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.

A hydraulic control unit (4) for an automatic transmission of a motor vehicle includes a volumetric flow rate control valve (49). The hydraulic control unit (4) is configured for delivering hydraulic fluid to an inlet (59) of the volumetric flow rate control valve (49). An outlet (31, 71) of the volumetric flow rate control valve (18, 49) is connected to a torque converter torus of the automatic transmission. In addition, the volumetric flow rate control valve (59) is configured for directing the hydraulic fluid across an orifice (66), so that the pressure of the hydraulic fluid is reduced and a constant flow of hydraulic fluid is feedable to a torque converter torus.

An automatic transmission according to one aspect of the present invention includes: a transmission mechanism including a rotational element; a valve body configured to control the transmission mechanism; an electronic control unit configured to perform electronic control of the valve body; and a transmission casing in which the transmission mechanism, the valve body, and the electronic control unit are arranged. The electronic control unit is formed such that an inner peripheral surface of the electronic control unit extends in a circumferential direction along an outer peripheral surface of the transmission mechanism.

An apparatus for fixing a sticking damper clutch may include: a transmission controller configured to determine whether a damper clutch sticks, using engine controller information received from an engine controller and damper clutch status information of the damper clutch; and a hydraulic pressure controller configured to fix the sticking damper clutch according to the determination result of the transmission controller.

Provided is a hydraulic pressure control device. A hydraulic pressure control device includes a solenoid valve configured to supply hydraulic pressure to switch between an engaged state and a released state of a lock-up clutch, and a transmission control device configured to control the solenoid valve. The solenoid valve supplies hydraulic pressure to switch between a parking locked state and a parking released state of a parking lock mechanism, in addition to switching of the lock-up clutch.

A torque converter controller includes a pressure regulator connected to a pipe that delivers a fluid circulating through a pump impeller and a turbine runner of a torque converter, the pressure regulator changing a pressure applied to the fluid based on a plurality of states of a vehicle where the torque converter controller is mounted, the plurality of states including a starting state where the vehicle is starting and at least one of a stopped state where the vehicle is stopped and a cruising state where the vehicle is cruising.

A torque converter controller includes a pressure regulator connected to a pipe that delivers a fluid circulating through a pump impeller and a turbine runner of a torque converter, the pressure regulator changing a pressure applied to the fluid based on a plurality of states of a vehicle where the torque converter controller is mounted, the plurality of states including a starting state where the vehicle is starting and at least one of a stopped state where the vehicle is stopped and a cruising state where the vehicle is cruising.

A powertrain for a vehicle includes a combustion engine and a drivetrain having a coupling with a first state of operation in which the input of the coupling is locked to the output of the coupling, and a second state of operation in which the input of the coupling is not locked to the output of the coupling for allowing slippage. The drivetrain also has a final drive configured for supplying torque to a drive wheel from the coupling, wherein the final drive is coupled to the coupling at a fixed gear ratio. The powertrain further includes one or more electric motors configured to supply torque to the drivetrain one or both of the input side and the output side of the coupling.

A control device that controls a vehicle transmission device including an input drivingly coupled to an internal combustion engine, an output drivingly coupled to wheels, a shift input drivingly coupled to the input via a fluid coupling having a lock-up clutch, and a speed change mechanism disposed on a power transmission path connecting the shift input and the output, wherein the speed change mechanism is capable of performing both continuously variable shifting that continuously changes a speed ratio, and stepped shifting that changes a speed ratio in a stepwise manner, the control device including: an electronic control unit that is configured to perform, when the stepped shifting is performed, rotation maintained engagement control that controls an engagement pressure of the lock-up clutch such that a rotational speed of the input follows a predetermined target rotational speed, regardless of a change in rotational speed of the shift input.

A transmission comprising a motor, a torque converter cover including an outside surface and an inside surface, a clutch configured to contact a portion of the inside surface of the torque converter cover, and a sprayer including a first end and a second end and configured to emit fluid on an outside surface of the torque converter is disclosed.