A valve, in particular a diaphragm valve, is proposed, in which a transponder is arranged in a transponder frame. An outer opening of the transponder frame is closed with a sealing compound. The transponder frame is connected to an outer surface of a component of the valve.

Variable flow resistance systems can be used to regulate fluid flow in various applications, particularly within a subterranean formation. A variable flow resistance system can comprise a chamber configured to induce rotational motion of a fluid flowing therethrough, a fluid inlet coupled to the chamber, and a fluid outlet coupled to the chamber that allows the fluid to exit through at least a sidewall of the chamber. If desired, a plurality of the chambers can be connected in series fluid flow communication with one another.

A fluid housing in the form of a valve or sensor housing has a plastically shaped outer housing body made of metal with a fluid inlet and a fluid outlet, which have protruding tubular ports. On the outer circumference of the ports clamping rings are seated, which are welded to the associated port without the port being welded through.

A diaphragm valve including an axially driven valve spindle provides a pressure member, which allows to directly couple the diaphragm to the valve spindle. The same pressure member may always be used for coupling, irrespectively of the type of fastener, which is integrated in the diaphragm.

A switching membrane for a pressure control valve has a plate-shaped flat body with a central area and a bending area surrounding the central area. The central area is provided with a closure area. For switching the switching membrane, the central area can be moved back and forth by a bending movement of the bending area in a direction transverse to an extension of the central area. At least the bending area is made of fluorocarbon rubber. A pressure control valve, especially for crankcase ventilation, is provided with a valve housing that has a housing cover and further is provided with a valve seat. A switching membrane as described above is disposed in the valve housing and switches at pressure differences of at most 500 mbar to release or shut off a flow of fluid at the valve seat.

A fluid control valve is provided, comprising a valve body configured with an inlet port extending into an inlet chamber, and an outlet port extending from an outlet chamber. The inlet and outlet chambers are partitioned by a sealing bridge. A control chamber accommodates a flexible sealing diaphragm deformable between a sealing position in which it sealingly bears over the sealing bridge and seals a fluid flow path extending between the inlet and outlet chambers, and an open position in which fluid flow along the flow path is enabled. An inlet path along the fluid flow path is longer than an outlet path therealong. An inlet radii of the sealing diaphragm is longer than an outlet radii of the sealing diaphragm.

A fluid control device includes: a fluid block having a first channel extending from an inlet to an outlet and a second channel above and in communication with the first channel, the fluid block including a bending cover configured to cover the second channel to thereby block fluid from flowing from the inlet to the outlet of the first channel; and a valve having a hollow portion, a first hole connected to the hollow portion, a piston in the hollow portion, and an elastic body configured to elastically support the piston, the valve configured to pressurize the bending cover, wherein the fluid block includes a guide plate below the bending cover, wherein the fluid block includes a first passage through which control gas flows, and wherein the valve includes a second passage connecting the first passage to the hollow portion.

Systems and methods disclosed herein related to an apparatus including a fluid flow plate and a microfluidic valve assembly. The fluid flow plate includes a plurality of polymer layers that define a fluid flow passage through the microfluidic valve assembly. The microfluidic valve assembly includes a valve seat, a flexible membrane, a valve cavity, a valve head, and an actuator. The actuator is configured to selectively control pressure applied by the valve head to the flexible membrane, such that in a first actuator state the valve head depresses the flexible membrane into the valve cavity and into contact with the valve seat, thereby preventing fluid flow through the valve assembly, and in a second state, the valve head and the flexible membrane are retracted substantially out of the valve cavity allowing fluid to flow through the valve assembly. In various implementations, the valve seat and/or the flexible membrane include an elastomer layer.

A method of controlling a valve plunger of a valve makes provision that, prior to the operation, the valve individually runs through a set-up procedure on the basis of a detected closed position, in which set-up procedure the valve plunger exerts an additional force in the direction of the valve seat beyond a detected closed position. The corresponding valve is equipped with an integrated valve controller which performs a corresponding set-up procedure automatically prior to the operation.

A valve module with a wireless energy-transfer unit is described, which comprises at least one energy-transmitting unit and at least one energy-receiving unit. The energy-receiving unit is arranged on a valve piston wherein, on a valve spindle wherein, on a valve actuator housing wherein, a valve housing or on a valve-closing element.