A torque converter having a pump, a turbine, and a lockup clutch assembly with a piston and a clutch plate. The lockup clutch assembly is capable of balancing pressure on opposing sides of the lockup clutch assembly to facilitate application of the lockup clutch assembly, in particular during an overrun condition in which the turbine rotates faster than the pump.

A torque converter includes a front cover configured to receive an input torque, and an impeller having an outer shell coupled to the front cover. A clutch is selectively engageable by a piston. A cover compensator is located axially between the front cover and the piston. The cover compensator is configured to reduce deflection of the front cover in the event of high pressures when changing gears in the transmission. The cover compensator has a radially-innermost sealing surface configured to engage and seal with a transmission input shaft. The cover compensator may also has an aperture to fluidly couple fluid chambers located on either axial side of the cover compensator. This can allow fluid to be forced through the clutch to continuously lubricate the clutch.

A control device for a vehicle having: an engine; a torque converter having a lock-up clutch; an engagement element disposed downstream of the torque converter; a drive shaft disposed downstream of the engagement element; and an electric motor disposed downstream of the engagement element, and connected to the drive shaft includes a control portion adapted to: in a case where an electric travel mode in which the lock-up clutch and the engagement element are disengaged is switched to an engine travel mode in which the lock-up clutch is disengaged and the engagement element is engaged, decrease driving torque of the electric motor after engagement of the engagement element; and gradually decrease the driving torque of the electric motor while gradually increasing driving torque of the engine after the driving torque of the electric motor is decreased.

A lockup disengagement control device for an automatic transmission including a torque converter including a lockup clutch, and a lockup control section, the lockup disengagement control device includes: when a brake is operated from a brake OFF to a brake ON during a coast traveling in an engagement state of the lockup clutch, the lockup control section being configured to sense an initial deceleration by the brake ON operation, and to set a lockup release vehicle speed to be higher as an absolute value of the initial deceleration is greater, and when a vehicle speed is sensed to be equal to or smaller than the set lockup release vehicle speed in a middle of a brake deceleration scene by the brake ON operation, the lockup control section being configured to disengage the lockup clutch.

A control device that includes an electronic control unit that is configured to perform lock-up engagement pressure control for acceleration upon acceleration of a vehicle where vehicle speed is increased by increasing a rotational speed of the internal combustion engine, the lock-up engagement pressure control for acceleration controlling engagement pressure of the lock-up clutch, wherein in the lock-up engagement pressure control for acceleration, when an actual rotational speed of the input has reached greater than or equal to a reference rotational speed, the electronic control unit is configured to start engagement pressure increase control, the reference rotational speed being lower than a target rotational speed of the internal combustion engine, and the engagement pressure increase control increasing the engagement pressure of the lock-up clutch.

Presented are clutch-type engine disconnect devices, methods for making/using such disconnect devices, and motor vehicles equipped with such disconnect devices. An engine disconnect device includes a notch plate, which has multiple notches and attaches to a torque converter, and a pocket plate, which has multiple pockets and attaches to an engine's crankshaft. A pawl is movably mounted within each notch; these pawls selectively engage the notches with the pockets. A notch plate insert is nested within each notch, supporting thereon one of the pawls. A selector plate interposed between the pocket and notch plates moves from a first position, to shift the pawls out of engagement with the pockets, and a second position, to move the notch plate inserts within the notches and allow the pawls to engage the notches with the pockets to thereby lock the notch plate to the pocket plate to rotate in unison with each other.

An engine air-fuel ratio control device is configured to be used in a vehicle including a power transmission device configured to transmit power between an output shaft of an engine and an input shaft of a transmission and to execute a lean-burn control that puts an air-fuel ratio of the engine into a lean state. An engine controller executes a fuel injection feedback control such that the air-fuel ratio becomes a lean target value after the power transmission device is released during a deceleration of the vehicle. An engine stall predictor predicts a stall of the engine on a basis of a deceleration indicator that is correlated with a deceleration degree of the vehicle in a state in which the power transmission device is released. A lean-burn control canceler cancels the lean-burn control in a case in which the engine is predicted to stall.

A vehicle lock-up clutch control method is performed in which an output of an engine is transmitted to an automatic transmission via a torque converter having a lock-up clutch. The method includes controlling a transmission torque capacity of the lock-up clutch such that a slip rotation speed of the lock-up clutch becomes zero after the lockup clutch is brought into a non-engaged state immediately after starting an accelerator operation, and when the accelerator operation is carried out during a fuel cut of the engine or in a state in which a road load and a driving force of the vehicle are balanced, and after completion of a downshift when the automatic transmission is downshifted while executing a slip control of the lock-up clutch from the non-engaged state to an engaged state during the accelerator operation.

Provided is a lock-up clutch control device of a vehicle in which a torque converter with a lock-up clutch is disposed between an engine and a transmission. This control device has a coasting capacity learning control section configured to decrease a LU differential pressure command value for the lock-up clutch during accelerator release operation and, when a slip of the lock-up clutch is detected during decrease of the LU differential pressure command value, update the LU differential pressure command value at the time of detection of the slip as a LU differential pressure learning value balanced with a coasting torque. The coasting capacity learning control section is further configured to, when operation of the PTC heater intervenes during coasting capacity learning control, correct the LU differential pressure command value by adding thereto a LU differential pressure correction value that corresponds to an increase of input torque to the lock-up clutch.

A washer having such a thickness t that a value (L3(L1+L2+t)) obtained by subtracting the sum of a first distance L1 in an axial direction between a leading end face of a friction member and a face of a lockup piston, a second distance L2 in the axial direction between a shell-side abutting face of a pump shell and a face of an outside extended portion of an output hub, and the thickness t in the axial direction of the washer, from a third distance L3 in the axial direction between an opposed face of a front cover and a cover-side abutting face of a tubular portion, is in a predetermined range larger than zero, is selected and placed between the lockup piston and the outside extended portion of the output hub.