Oxide superconductor wire, connection structure thereof, and superconductor equipment

The invention claimed is: 1. An oxide superconductor wire comprising: a superconductor laminate comprising a tape-shaped substrate, an interlayer, an oxide superconductor layer, and a protection layer which are formed on the substrate; a metal stabilization layer covering the periphery of the superconductor laminate; a first electrically conductive joint material arranged between the superconductor laminate and the metal stabilization layer; and a sealing member formed from a metal foil, connected to a terminal of the superconductor laminate, and extending in the longitudinal direction of the superconductor laminate, wherein the metal stabilization layer comprises an extension part formed so as to cover the periphery of the sealing member, and wherein the first electrically conductive joint material comprises an extension part arranged between the extension part of the metal stabilization layer and the sealing member and formed so as to cover the periphery of the sealing member. 2. The oxide superconductor wire according to claim 1 , wherein the sealing member is butt-welded to the terminal of the superconductor laminate. 3. The oxide superconductor wire according to claim 1 , wherein a recess is formed in the terminal of the superconductor laminate, and wherein an end of the sealing member is overlaid on and welded to the recess. 4. A connection structure of an oxide superconductor wire comprising: a first oxide superconductor wire and a second oxide superconductor wire which are the oxide superconductor wire according to claim 1 ; and a second electrically conductive joint material joining the first oxide superconductor wire and the second oxide superconductor wires together, wherein upper faces of the metal stabilization layers arranged at an upside of the first oxide superconductor wire and the second oxide superconductor wires are mutually overlaid so as to oppose to each other, and are joined together with the second electrically conductive joint material. 5. A connection structure of an oxide superconductor wire comprising: a first oxide superconductor wire, a second oxide superconductor wire, and a third oxide superconductor wire which are the oxide superconductor wire according claim 1 ; a third electrically conductive joint material joining the first oxide superconductor wire and the third oxide superconductor wire together; and a fourth electrically conductive joint material joining the second oxide superconductor wire and the third oxide superconductor wire together, wherein an upper face of the metal stabilization layer arranged at an upside of the first oxide superconductor wire and an upper face of the metal stabilization layer arranged at an upside of the third oxide superconductor wire are mutually overlaid so as to oppose to each other, and are joined together with the third electrically conductive joint material, and wherein an upper face of the metal stabilization layer arranged at an upside of the second oxide superconductor wire and the upper face of the metal stabilization layer arranged at the upside of third oxide superconductor wire are mutually overlaid so as to oppose to each other, and are joined together with the fourth electrically conductive joint material. 6. A superconductor equipment comprising the oxide superconductor wire according to claim 1 . 7. A superconductor equipment comprising the connection structure of a oxide superconductor wire according to claim 4 . 8. A manufacturing method of the oxide superconductor wire according to claim 1 , the method comprising: joining the sealing member to the terminal of the superconductor laminate; with a use of a coated metal tape of which at least one surface is provided with the first electrically conductive joint material, adhering the coated metal tape to the periphery of the sealing member and the periphery of the superconductor laminate by roll forming, covering the periphery of the superconductor laminate with the first electrically conductive joint material and the metal stabilization layer by melting and solidifying the first electrically conductive joint material; and covering the periphery of the sealing member with the extension part of the electrically conductive joint material and the extension part of the metal stabilization layer.