초록 ▼

A Nb3Sn superconducting coil can be formed from a wire including multiple unreacted strands comprising tin in contact with niobium. The strands are wound into a cable, which is then heated to react the tin and niobium to form a cable comprising reacted Nb3Sn strands. The cable comprising the reacted

A Nb3Sn superconducting coil can be formed from a wire including multiple unreacted strands comprising tin in contact with niobium. The strands are wound into a cable, which is then heated to react the tin and niobium to form a cable comprising reacted Nb3Sn strands. The cable comprising the reacted Nb3Sn strands are then mounted in and soldered into an electrically conductive channel to form a reacted cable-in-channel of Nb3Sn strands. The cable-in-channel of reacted Nb3Sn strands are then wound to fabricate a superconducting coil. The Nb3Sn superconducting coil can be used, for example, in a magnet structure for particle acceleration. In one example, the superconducting coil is used in a high-field superconducting synchrocyclotron.

대표청구항 ▼

1. A superconducting coil, comprising: a plurality of windings of a coil comprising Nb3Sn strands; andan electrically conductive channel in which the coil comprising Nb3Sn strands is mounted, with no more than nine Nb3Sn strands mounted in a cross-section of the channel. 2. The superconducting coil

1. A superconducting coil, comprising: a plurality of windings of a coil comprising Nb3Sn strands; andan electrically conductive channel in which the coil comprising Nb3Sn strands is mounted, with no more than nine Nb3Sn strands mounted in a cross-section of the channel. 2. The superconducting coil of claim 1, further comprising solder in the channel, wherein the solder bonds the coil comprising Nb3Sn to the channel. 3. The superconducting coil of claim 2, wherein the channel comprises copper. 4. The superconducting coil of claim 1, wherein the coil includes at least 1,200 of the windings, and wherein the windings provide a current-carrying capacity of at least 2 million amps-turns in the coil. 5. The superconducting coil of claim 1, wherein the coil includes at least 1,500 of the windings, and wherein the windings provide a current-carrying capacity of at least 3 million amps-turns in the coil. 6. The superconducting coil of claim 1, further comprising a matrix between the windings. 7. The superconducting coil of claim 6, wherein the matrix comprises epoxy. 8. The superconducting coil of claim 7, wherein the matrix further comprises fiber. 9. The superconducting coil of claim 8, wherein the fiber comprises glass. 10. The superconducting coil of claim 1, wherein the channel has a cross-section with a radial dimension no greater than about 2.4 mm. 11. The superconducting coil of claim 1, wherein no more than four Nb3Sn strands are mounted in the cross-section of the channel. 12. A magnet structure, comprising: at least one superconducting coil comprising a plurality of windings of a coil comprising Nb3Sn strands and an electrically conductive channel in which the coil comprising Nb3Sn strands is mounted, with no more than nine Nb3Sn strands mounted in a cross-section of the channel; anda cryocooler configured and positioned to cool the superconducting coil. 13. The magnet structure of claim 12, wherein the cryocooler is a Gifford-McMahon cryocooler or a pulse-tube cryocooler. 14. The magnet structure of claim 12, further comprising at least one thermal coupling between the cryocooler and the superconducting coil. 15. The magnet structure of claim 14, wherein the thermal coupling is a superconducting current lead. 16. The magnet structure of claim 12, further comprising a matrix between the windings. 17. The magnet structure of claim 16, wherein the matrix comprises a glass-fiber/epoxy composite. 18. The magnet structure of claim 12, further comprising: a bobbin in which the superconducting coil is mounted; andradial-tension links coupled with the bobbin and applying outward radial tension on the bobbin at a plurality of positions. 19. The magnet structure of claim 18, further comprising a pressurized bladder positioned between each coil and the bobbin to apply radial inward force on the coil. 20. The magnet structure of claim 12, wherein the structure includes at least two of the superconducting coils, the magnet structure further comprising a magnetic yoke that contains the superconducting coils. 21. The magnet structure of claim 20, wherein the magnetic yoke comprises a pair of poles, wherein the poles are on opposite sides of a median acceleration plane, and wherein the magnet structure further comprises an ion source configured to release ions into the median acceleration plane for acceleration. 22. The magnet structure of claim 21, wherein the superconducting coils have an outer radius no greater than 20 inches.