A system includes a mounting panel having diffusion-bonded metal plates that form a reservoir to contain a process fluid, multiple channels through which to flow the process fluid, and vias through which to flow the process fluid to and from process fluid control components attached to the mounting panel. At least a pair of the multiple channels are connected with the reservoir. A temperature sensor is attached to a top of the mounting panel, the temperature sensor in fluid communication with the reservoir through one of the vias. A set of inlet ports are attached to the mounting panel, the set of inlet ports to receive the process fluid. At least one outlet port is attached to the mounting panel, the at least one outlet port to output the process fluid from the mounting panel.

An annulus pressure release system includes a gas metering valve assembly having a fluid pathway. The gas metering valve assembly includes a pressure sensor configured to be fluidly coupled to an annulus and to output a sensor signal indicative of a fluid pressure within the annulus. The gas metering valve assembly also includes an electronically actuated adjustable control valve disposed along the fluid pathway and a electronically actuated two-position valve disposed along the fluid pathway. Furthermore, the gas metering valve assembly includes a flow controller. The flow controller, in response to determining the fluid pressure exceeds a threshold pressure, is configured to output a first control signal to the electronically actuated two-position valve indicative of instructions to open the electronically actuated two-position valve, and to output a second control signal to the electronically actuated adjustable control valve indicative of instructions to adjust a flow of fluid through the fluid pathway.

An integrated multi-port solenoid valve, comprising: at least two sub-solenoid valves (20), each sub-solenoid valve (20) comprising at least two connection ports; and at least one first joint (30), each first joint (30) comprising at least two connection joints, wherein at least one first connection port in the at least two connection ports is used for connection to other sub-solenoid valves (20), each first joint (30) is used for connecting any two sub-solenoid valves (20), and each connector joint is connected to the first connection port. The present integrated multi-port solenoid valve integrates multiple sub-solenoid valves, and any connection ports of each sub-solenoid valve is communicated with each other to meet control requirements of a variety of working conditions. The integrated multi-port solenoid valve has lightweight design, few components, a light weight, and low cost of use. Also provided are a vehicle thermal management system and a vehicle.

Passage forming blocks of a first pilot valve and a second pilot valve each include a supply passage, which opens in a first surface and a second surface and is connected to a valve chamber, a first output passage, which opens in the first surface and are connected to the valve chamber, and a second output passage, which opens in the first surface. Further, the passage forming blocks each include an output passage connecting recess. The output passage connecting recess is provided in a section of the second surface that overlaps with an opening region of the first output passage, which opens in the first surface, and is connected to the second output passage. The first output passage of the first pilot valve is connected to the second output passage of the second pilot valve via the output passage connecting recess of the second pilot valve.

A valve block may be assembled, in a controlled environment, a valve block to be modular and purpose built for a specific application. The specific application may be an operation to be performed at a well site. The modular purpose built valve block may be function tested, in the controlled environment. Additionally, the modular purpose built valve block may be pre-packaged, in the controlled environment, to have a digital system to operate and automate the modular purpose built valve block. Further, the modular pre-packaged purpose built valve block may be deployed to the well site, and the modular pre-packaged purpose built valve block may be fluidly coupled to a wellhead. The modular pre-packaged purpose built valve block may be operated to perform the operation at the well site.

A housing assembly for a manifold includes a first housing with an inlet and a plurality of outlets, a second housing, and a valve retainer engaged with the first and second housings. The valve retainer includes a retention plate defined between first and second surfaces, a plurality of slot walls extending from the first surface, and a protruding edge that extends from a flanged lip and surrounds the plurality of slot walls. The retention plate defines a plurality of slots corresponding to the plurality of slot walls. The first housing may define a groove that receives the protruding edge, and the second housing may include a rim that engages the flanged lip of the valve retainer. Valve housings including first and second mating structures separated by wall segments may be positioned in outlets of the first housing and corresponding slots of the valve retainer.

Improvement of maintainability in a device on which a solenoid valve is mounted. An aspect of an electromagnetic valve module includes a cover detachably attached to an attachment portion of a housing as a part of the housing enclosing a fluid control device that controls fluid by a detachably attached electromagnetic valve, and an electromagnetic valve attached to the cover and mounted on the fluid control device as the cover is attached to the attachment portion.

An electromagnetic valve manifold includes valve assemblies arranged in a single direction, each valve assembly including electromagnetic valves arranged in the single direction, a slave station disposed at one of ends of the electromagnetic valve manifold in the single direction, and a valve driving unit disposed in correspondence with each of the valve assemblies. The slave station includes a slave station output port that sends a control signal and valve driving unit power to the valve driving units. The valve driving units each include an electromagnetic valve power input port that receives electromagnetic valve power from an external device and a circuit board configured to control driving of the electromagnetic valves of a corresponding one of the valve assemblies using the control signal and send the electromagnetic valve power to the electromagnetic valves.

A fluid control apparatus includes a block elongated in a longitudinal direction and having a predetermined width, an internal flow channel formed inside the block so as to extend in the longitudinal direction, a first control valve mounted on the block, a second control valve mounted on the block at a position downstream of the first control valve. In the fluid control apparatus, the internal flow channel has a first outflow channel connected to a first outlet of the first control valve through which a fluid flows out thereof and also has a second inflow channel connected to a second inlet of the second control valve through which the fluid flows thereinto. In addition, the first outflow channel and the second inflow channel are disposed so as to overlap each other at one point as viewed in the width direction through the block.

In some examples, a gas mixer comprises a body and an orbital array of gas inlets for receiving one or more constituents of a mixed gas. A mixed gas outlet emits a mixed gas from the body and is disposed at a center of the orbital array of gas inlets. A central gas mixing point, separate from the mixed gas outlet, comprises an internal volume disposed within the body and is surrounded by the orbital array of gas inlet. The internal volume is in fluid communication with the orbital array of gas inlets via a corresponding array of gas pathways extending from the internal volume to each of the gas inlets. Each gas path length of the respective gas pathways is the same. Control circuitry is configured to control gas flow rate within each of the gas pathways individually.