A hydraulic controller that includes a first oil passage that communicates two ports of a plurality of solenoid valves having a plurality of ports with each other; a second oil passage that communicates two ports of a plurality of valves having a plurality of ports with each other; and a third oil passage provided in a third region provided in an overlapping manner between a first region in which the first oil passage is arranged and a second region in which the second oil passage is arranged, the third oil passage being orthogonal to an overlapping direction of the first region and the second region, wherein the third oil passage communicates any one port out of the ports of the solenoid valves and any one port out of the ports of the valves with each other.

A hydraulic system control plate with at least three layers, at least one through-opening being introduced in an inner one of the three layers and being delimited, on at least one part of its surface in the inner layer, by the two other layers is disclosed. A method for producing such a hydraulic system control plate is disclosed.

A hydraulic control device for an automatic transmission, the hydraulic control device including: a first layer having a first parting surface and a plurality of first grooves formed in the first parting surface; and a second layer that has a second parting surface and a plurality of second grooves formed in the second parting surface and facing the plurality of first grooves, and that is stacked on the first layer in a stacking direction with the second parting surface facing the first parting surface of the first layer, so that the plurality of first grooves and the plurality of second grooves form a plurality of first oil passages.

A hydraulic control device for a vehicle drive device that includes a first layer having a first opposing surface, a first groove formed in the first opposing surface, and a first bonding formed on the first opposing surface and surrounding the first groove; and a second layer having a second opposing surface facing the first opposing surface, a second groove facing the first groove and formed in the second opposing surface, and a second bonding facing the first bonding, surrounding the second groove, and bonded to the first bonding, the second opposing surface being placed on, and bonded to, the first opposing surface, so that the first groove and the second groove form a first oil passage.

An electropneumatic valve assembly comprises an electropneumatic pilot stage and a pneumatic power stage which is actuated by the pilot stage. Each pilot valve switches at least two power valves, and the valve assembly has a housing with an electrical signal input, with a compressed-air port, at least one vent port and at least one working outlet. The housing is layered with a pilot stage housing and a power stage housing connected along a substantially planar parting surface. At least one sealing element is between the pilot stage housing and power stage housing surrounding a control pressure region between the pilot stage housing and power stage housing. The control pressure region has two actuation regions for two power valves and has a duct-like connection with a defined flow cross section between the two actuation regions. An outlet of the associated pilot valve opens into the control pressure region.

A valve mounting system includes an upper plate including an upper inlet, an upper outlet, and an upper exhaust. A lower plate includes a lower inlet, a lower outlet, and a lower exhaust that are aligned with the upper inlet, the upper outlet, and the upper exhaust, respectively to define an inlet, an outlet and an exhaust, respectively. A spoon moves about an axis to control a flow of fluid through an opening. The opening is one of the inlet, the outlet and the exhaust.

A valve part that includes a body and a spool housing, wherein the spool housing has: a main body that has a hole that slidably houses a spool, a port formed in a wall surface of the hole of the main body and configured to vary a state of communication between an inside and an outside of the main body in accordance with a position of the spool, a communication hole that extends from the port toward a radially outer side, a first projection in which the communication hole is formed and which is formed so as to project from an outside surface of the main body toward the radially outer side, and a first opening at which the communication hole opens at a distal end of the first projection.

A hydraulic control device that includes a first layer including a first surface, a first groove having a semicircular cross-sectional shape and formed in the first surface, and a first oil passage having a circular cross-sectional shape, communicating with an end of the first groove, extending in a direction orthogonal to the first surface, and open to the first groove; a second layer including a second surface, and a second groove having a semicircular cross-sectional shape and formed in the second surface to face the first groove, the second layer being stacked on the first layer, with the second surface joined to the first surface; and a second oil passage having a circular cross-sectional shape, defined by the first groove in the first surface and the second groove in the second surface, and communicating with the first oil passage.

A hydraulic control device that includes a hole that houses a spool of a valve so as to be movable in an axial direction of the spool, and that has a first port opening in an inner peripheral surface of the hole; a first communication oil passage that extends from the first port toward an outer side in a radial direction of the spool; and a first oil passage that has an opening that communicates with the first communication oil passage.

A Hydraulic Manifold Control Assembly for use in connection with surface blowout preventers and diverter control systems. Said Hydraulic Manifold Control Assembly incorporates design elements and methods which reduce overall envelope dimensions, improving maintenance accessibility, thereby reducing overall installation and manufacturing time and ultimately contributing to a more robust, cost effective end-product. Said design elements and methods include: the use of intrinsically safe I/O modules and components; the employment of a removable valve assembly rack installation method; the use of a removable face plate for identification of flow control valves; the implementation of a digital automatic diverter sequence; the use of integrated manifold assemblies; and the integration of a wide-range function count.