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Provided is a superconducting apparatus, including a joint of superconducting wires having high electric conduction characteristics and a superconducting magnet or the like. The superconducting joint comprises a plurality of superconducting wires and a sinter which integrates the plurality of superc

Provided is a superconducting apparatus, including a joint of superconducting wires having high electric conduction characteristics and a superconducting magnet or the like. The superconducting joint comprises a plurality of superconducting wires and a sinter which integrates the plurality of superconducting wires. Herein, at least any one of the superconducting wires is a MgB2 superconducting wire, the sinter contains MgB2, and the sinter is compressed form the direction different from the direction toward which the superconducting wires protrude. Further, in order to form such a joint, a compression vessel provided with an opening used for introducing raw material powders to construct the sinter and another opening used for inserting the superconducting wires is utilized, and the openings are directed to different directions each other. Accordingly, MgB2 is filled in the sinter at high density, allowing the joint structure to have a good bonding property among particles.

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1. A joint of superconducting wires comprising; a plurality of superconducting wires; anda compressed sinter containing MgB2 which integrates the superconducting wires, wherein the sinter has a density slope in a direction different from a direction along which longitudinal axes of the superconducti

1. A joint of superconducting wires comprising; a plurality of superconducting wires; anda compressed sinter containing MgB2 which integrates the superconducting wires, wherein the sinter has a density slope in a direction different from a direction along which longitudinal axes of the superconducting wires extend. 2. The joint of superconducting wires as described in claim 1, wherein at least any one of the superconducting wires contains MgB2. 3. The joint of superconducting wires as described in claim 1, wherein the sinter is covered by a resin. 4. The joint of superconducting wires as described in claim 1, wherein density of the sinter is 70% or more of the theoretical density of MgB2. 5. The joint of superconducting wires as described in claim 1, wherein the sinter contains at least any element selected from Cu, Ag, Sn, Ga, Pb, In, Bi, and Zn. 6. The joint of superconducting wires as described in claim 1, wherein surface areas of end parts of the superconducting wires that are in contact with the sinter are larger than cross-sectional areas of the wires in a direction orthogonal to the longitudinal direction of the wires. 7. The joint of superconducting wires as described in claim 1, wherein the wires are cut off to have slanting cross-sections, or partially scraped off in a longitudinal direction; andthe cross-sections of the wires are directed to the compressing direction. 8. The joint of superconducting wires as described in claim 6, wherein cross-sections of the plurality of superconducting wires are arranged so as to mutually face each other. 9. The joint of superconducting wires as described in claim 1, wherein the compressed sinter is covered by a compression vessel; andthe superconducting wires protrude from openings in the compression vessel. 10. The joint of superconducting wires as described in claim 9, wherein the compression vessel has an opening from which no superconducting wires protrude, and the opening from which no superconducting wires protrude has a tapered portion. 11. The joint of superconducting wires as described in claim 9, wherein the compression vessel has an opening from which no superconducting wires protrude, and a compressing member is inserted into the opening from which no superconducting wires protrude. 12. The joint of superconducting wires as described in claim 9, wherein the compression vessel has an opening from which no superconducting wires protrude, and screw machining is performed at an inside surface of a hole with the opening from which no superconducting wires protrude. 13. The joint of superconducting wires as described in claim 9, wherein the plurality of superconducting wires protrude from different openings respectively. 14. The joint of superconducting wires as described in claim 9, wherein the plurality of superconducting wires protrude from openings arranged in an opposite direction. 15. The joint of superconducting wires as described in claim 9, wherein the plurality of superconducting wires protrude from a single opening. 16. The joint of superconducting wires as described in claim 9, wherein the vessel is composed of any one of metals selected from Fe, Ni, Nb, and Ta, or an alloy containing the metal. 17. The joint of superconducting wires as described in claim 9, wherein the vessel is composed of a non-conducting material. 18. The joint of superconducting wires as described in claim 9, wherein the vessel is composed of at least any one member selected from alumina (Al2), silica (SiO2) and magnesia (MgO). 19. The joint of superconducting wires as described in claim 9, wherein the vessel and the superconducting wires are fixed by a resin or a solder. 20. A superconducting magnet comprising a superconducting coil, a persistent current switch, a joint for joining the superconducting coil and the persistent current switch, wherein the joint is the same joint of the superconductive wires as described in claim 1. 21. A method for joining superconducting wires, comprising the steps of: using a compression vessel provided with at least one first opening for inserting a plurality of superconducting wires and a second opening for introducing raw material powders used for forming MgB2;introducing the superconducting wires and the raw material powders from the respective openings into the compression vessel;compressing the powders by inserting a compressing member into the second opening; andheating the compressed powders, whereina longitudinal axis of the at least one first opening and a longitudinal axis of the second opening are arranged in different directions, and compressing the powders provides the powders with a density slope in a direction different from a direction along which longitudinal axes of the superconducting wires extend. 22. The method for joining superconducting wires as described in claim 21, wherein the compression member is removed after completion of compressing. 23. The method for joining superconducting wires as described in claim 21, further comprising the steps of: removing the compression vessel after completion of compressing, and covering a sinter produced after completion of heating the powders with a member made of a material which is different from a material of which the compression vessel is made. 24. The method for joining superconducting wires as described in claim 21, wherein an angle between the longitudinal axis of the at least one first opening and the longitudinal axis of the second opening is 60 degrees or more. 25. The method for joining superconducting wires as described in claim 21, wherein the longitudinal axis of the at least one first opening is orthogonal to the longitudinal axis of the second opening. 26. The joint of superconducting wires as described in claim 1, wherein the sinter has a density slope in a direction inclined at an angle of 60 degrees or more to the direction along which longitudinal axes of the superconducting wires extend. 27. The joint of superconducting wires as described in claim 1, wherein the sinter has a density slope in a direction orthogonal to the direction along which longitudinal axes of the superconducting wires extend.