A valve assembly for use in an actuation assembly, with the actuation assembly including an actuation housing, includes a valve support adapted to be coupled to the actuation housing. The valve support has a body portion defining a plurality of solenoid bores. The valve assembly also includes a plurality of solenoids with each one of the plurality of solenoids disposed within a corresponding one of the plurality of solenoid bores and directly mounted to the valve support for controlling a flow of fluid. The valve assembly further includes an electrical power distribution device at least partially coupled to the valve support and connected to each of the plurality of solenoids. The valve assembly also includes a tray coupled to the body portion of the valve support to support a portion of the electrical power distribution device.

The present invention improves fuel efficiency of a vehicle and decreases a noise, by decreasing a margin value of a hydraulic pressure supplied to a hydraulic pressure control target and decreasing the hydraulic pressure supplied to the hydraulic pressure control target, when the vehicle is driven automatically. In a hydraulic pressure control device 1 for a vehicle that controls a line pressure or an operation pressure (hydraulic pressure) supplied to a clutch 40 or a transmission 41 (hydraulic pressure control target) provided in the vehicle, the hydraulic pressure control device 1 includes an operation pressure control unit 10 (hydraulic pressure setting device) that sets margin values a1 and a2 of the operation pressure (line pressure) supplied to hydraulic circuits 31 and 31 of the clutch 40 or the transmission 41, on the basis of a predetermined driving plan (refer to FIG. 2) in the case of driving the vehicle automatically.

The disclosure provides a pressure control device that improves the workability in assembling a body and a filter unit. The pressure control device includes a body and a filter unit. The body has a flow path that includes a groove and a widened part. The widened part is connected to the groove, extends to a bottom of the groove, and has a width larger than a width of the groove. The filter unit is housed along a depth direction of the widened part to capture foreign matter mixed in a fluid that passes through the flow path. The filter unit includes a cylindrical frame and a flat plate-shaped filter member, wherein the frame includes a through hole part that penetrates in a direction orthogonal to a central axis, and the filter member is disposed to block the through hole part.

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.

A hydraulic control unit (10) for a transmission (36) of a motor vehicle drive train may include a housing top section (12), a first valve housing (14) having a first valve (60), and a second valve housing (16) having a second valve (62). The first valve (60) is aligned along a first direction (30) and the second valve (62) is aligned along a second direction (32), wherein the first direction (30) differs from the second direction (32).

Transmission control devices may have two control boxes, and a planar transmission control plate disposed between the two control boxes. The transmission control plate seals the intermediate space between the two control boxes or the channel portions and borings thereof in the form of a flat gasket. The plate also makes available throughflow-openings between channels or borings in the control boxes for a fluid, the fluid in the channels controlling the function of a transmission. The sealing function is achieved by embossed beads and/or partial coatings.

In a hydraulic control device, a state determination unit of a control unit determines whether a second pump is in a boosting operation or in a transition state. If the state determination unit has determined that the second pump is in the boosting operation or in the transition state, a valve-opening detection unit determines whether a check valve is opened. If the valve-opening detection unit has determined that the check valve is opened, a controller stops the second pump or decreases the rotation number of the second pump.

A switch valve assembly controls first and second fluid flows in a hydraulic circuit defined by a valve body and a separator plate of a valve body assembly of a hydraulic control module. The valve body defines a fluid exit. The valve body is further defined as first and second body housings. The switch valve assembly includes a piston moveable between a first position for allowing the first fluid flow to flow and a second position for allowing the first and second fluid flows to flow into the fluid exit, and a biasing member coupled to the piston and biasing the piston from the second position toward the first position. The piston presents a regulating surface oriented with respect to the first axis. The first fluid flow fluidly engages the regulating surface in a manner that biases the piston into the first position in conjunction with the biasing member.

In a hydraulic control device, a hydraulic sensor is provided on an intake side of a second pump where first oil is taken in and a line pressure sensor is provided on a discharging side of the second pump where the second oil is discharged. A control unit controls driving of the second pump by controlling a motor on the basis of an output pressure detected by the output pressure sensor or a line pressure detected by the line pressure sensor.

A hydraulic mechanical transmission includes a first hydraulic unit having a first shaft and a second hydraulic unit having a second shaft. The second hydraulic unit is connected in hydraulic fluid communication with the first hydraulic unit by high and low pressure lines. At least one of the first and second hydraulic units has variable displacement. A mechanical torque transfer arrangement transfers torque between the first shaft and the rotatable component of the second hydraulic unit. One of the first and second hydraulic units operates as a hydraulic pump and the other of the first and second hydraulic units operates as a hydraulic motor.