An electronic device is provided. The electronic device includes a first housing, a second housing coupled to the first housing and that performs a sliding operation, a display, of which a size of a visual exposure area is changed in correspondence to the sliding operation of the second housing, a first variable magnetism member disposed at a first location of the first housing, and of which a magnetic force varies depending on a current or a voltage that is supplied thereto, a second variable magnetism member disposed at a second location of the first housing, and of which a magnetic force varies depending on a current or a voltage that is supplied thereto, a magnet member fixed to an inner surface of the second housing, and that moves between the first variable magnetism member and the second variable magnetism member during the sliding operation, and a processor operatively connected.

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 fluid flow control valve comprising an outer casing with an inner valve member displaceable between first and second positions within the casing, the valve member including passages which interconnect different valve inlets and outlets dependent on whether the valve member is in its first or second position, the valve member being made from plastic material so that the diameter of the valve member can be increased without increasing its weight above that of a conventional metal inner valve member. This allows the passages through the inner valve member to be of the same internal diameter as the tubing leading up to and away from the valve. The valve member can be acted upon by a magnetic restoring means which tends to return the valve member towards its first position when displaced therefrom.

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.

The present invention relates to a valve assembly, comprising a valve chamber, accesses to the valve chamber, the accesses including a first access and a second access, and a movable sealing body assembly comprising at least one sealing portion, wherein at least a portion of the sealing body assembly is magnetic, and wherein at least a portion of the sealing body assembly comprising the at least one sealing portion is located within the valve chamber. Further, the valve assembly comprises at least one sealing surface, wherein each of the at least one sealing surface is configured to complement one of the at least one sealing portion, and wherein each sealing surface comprises an orifice fluidly connected to one of the accesses. The valve assembly further comprises a force unit configured to exert a magnetic force on the magnetic portion of the movable sealing body assembly and is configured to assume at least two configurations, wherein in a first configuration, the first access is sealed, and wherein in a second configuration, the first access is fluidly connected to the second access. Further, the present invention relates to a pump system, as well as a use and manufacturing method of a valve assembly according got the present invention.

Apparatus and associated methods relate to a valve having an actuator configured to translate a mass in a plane and a valve element located out of the first plane and configured to translate along a first linear axis. In an illustrative example, at least one of the mass and the valve element may include a magnetic source providing a persistent magnetic field and the other may include a non-magnetized, magnetically permeable mass. Reluctance-induced forces may, for example, translate the valve element towards the mass along the first linear axis when the mass is brought into register with a second linear axis. The first linear axis and the second linear axis may, for example, be colinear. Various embodiments may advantageously provide a valve requiring low energy input for operation.

An overfill valve associated with a drop tube segment fluidly connected to a fluid reservoir is described. The overfill valve includes a valve body positioned within the drop tube segment and a non-contact valve actuator positioned exterior to the drop tube segment and operable to actuate the valve body from an open position to a closed position without requiring any physical penetration through the wall of the drop tube segment. The non-contact valve actuator has a first position in which the non-contact valve actuator does not actuate the valve body from the open position to the closed position in a second position, achieved when the liquid reservoir reaches a predetermined level approaching the capacity of the liquid reservoir, the non-contact valve actuator actuating the valve body from the open position to the closed position when the non-contact valve actuator obtains the second position.

Lethal and Severe Service Magnetically Actuated Valves and Retrofit Kits is disclosed. My invention encapsulates a magnetically permeable, but ordinarily non-magnetic piece of metal such as iron, steel, or ferritic stainless inside the exotic alloys and compatible materials such as Monel, Inconel, Hastelloy, Alloy 20, PTFE, TFM or PTA that are necessary to construct modern severe and lethal service valves.

Examples disclosed herein relate to conduits, devices, systems and methods, which may include a dispensing device including a valve configured to interact with an inlet stream, the inlet stream having a first pressure, the valve having an outlet area with an outlet stream, the outlet stream having a second pressure; and a solenoid configured to interact with the outlet stream.

Examples disclosed herein relate to conduits, devices, systems and methods, which may include a hollow element including an inner surface and an outer surface which allows for a passage of one or more of one or more fluid elements and one or more gaseous elements, a constraining element with one or more openings and one or more non-open elements, one or more blocking elements configured to stop the passage of the at least one of the one or more fluid elements and the one or more gaseous elements when the one or more blocking elements are in a first position relative to the one or more openings, and a movement device configured to move the one or more blocking elements to a second position relative to the one or more openings which allows for the passage of the one or more fluid elements and the one gaseous elements through the one or more openings in the constraining element.