A vehicle includes an engine, a continuously variable transmission and a torque converter that has a lock-up clutch. The torque converter is arranged between the engine and the continuously variable transmission. The vehicle further includes engine accessories such as an air conditioner compressor and alternator that are driven by the engine. In this vehicle, a slip control is executed that produces a predetermined slip rotational state by controlling a lock-up capacity of the lock-up clutch. During slip control of the lock-up clutch, the engine-equipped vehicle executes cooperative control that suppresses load fluctuations of engine accessories such as the air conditioner compressor and the alternator.

Disclosed are engine flexplates with integrated engine disconnects, methods for making and for using such flexplates, and motor vehicles with an engine flexplate having an integrated engine disconnect device. An engine flexplate assembly is disclosed for operatively coupling an engine to a hydrokinetic torque converter. The flexplate assembly includes a disk-shaped body with a central hub that rigidly attaches on the fore side thereof to the engine output shaft for common rotation therewith. A disconnect device, which is positioned on the aft side of the disk-shaped body, includes concentric inner and outer races. The outer race is rigidly attached to the disk-shaped body for common rotation therewith. The inner race rigidly attaches to the front cover of the TC housing for common rotation therewith. The disconnect device operatively disconnects the engine output shaft from the TC housing front cover when a torque transmitted therebetween reverses direction.

A disk assembly of a torque converter bypass clutch includes a disk defining a circular spring cavity and a plurality of arc springs circumferentially arranged in the cavity with gaps defined between adjacent ones of the arc springs. Each of the springs includes an end cap fitted on an end of the spring. Spring connectors are each disposed in one of the gaps and include an end received within a corresponding one of the end caps.

A hydrodynamic coupling arrangement (1), comprising an impeller (6) linkable to a drive shaft, a turbine (7) linkable to a driven shaft via a hub (11) and able to hydrodynamically coupled with the impeller (6), a lockup clutch (20) able to short-circuited the hydrodynamically coupling between the impeller (6) and the turbine (7), a torsional vibration damper arrangement (13;14,15) located between the lockup clutch (20) and the hub (11), said torsional vibration damper arrangement comprising an input element (16;17,47,24), an output element (17; 25,33,32) and a plurality of elastic elements (22;26) disposed between the input element and the output element, the output element of the torsional vibration damper arrangement forms a part of the hub, wherein the coupling arrangement comprises an absorber device (29) being linked in rotation to the hub, said absorber device comprising a unique resonance frequency.

A dynamic damper device for inhibiting torque fluctuations in a rotor to which a torque is inputted includes a mass body and a magnetic damper mechanism. The mass body is disposed to be rotatable with the rotor and be rotatable relatively to the rotor. The magnetic damper mechanism includes at least a pair of magnets disposed in the rotor and the mass body. The magnetic damper mechanism couples the rotor and the mass body in a rotational direction by a magnetism of the pair of magnets.

A torsional vibration damper of a hydrokinetic torque-coupling device. The torsional vibration damper comprises an input member including a first side plate and a supporting member mounted to the first side plate, and a radially elastic member elastically coupled to the input member. The radially elastic member includes a central part and an elastic blade formed separately from the central part. The central part has a mounting portion. The elastic blade has a connection portion, a free distal end and a curved raceway portion disposed between the connection portion and the distal end. The connection portion of the elastic blade is non-rotatably connected to the mounting portion of the central part. The curved raceway portion of the elastic blade is configured to elastically engage the supporting member and to elastically bend in the radial direction upon rotation of the input member with respect to the radially elastic member.

A torque converter transmits a torque from a drive source to an input shaft of a transmission. The torque converter includes a front cover, an impeller, a turbine and a lock-up device. The torque is inputted to the front cover. The impeller is fixed to the front cover. The turbine is disposed in opposition to the impeller, and is coupled to the input shaft of the transmission. The lock-up device mechanically transmits the torque from the front cover to the turbine. The lock-up device includes a piston, a damper mechanism and a friction generating mechanism. The piston is disposed between the front cover and the turbine so as to be axially movable, and is capable of being engaged by friction with the turbine. The damper mechanism transmits the torque from the front cover to the piston. The friction generating mechanism generates a hysteresis torque on the piston by frictional resistance.

Presented are torque converters (TC) with hydraulic systems for converter feed and clutch control, methods for making/operating such TC assemblies, and vehicles equipped with such TC assemblies. A TC assembly includes a housing that drivingly connects to an electric motor, and an output member that drivingly connects to a multi-gear transmission. Rotatable within the TC housing are a turbine attached to the TC output member and an impeller juxtaposed with the turbine. A lockup clutch disposed inside the TC housing, between the turbine and housing, is operable to lock the housing to the output member. A disconnect clutch disposed inside the housing, between the impeller and housing, is operable to lock the housing to the impeller. A pump is attached to the TC housing and drivingly connected to the motor for feeding fluid into the housing to increase pressure within the TC chamber and activate the lockup and disconnect clutches.

A vehicle includes an engine, a continuously variable transmission and a torque converter that has a lock-up clutch. The torque converter is arranged between the engine and the continuously variable transmission. The vehicle further includes engine accessories such as an air conditioner compressor and alternator that are driven by the engine. In this vehicle, a slip control is executed that produces a predetermined slip rotational state by controlling a lock-up capacity of the lock-up clutch. During slip control of the lock-up clutch, the engine-equipped vehicle executes cooperative control that suppresses load fluctuations of engine accessories such as the air conditioner compressor and the alternator.

A lock-up device for a torque converter includes a clutch part, a piston, a lock-up oil chamber, a cancellation oil chamber and a cancellation hydraulic pressure maintenance circuit. The clutch part is disposed in a power transmission path between a front cover and a transmission-side member. The piston is provided to be movable in an axial direction. The lock-up oil chamber is supplied with hydraulic oil for moving the piston to turn the clutch part into a power transmission activated state. The cancellation oil chamber is provided on the opposite side of the lock-up oil chamber through the piston, and is supplied with the hydraulic oil. The cancellation hydraulic pressure maintenance circuit is provided in an oil passage for leading the hydraulic oil discharged from the cancellation oil chamber to the transmission side, and maintains the cancellation oil chamber at a predetermined hydraulic pressure.