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Various devices and techniques related to magnetically-actuated valves are generally described. In some examples, valves may include a valve body with a cavity. Valves may include a stem at least partially disposed in the cavity. Valves may include a valve member coupled to the stem. Valves may incl

Various devices and techniques related to magnetically-actuated valves are generally described. In some examples, valves may include a valve body with a cavity. Valves may include a stem at least partially disposed in the cavity. Valves may include a valve member coupled to the stem. Valves may include a ferromagnetic actuation member disposed in the cavity. The ferromagnetic actuation member may be operatively coupled to the stem such that movement of the ferromagnetic actuation member actuates movement of the valve member between an open position and the closed position. Valves may include an actuator exterior to the valve body. The actuator may include a first magnetic pole section and a second magnetic pole section. A magnetic flux may flow from the first magnetic pole section through the ferromagnetic actuation member to the second magnetic pole section in a magnetic flux path through the interior portion of the valves.

대표청구항 ▼

1. A valve assembly, comprising: a valve body defining an enclosure;a movable valve member disposed in the enclosure;an internal actuation member having a ferromagnetic portion comprising an impermanent magnet, the internal actuation member operatively coupled to the movable valve member;an external

1. A valve assembly, comprising: a valve body defining an enclosure;a movable valve member disposed in the enclosure;an internal actuation member having a ferromagnetic portion comprising an impermanent magnet, the internal actuation member operatively coupled to the movable valve member;an external actuator attached to an exterior of the valve body, the external actuator comprising: a first magnetic pole section adjacent to the valve body;a second magnetic pole section adjacent to the valve body, whereinwhen the external actuator is in a first rotational position relative to the internal actuation member there is at least a first magnetic reluctance between the first magnetic pole section, the second magnetic pole section, and the internal actuation member, and when the external actuator is in a second rotational position relative to the internal actuation member there is at least a second magnetic reluctance between the first magnetic pole section, the second magnetic pole section, and the internal actuation member, wherein the second magnetic reluctance is lower than the first magnetic reluctance such that when the external actuator is in the second rotational position, magnetic flux paths from the first magnetic pole section, through the ferromagnetic portion, to the second magnetic pole section have a magnetic field strength sufficient to cause rotation of the internal actuation member when the external actuator is rotated; and an impermanently magnetic ferromagnetic material completing a return flow path for magnetic flux between the first magnetic pole section and the second magnetic pole section. 2. The valve assembly of claim 1, wherein the internal actuation member comprises an elongate member having a first end aligned with the first magnetic pole section and a second end aligned with the second magnetic pole section. 3. The valve assembly of claim 1, wherein magnetic flux of the magnetic flux paths is effective to orient the internal actuation member in the second rotational position. 4. The valve assembly of claim 1, wherein at least a portion of the valve body comprises a cylindrical portion containing the internal actuation member; the external actuator further comprises an annular base portion concentric with the cylindrical portion of the valve body;the first magnetic pole section is disposed at a first location of the annular base portion; andthe second magnetic pole section is disposed at a second location of the annular base portion. 5. The valve assembly of claim 1, wherein the first magnetic pole section and the second magnetic pole section comprise a magnet with the first magnetic pole section being a north pole of the magnet and the second magnetic pole section being a south pole of the magnet. 6. The valve assembly of claim 1, wherein the internal actuation member is disposed in a cavity of the valve body, wherein the cavity is sealed such that the external actuator is not mechanically coupled to the internal actuation member or a stem of the valve assembly. 7. The valve assembly of claim 1, further comprising a first port and a second port separated by the movable valve member. 8. The valve assembly of claim 1, further comprising a cheater handle, the cheater handle comprising: at least one other magnet, wherein the at least one other magnet has a second magnetic field strength that is greater than the magnetic field strength of the first magnetic pole section and the second magnetic pole section, wherein the cheater handle is sized and shaped so as to couple to the exterior of the valve body. 9. The valve assembly of claim 1, further comprising: a magnetically permeable conical portion, the magnetically permeable conical portion further comprising:a first base in a first plane, and a second base in a second plane parallel to the first plane, wherein the second base has a larger area in the second plane relative to an area of the first base in the first plane; andwherein the second base is coupled to the first magnetic pole section. 10. The valve assembly of claim 1, wherein the external actuator is removable from the valve body such that the valve body may be heated without heating the external actuator, the first magnetic pole section, and the second magnetic pole section. 11. A valve comprising: a valve body having an interior portion and an exterior portion, the interior portion defining a cavity;a movable valve member movable between an open position and a closed position;an internal actuation member having a ferromagnetic portion comprising an impermanent magnet disposed in the cavity, the internal actuation member operatively coupled to the movable valve member such that rotation of the internal actuation member actuates movement of the movable valve member between the open position and the closed position; andan external actuator attached to the exterior portion of the valve body, the external actuator comprising: a first magnetic pole section adjacent to the exterior portion of the valve body;a second magnetic pole section adjacent to the exterior portion of the valve body, wherein magnetic flux flows from the first magnetic pole section through the ferromagnetic portion to the second magnetic pole section in a magnetic flux path through the interior portion of the valve, the magnetic flux having a magnitude sufficient to cause movement of the internal actuation member in response to rotation of the external actuator, wherein the external actuator and the internal actuation member are configured to remain adjacent to one another during rotation of the external actuator; andan impermanently magnetic ferromagnetic material completing a return flow path for the magnetic flux between the first magnetic pole section and the second magnetic pole section. 12. The valve of claim 11, wherein the internal actuation member comprises an elongate member having a first end aligned with the first magnetic pole section and a second end aligned with the second magnetic pole section. 13. The valve of claim 11, wherein the magnetic flux is effective to orient the internal actuation member in a first orientation with respect to the first magnetic pole section and the second magnetic pole section. 14. The valve of claim 11, wherein an aligned orientation of the internal actuation member with respect to the external actuator results in a lower magnetic reluctance than other orientations of the internal actuation member with respect to the external actuator. 15. The valve of claim 11, wherein the valve body comprises a cylindrical portion containing the internal actuation member; the external actuator comprises an annular base portion concentric with the cylindrical portion of the valve body;the first magnetic pole section is disposed at a first location of the annular base portion; andthe second magnetic pole section is disposed at a second location of the annular base portion. 16. The valve of claim 11, wherein the cavity is sealed such that the external actuator is not mechanically coupled to the internal actuation member or a stem coupled to the movable valve member. 17. The valve of claim 11, further comprising a magnetically permeable material disposed between the first magnetic pole section and a portion of the valve body adjacent to the internal actuation member, wherein a first size of a first surface of the magnetically permeable material that is adjacent to the first magnetic pole section corresponds to a second size of the magnetically permeable material, and a third size of a second surface of the magnetically permeable material corresponds to a fourth size of the portion of the valve body adjacent to the internal actuation member. 18. A method for magnetically actuating a valve, the method comprising: providing a valve comprising a sealed valve body, an internal actuation member disposed within the sealed valve body, and a valve member operatively coupled to the internal actuation member;attaching an external actuator to an exterior region of the sealed valve body, wherein the external actuator comprises: a first magnetic pole section adjacent to the sealed valve body;a second magnetic pole section adjacent to the sealed valve body; andan impermanently magnetic ferromagnetic material;magnetizing at least a portion of the internal actuation member by exposing the internal actuation member to magnetic fields of the first magnetic pole section and the second magnetic pole section to create a magnetic flux flowing from the first magnetic pole section, through the internal actuation member, to the second magnetic pole section, and returning through the impermanently magnetic ferromagnetic material to the first magnetic pole section;rotating the external actuator, wherein the rotation of the external actuator causes a corresponding rotation of the internal actuation member due to the magnetic flux; andmoving the valve member between an open position and a closed position, wherein the external actuator and the internal actuation member are configured to remain adjacent to one another during the rotation of the external actuator. 19. The method of claim 18, further comprising: removing the external actuator from the exterior region of the sealed valve body;heating the sealed valve body;determining that the sealed valve body has reached a temperature that is within a rated operating temperature range of the first magnetic pole section and the second magnetic pole section; andcoupling the external actuator to the exterior region of the sealed valve body. 20. The method of claim 18, further comprising changing an orientation of a magnetic flux path through the sealed valve body in response to the rotating the external actuator. 21. The method of claim 18, wherein, when the external actuator is in a first rotational position relative to the internal actuation member there is a first magnetic reluctance between the first magnetic pole section and the second magnetic pole section, and when the external actuator is in a second rotational position relative to the internal actuation member there is a second magnetic reluctance between the first magnetic pole section and the second magnetic pole section, wherein the second magnetic reluctance is lower than the first magnetic reluctance. 22. The valve assembly of claim 1, wherein the external actuator and the internal actuation member are configured to remain adjacent to one another during the rotation of the internal actuation member and the external actuator.