An emergency shut-off device comprises an activation means configured to generate an activation force in response to detecting a seismic event, and a magnetic driver having a hollow guide tube with two magnets affixed at a selected position on opposite sides along a length of the guide tube with like poles facing each other and a drive piston movable inside the guide tube. The driver piston is coupled to a third magnet and has a first end for receiving an activation force to move the third magnet crossing a magnetic repulse shift line formed by the two magnets, and a second end for applying the drive force to an output system to effectuate a. shut-off of a fluid line.

A flow regulating switch valve includes a valve core that includes a switch assembly configured to drive a diaphragm assembly to open or close a water outlet, and also includes a flow regulating assembly that comprises a rotating ring, a sliding block, and a magnet. A control key is configured to control the switch assembly. The rotating ring is connected to the control key and includes an inclined plane that transitions from high to low and is configured to drive the sliding block to slide up and down such that the sliding block drives the magnet to move up and down. The magnet is configured to control the diaphragm assembly to regulate a size of the water outlet.

A fluidic valve device intended to be arranged in a fluidic circuit, the device notably including a first switching assembly including a first compartment defining a first internal space and a first permanent magnet arranged with the freedom to slide in the first internal space, a second switching assembly including a second compartment defining a second internal space and a second permanent magnet arranged with the freedom to slide in the second internal space, the first permanent magnet and the second permanent magnet being arranged relative to one another in such a way as to be in a first state of magnetic interaction, making it possible to obtain a first stable mechanical configuration or in a second state of magnetic interaction, it possible to obtain a second stable mechanical configuration.

Various devices and techniques related to magnetically-actuated valves are generally described. In some examples, valves may include a bonnet defining an enclosure. In various examples, a movable valve member may be disposed in the enclosure. A valve stem may be disposed in the enclosure and may be operatively coupled to the movable valve member. A first internal ferromagnetic actuation member and a second internal ferromagnetic actuation member may be coupled to the valve stem. The first internal ferromagnetic actuation member and the second internal ferromagnetic actuation member may be disposed in a spaced relationship along the valve stem. In various examples, the valves may include an external actuator slidably engaged to an exterior surface of the valve bonnet. The external actuator may comprise a first magnet magnetically coupled to the first internal ferromagnetic actuation member and a second magnet magnetically coupled to the second internal ferromagnetic actuation member.

A magnetically damped check valve having a non-magnetic metal sleeve and a spring-biased poppet disposed within the check valve. The spring-biased poppet is operably supported by the sleeve. A poppet guide is attached to the sleeve. The poppet includes a shaft that is slidably attached to the poppet guide. A portion of the shaft extends into the sleeve. At least one magnet is attached to the portion of the shaft that extends into the sleeve. The magnet therefore moves with the shaft as the poppet moves in response to changes in differential pressure across the check valve. The magnet produces a magnetic field. As the magnet moves within the sleeve, the magnetic field changes thereby inducing an electrical current in the sleeve which produces another magnetic field that opposes the magnetic field of the magnet thereby damping the movement of the magnet and hence, damping the movement of the poppet.

Provided is a retrievable choke insert. The retrievable choke insert, in one aspect, includes an outer housing including a central bore extending axially through the outer housing, an open end, a closed end, and one or more outer housing openings extending through an outer housing sidewall thickness, and a bore flow management actuator disposed in the central bore, the bore flow management actuator having one or more bore flow management openings extending through a bore flow management actuator sidewall thickness, the bore flow management actuator operable to convey subsurface production fluids there through. The retrievable choke insert, in accordance with this aspect, further includes one or more choke insert magnets coupled to the bore flow management actuator, the one or more choke insert magnets configured to magnetically couple with one or more landing nipple magnets of a choke landing nipple to slide the bore flow management actuator and move the one or more bore flow management openings relative to the one or more outer housing openings to control an amount of the subsurface production fluid entering the bore flow management actuator.

Technologies are described herein or a solenoid valve having an encapsulated magnetic piston. In some examples, the piston comprises a ferromagnetic core encapsulated by a low reactive outer shell. In some examples, the low reactive outer shell is selected for use within a system at a vacuum. In further examples, the valve is used in a cooling system that uses an adsorbent.

A magnetic actuator including a housing having an inside surface, an outside surface and a body between the inside and outside surfaces; a mobile component movable relative to the housing; a magnet piston chamber disposed within the body; a magnet piston disposed in the magnet piston chamber and disposed to effect movement of the mobile component relative to the housing, the magnet piston having a magnetic field; a prime piston chamber disposed within the body in spaced relationship to the magnet piston chamber and segregated from the magnet piston chamber by material of the body, there being no fluid path between the magnet piston chamber and the prime piston chamber; a prime piston disposed in the prime piston chamber, the prime piston having a magnetic field; wherein the magnet piston is responsive to movement of the prime piston by magnetic interaction between the magnet piston and the prime piston.

A flow regulating switch valve includes a valve core that includes a switch assembly configured to drive a diaphragm assembly to open or close a water outlet, and also includes a flow regulating assembly that comprises a rotating ring, a sliding block, and a magnet. A control key is configured to control the switch assembly. The rotating ring is connected to the control key and includes an inclined plane that transitions from high to low and is configured to drive the sliding block to slide up and down such that the sliding block drives the magnet to move up and down. The magnet is configured to control the diaphragm assembly to regulate a size of the water outlet.

A method and apparatus for metering fluids, in particular liquid fluids, includes at least one fluid being guided out of at least one fluid reservoir through a closeable valve device in a discharge direction, at least one valve opening in the valve device being closed or opened by a valve closing member in order for the fluid to flow or be prevented from flowing through the valve opening, the opening and closing movement being performed magnetically by moving the valve closing member, which is arranged and moved in the fluid reservoir on an upstream side of the valve opening.