Apparatus for inductive braking of a projectile are disclosed. Embodiments include a receiver that has a unidirectional conductor having a closed conductive pathway that encircles a passageway for a moving projectile. The unidirectional conductor permits current to flow through it in substantially o
Apparatus for inductive braking of a projectile are disclosed. Embodiments include a receiver that has a unidirectional conductor having a closed conductive pathway that encircles a passageway for a moving projectile. The unidirectional conductor permits current to flow through it in substantially only one direction around the passageway. As the projectile and its associated magnetic field move past the unidirectional conductor, the moving magnetic field induces a current flow through the closed conductive pathway, which in turn generates a magnetic field behind the projectile having the same polarity as the projectile's field. The two fields attract one another, which both exerts a braking force on the projectile and tends to align the two fields. Alignment of these fields centers the projectile away from the passageway wall. Because the unidirectional conductor permits current to flow in substantially only the direction that produces a field having the same polarity as the moving field, the opposite-polarity repulsive magnetic field that would otherwise be generated ahead of the projectile, which would otherwise deflect the projectile from its path, is suppressed. Methods of inductive braking are also disclosed.
대표청구항▼
1. An inductive-braking system, comprising a projectile having an associated magnetic field that moves with the projectile, a unidirectional conductor comprising a first winding of a strip of conductive material wound around a longitudinal axis, said first winding having a first inner terminus and f
1. An inductive-braking system, comprising a projectile having an associated magnetic field that moves with the projectile, a unidirectional conductor comprising a first winding of a strip of conductive material wound around a longitudinal axis, said first winding having a first inner terminus and first outer terminus, said first inner and outer termini being connected via at least one diode to complete a closed conductive pathway that permits current to flow in substantially only one direction through said pathway, and a passageway for receiving said projectile, said passageway passing through a center of said first winding such that said first winding encircles said passageway. 2. The system of claim 1, said unidirectional conductor further comprising a second winding of a strip of conductive material, said first and second windings being concentric and axially adjacent one another such that said passageway passes through a center of both windings, said windings being electrically connected together to complete said closed conductive pathway. 3. The system of claim 2, said second winding having a second inner terminus and a second outer terminus, said outer termini being radially more distant from said longitudinal axis than said inner termini, wherein adjacent termini of the respective windings are connected together. 4. The system of claim 2, each said first and second windings having a plurality of turnings wound radially over one another such that current traveling through said conductive pathway travels through a radial depth of said windings and is not substantially confined at or adjacent an inner surface proximate said passageway. 5. The system of claim 3, said first and second outer termini being connected together via at least one diode. 6. The system of claim 3, each of the adjacent inner and outer termini of said first and second windings being connected together via at least one diode. 7. The system of claim 1, said first outer terminus being radially more distant from said longitudinal axis than said first inner terminus. 8. The system of claim 1, said first winding of conductive material having a plurality of successive turnings wound at successive radial depths of said first winding, such that current traveling through said first winding travels through said depths thereof and is not substantially confined at or adjacent an inner surface thereof proximate said passageway. 9. The system of claim 1, comprising a plurality of said unidirectional conductors disposed at axially-spaced intervals along a length of said passageway. 10. The system of claim 1, said projectile comprising a superconducting magnet for generating said magnetic field, said magnetic field having a field strength of at least 2 Tesla. 11. The system of claim 1, said projectile comprising a YBCO superconducting magnet for generating said magnetic field. 12. The system of claim 1, said unidirectional conductor being passive such that any current therein is induced by an applied magnetic field. 13. The system of claim 1, the magnetic field associated with said projectile inducing a current in said unidirectional conductor, said current flowing through said unidirectional conductor substantially in said only one direction. 14. An inductive-braking system, comprising a unidirectional conductor having a closed conductive pathway that permits current to flow in substantially only one direction, and a passageway for receiving a projectile, said passageway having a longitudinal axis, said unidirectional conductor being arranged such that said closed conductive pathway encircles said longitudinal axis, said unidirectional conductor comprising a cylinder of conductive material that is discontinuous along a longitudinal slit extending the length of said cylinder, wherein opposing longitudinal edges of the cylinder wall on opposite sides of said slit are connected via at least one diode. 15. The system of claim 14, comprising a plurality of diodes connecting said opposing longitudinal edges at spaced intervals along said length. 16. A method of decelerating a projectile, comprising: a) generating a first magnetic field that moves with said projectile;b) directing said projectile along a path that is encircled by a closed conductive pathway; andc) inhibiting induction of a current through said conductive pathway in a direction that would generate a magnetic field of opposite polarity to said first magnetic field;wherein as said projectile travels past said closed conductive pathway along said path, said first magnetic field produces a changing magnetic flux in a vicinity of said closed conductive pathway that induces a current in said closed conductive pathway in a direction that produces a second magnetic field having the same polarity as said first magnetic field. 17. The method of claim 16, said closed conductive pathway being provided by a winding of conductive material having a plurality of successive turnings wound at successive radial depths of said unidirectional conductor, such that current traveling through said unidirectional conductor travels through said depths thereof and is not substantially confined at or adjacent an inner surface thereof proximate the path of said projectile. 18. The method of claim 16, said closed conductive pathway comprising at least one diode, said diode permitting current to flow in substantially only the direction that generates said second magnetic field having the same polarity as the first magnetic field. 19. The method of claim 16, wherein said first and second magnetic fields attract one another to both exert a braking force on said projectile and center said projectile along a common central axis of said first and second magnetic fields. 20. The method of claim 16, said projectile comprising a superconducting field source for generating said first magnetic field, said first magnetic field having a field strength of at least 2 Tesla. 21. The method of claim 16, said projectile traveling at a speed of at least 2 kilometers per second on approaching said closed conductive pathway. 22. The method of claim 16, wherein the projectile is stationary and said closed conductive pathway is moving. 23. An inductive-braking system comprising: a receiver comprising a passageway for receiving a projectile, and a unidirectional conductor having a closed conductive pathway that encircles said passageway and permits current to flow in substantially only one direction around said passageway; anda projectile traveling through said passageway, wherein a first magnetic field moves with said projectile;said first magnetic field producing a changing magnetic flux in a vicinity of said closed conductive pathway, which induces a current to flow through said closed conductive pathway in said one direction around said passageway, said current generating a second magnetic field at a location behind said projectile, said second magnetic field having the same polarity as said first magnetic field such that an attraction between them exerts a braking force on said projectile and also tends to align said first magnetic field, which is moving with said projectile, on a common central axis with said second magnetic field. 24. The system of claim 23, said projectile comprising a field source that generates said first magnetic field. 25. The system of claim 24, said field source comprising a persistent-current superconducting magnet. 26. The system of claim 24, said persistent-current superconducting magnet comprising a high-temperature superconductor. 27. The system of claim 25, said persistent-current superconducting magnet being disposed within a cooling jacket filled with a liquid cryogen. 28. The system of claim 23, said passageway being defined by a wall, the alignment of said first and second magnetic fields centering said projectile within said passageway so as not to be in contact with said cylindrical wall. 29. The system of claim 28, said wall being cylindrical. 30. The system of claim 23, said receiver comprising a plurality of said unidirectional conductors encircling said passageway at spaced axial intervals along a length of said passageway. 31. The system of claim 23, said unidirectional conductor comprising first and second windings of strips of conductive material, said windings being concentric and axially adjacent such that said passageway passes through a center of both windings, said windings being electrically connected together via at least one diode to complete said closed conductive pathway. 32. The system of claim 23, said unidirectional conductor comprising a winding of conductive material having a plurality of successive turnings wound at successive radial depths of said unidirectional conductor, such that current traveling through said unidirectional conductor travels through said depths thereof and is not substantially confined at or adjacent an inner surface thereof proximate said passageway.
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