a hydrokinetic torque coupling device for a motor vehicle, comprising a torque input element (11) intended to be coupled to a crankshaft (1), an impeller wheel (3) rotationally coupled to the torque input element (11) and able to hydrokinetically drive a turbine wheel (4) through a reactor (5), a torque output element (8) intended to be coupled to a transmission input shaft (2), clutch means (10) adapted to rotationally couple the torque input element (11) and the torque output element (8) in an engaged position, through damping means (22, 26), and adapted to rotationally uncouple the torque input element (11) and the torque output element (8) in a disengaged position.

Abstract: A controllable hydrodynamic torque converter is provided for use within a vehicle having a detectable throttle level, the torque converter comprising a first stator having a first outlet angle and a second stator having a higher second outlet angle. The second stator is selectively engageable with the first stator using a hydraulic clutch to thereby vary the torque converter K-factor during idle and high-throttle conditions, and is permitted to freewheel during low or part throttle conditions. The first outlet angle is at least five degrees lower than the second outlet angle. A vehicle is also provided including an engine having an engine torque and a detectable throttle level, a transmission, a torque converter operable to transmit the engine torque to the transmission and having a stator assembly with two stators, a selectively controllable clutch, and a controller configured to selectively actuate the clutch to vary the K-factor depending on the throttle level.

Abstract: A drive arrangement for driving, or for being driven by, a fluid is disclosed. The drive arrangement comprises a rotatable member (40) for receiving the fluid, and having mounted thereon a plurality of drive members (56). The drive members (56) are movable between a drive position, in which the drive members can drive, or be driven by, the fluid, and a non-drive position in which the drive members (56) are substantially prevented from driving or being driven by a fluid received in the rotatable member (40).

Abstract: A hydrodynamic torque converter has a converter housing drivable in rotation by an engine, with an impeller. A turbine non-rotatably connected to an output shaft is hydrodynamically coupled to the impeller by way of a stator through an oil circuit. The turbine is axially slidably supported on the shaft. A friction surface on the turbine upon axial displacement of the turbine comes into frictional contact with a counterpart friction surface on the converter housing, thereby producing a lockup clutch effect. The turbine is also connected by way of springs to a coupling element arranged non-rotatably on the shaft. In an alternative configuration the turbine is arranged non-rotatably on the shaft and the lockup clutch action is by way of friction surfaces on a coupling element and on the converter housing. A torsion damper can be provided between the coupling element and the turbine.

Abstract: A three element fluid torque converter has a variable pitch stator. The stator blades have two principal orientations, closed and open. The blades are biased toward the closed position by a spring loaded annular piston. In the closed position, the blades block approximately 75% to 90% of the annular area between a stator core and a stator shell. An inlet angle for the stator blades is between 30 degrees and 70 degrees in the closed position. This combination reduces creep torque without any significant increase in driveline noise and vibration when the engine is idling. As engine speed and torque are increased, the blades overcome the spring bias to rotate to the open position thereby increasing the torque transmitted to effectively propel the vehicle.

Abstract: A three element fluid torque converter has a variable pitch stator. The stator blades have two principal orientations, closed and open. The blades are biased toward the closed position by a spring loaded annular piston. In the closed position, the blades block approximately 75% to 90% of the annular area between a stator core and a stator shell. An inlet angle for the stator blades is between 30 degrees and 70 degrees in the closed position. This combination reduces creep torque without any significant increase in driveline noise and vibration when the engine is idling. As engine speed and torque are increased, the blades overcome the spring bias to rotate to the open position thereby increasing the torque transmitted to effectively propel the vehicle.

Abstract: A hydrodynamic torque converter includes a pump wheel, a turbine wheel, and a stator wheel having a variable entrance between the blade rows upon at least one of these wheels, preferably on the stator wheel. The opening between the blades is adjustable automatically by the torque applied by the circulating fluid against the action of a compression spring. The blades on the wheel whose entrance is adjustable includes at least two annular members divided along a plane perpendicular to the axis of the wheel. The annular members are rotatable relative to one another approximately one-half blade pitch. The annular member becomes located in the inlet region of the blade row, is rotatable by the torque of the circulating flow only in the region of the installed condition against the force of the spring to a position that reduces the inlet cross section of the blade row.

Abstract: A stator construction for hydrodynamic torque converters with the stator construction including a plurality of stator blades fixedly arranged on a supporting hub. A supporting hub is adapted to be non-rotatably fixed in a reactionary direction of rotation of the torque converter. At least one additional stator blade is arranged between two neighboring fixed stator blades and guided movably on the supporting hub along a path of revolution concentric to the wheel axis between a central partial load position and a clutch position in the proximity of one of the fixed stator blades lying at the rear with respect to the reactionary direction of rotation.

Abstract: Torque converter with a stator whose blades are selectively set at open and closed position to tailor converter operation for optimized vehicle performance and fuel economy. Turbine discharge pressure is routed to impeller side of stator control piston to move stator blades to low angle position for improved engine economy during vehicle coast down operation. Low angle stator is also used for economical anti-creep idle and for higher stall speeds and acceleration when needed. For economical cruising and other operation, the stator blades are set at their high angle or open position.

Abstract: Two closely juxtaposed coaxial disks, one fixed and the other rotatable, are formed with confronting annular grooves partitioned by slanting vanes into coextensive pockets designed to decelerate the rotation upon the admission of hydraulic fluid into a chamber formed around the rotatable disk by the fixed disk and a brake housing secured thereto. The fixed disk has a limitedly rotatable annular insert which carries at least a part of each stationary vane thereof and can be moved between a working position in which its pockets are mutually isolated and an idling position in which these pockets intercommunicate either directly or through an external space. The annular insert may be urged into the idling position by a set of springs whose force is overcome, upon the production of hydraulic fluid, by the reaction torque exerted upon the stationary vanes.

Abstract: A hydrodynamic torque converter for vehicles, particularly for passenger motor vehicles, with at least one pump wheel, one turbine wheel and one guide wheel supported on a free-wheeling device, in which the guide blades are automatically adjustable, when the guide wheel rotates, in dependence on the centrifugal force in the sense of a cascade opening with an increasing rotational speed.

Abstract: A hydrodynamic torque converter, especially for motor vehicles, which is equipped with a pump wheel, a turbine wheel and a guide wheel and with adjustable cascade at least at one of these wheels, preferably at the guide wheel; each blade of such wheel is thereby rotatably supported and is automatically adjustable against a spring force by the torque exerted by the circulating flow of the hydraulic medium.