| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 81 | OXIDE SUPERCONDUCTING BULK MAGNET | US15545170 | 2016-01-21 | US20180012690A1 | 2018-01-11 | Mitsuru MORITA |
| An oxide superconducting bulk magnet able to prevent breakage of a superconducting bulk member and able to give a sufficient amount of total magnetic flux at a superconducting bulk member surface even under high magnetic field strength conditions, comprising an oxide superconducting bulk laminate formed from sheet-shaped oxide superconducting bulk members and high strength reinforcing members arranged between the stacked oxide superconducting bulk members, the outer circumference of the oxide superconducting bulk laminate being provided with an outer circumference reinforcing member. | ||||||
| 82 | SUPERCONDUCTING WIRE AND SUPERCONDUCTING COIL | US15540928 | 2015-12-22 | US20180005731A1 | 2018-01-04 | Kosei FUKUOKA; Yuki ITO; Kazunari MAKI |
| The present invention is a superconducting wire including: a wire formed of a superconducting material; and a superconducting stabilization material disposed in contact with the wire, in which the superconducting stabilization material is formed of a copper material which contains: one or more types of additive elements selected from Ca, Sr, Ba, and rare earth elements in a total of 3 ppm by mass to 400 ppm by mass; a balance being Cu and inevitable impurities, and in which a total concentration of the inevitable impurities excluding O, H, C, N, and S which are gas components is 5 ppm by mass to 100 ppm by mass. | ||||||
| 83 | SUPERCONDUCTING STABILIZATION MATERIAL, SUPERCONDUCTING WIRE, AND SUPERCONDUCTING COIL | US15539077 | 2015-12-24 | US20170352453A1 | 2017-12-07 | Kosei FUKUOKA; Yuki ITO; Kazunari MAKI |
| The present invention is a superconducting stabilization material used for a superconducting wire, which is formed of a copper material which contains: one or more types of additive elements selected from Ca, La, and Ce in a total of 3 ppm by mass to 400 ppm by mass; and a balance being Cu and inevitable impurities and in which a total concentration of the inevitable impurities excluding O, H, C, N, and S which are gas components is 5 ppm by mass to 100 ppm by mass. | ||||||
| 84 | WIRE SPLICING DEVICE, WIRE SPLICING METHOD, AND METHOD FOR MANUFACTURING SPLICE STRUCTURE | US15399951 | 2017-01-06 | US20170117688A1 | 2017-04-27 | Shinji FUJITA |
| A wire splicing method including: disposing an end portion of a tape-like first wire and an end portion of a tape-like second wire in a holding base in an overlapping manner with solder interposed therebetween, pressing a heating body to the first wire and the second wire via a pressing plate, and pressing together and heating the first wire and the second wire so as to melt the solder; keeping the first wire and the second wire pressed together by the pressing plate; separating the heating body from the pressing plate; and cooling the pressing plate to solidify the solder, and thereby connecting the first wire and the second wire together. | ||||||
| 85 | WIRE SPLICING DEVICE, WIRE SPLICING METHOD, AND METHOD FOR MANUFACTURING SPLICE STRUCTURE | US14893814 | 2014-05-28 | US20160105005A1 | 2016-04-14 | Shinji FUJITA |
| A wire connection device includes: a holding base which is provided with a wire accommodation groove having a width, the wire accommodation groove being configured to accommodate a plurality of wires; a pressing plate which is positioned above the holding base; a heating body which is positioned above the pressing plate and includes a heating member; a first driver which drives the holding base and the pressing plate away from or toward one another; and a second driver which drives the holding base and the heating body toward or away from one another, in which the pressing plate which is driven toward the holding base by the first driver presses together the plurality of wires accommodated in the wire accommodation groove with solder interposed therebetween. | ||||||
| 86 | System with a superconductive cable and a surrounding cryostat | US13529293 | 2012-06-21 | US09006576B2 | 2015-04-14 | Mark Stemmle; Rainer Soika |
| A superconductive cable which has a cryostat with two concentric metal pipes where the cryostat has at least a first axial section with a first axial spring constant, and at least a second axial section which has a second axial spring constant which at most is 20%, more preferred at most 10%, of the axial spring constant of the first section. | ||||||
| 87 | Super-conductive tube used for a discharge device | US13355971 | 2012-01-23 | US08929962B2 | 2015-01-06 | Chao-Yuan Liang |
| A super-conductive tube used for a discharge device is formed integrally by a super-conductive material. The super-conductive tube is a hollow tube formed by a front end surface, a rear end surface, an inner tube wall and an outer tube wall. An interior of the super-conductive tube is formed with a hollow space and an interior of the hollow space is in a vacuum state. The inner tube wall and the outer tube wall are formed by extending the front end surface toward the rear end surface and an end of the outer tube wall is extended with a guide portion toward the discharge device. Accordingly, when the super-conductive tube is applied to a discharge device, electrical energy will be generated by the super-conductive tube through a magnetic field that results from an operation of electric current, after the discharge device has released electric energy. | ||||||
| 88 | Adjustable support insulator for a high-voltage long-distance transmission line | US13379735 | 2010-05-03 | US08759684B2 | 2014-06-24 | Jens Seifert |
| The invention relates to a long-distance line for high voltage, having an outer jacket pipe extending in a longitudinal direction, having an inner conductor led in the interior of the jacket pipe in parallel to the longitudinal direction, and having a number of mounting insulators, by means of which the inner conductor is held on the jacket pipe at a distance therefrom transverse to the longitudinal direction, and a correspondingly embodied mounting insulator. The mounting insulators serve for adjusting the distance between the inner conductor and the jacket pipe. The long-distance transmission line is particularly air insulated in design. The mounting insulators allow simple assembly and installation of the inner conductor. | ||||||
| 89 | Semi-finished wire for a Nb3Sn superconducting wire | US14043865 | 2013-10-02 | US20140096997A1 | 2014-04-10 | Klaus Schlenga |
| A semi-finished wire (1) for a Nb3Sn superconducting wire (45) has a multiplicity of elements containing Nb packed against each other (6). The elements containing Nb (6) each have a rod containing Nb (7) and an enclosure containing Cu (8) surrounding the latter. The semi-finished wire also has a structure containing Sn (5) and a matrix containing Cu (4) in which the structure containing Sn (5) is disposed and on and/or in which the elements containing Nb (6) are disposed. The enclosures containing Cu (8) of the elements containing Nb (6), contain Sn. The semi-finished wire is suitable for manufacturing an Nb3Sn superconducting wire with which further improved superconducting current-carrying capacity is achieved. | ||||||
| 90 | SUPERCONDUCTING POWER TRANSMISSION SYSTEM | US13821277 | 2011-09-05 | US20130240236A1 | 2013-09-19 | Sataro Yamaguchi; Hirofumi Watanabe |
| In a thermally insulated double pipe, a structure is provided in which an inner pipe may be prevented from being appreciably offset relative to an outer pipe due to thermal contraction. The structure includes an inner pipe 101, within which a superconducting cable is mounted, an outer pipe 103 within which the inner pipe is housed, with the inner and outer pipes constituting a thermally insulated double pipe, and an inner pipe support member 104 supporting the inner pipe. The inner pipe support member 104 is secured to the inner and outer pipes. | ||||||
| 91 | SUPER-CONDUCTIVE TUBE USED FOR A DISCHARGE DEVICE | US13355971 | 2012-01-23 | US20130190182A1 | 2013-07-25 | Chao-Yuan LIANG |
| A super-conductive tube used for a discharge device is formed integrally by a super-conductive material. The super-conductive tube is a hollow tube formed by a front end surface, a rear end surface, an inner tube wall and an outer tube wall. An interior of the super-conductive tube is formed with a hollow space and an interior of the hollow space is in a vacuum state. The inner tube wall and the outer tube wall are formed by extending the front end surface toward the rear end surface and an end of the outer tube wall is extended with a guide portion toward the discharge device. Accordingly, when the super-conductive tube is applied to a discharge device, electrical energy will be generated by the super-conductive tube through a magnetic field that results from an operation of electric current, after the discharge device has released electric energy. | ||||||
| 92 | SUPERCONDUCTIVE CABLE | US13529293 | 2012-06-21 | US20130174584A1 | 2013-07-11 | Mark Stemmle; Rainer Soika |
| A superconductive cable which has a cryostat with two concentric metal pipes where the cryostat has at least a first axial section with a first axial spring constant, and at least a second axial section which has a second axial spring constant which at most is 20%, more preferred at most 10%, of the axial spring constant of the first section. | ||||||
| 93 | Superconductive circuits with efficient method | US11545656 | 2006-10-10 | US20080085834A1 | 2008-04-10 | James Scott Hacsi |
| Circuits exhibiting very low electrical resistance or superconductivity are provided as well as a method for transmitting, storing, or otherwise using electric energy more effectively and efficiently for providing powerful electromagnets for motors and generators, for transmitting electric power with few losses, or for making energy-storage devices with a high energy-density. | ||||||
| 94 | Superconducting cable and superconducting cable line | US10470418 | 2003-07-29 | US20040058822A1 | 2004-03-25 | Kazuya Ohmatsu |
| A superconducting cable includes a first conductor layer formed of superconducting wires, and an insulating layer formed at the outer periphery of the first conductor layer. The first conductor layer is an assembly of a plurality of superconducting wires obtained by forming an RE based superconductor layer on a metal substrate. The current is limited by an electrical resistance generated when the current of the first conductor layer exceeds the critical current, thereby preventing the superconducting cable from being damaged. A superconducting cable line is formed of a base and a current limiter, which is formed by using the above-described superconducting cable. Accordingly, when a current exceeding the rated current of the base flows, it can be damped. | ||||||
| 95 | Structure of the terminal portion of a cable | US3801723D | 1973-01-30 | US3801723A | 1974-04-02 | KUBO I; SHISEKI N |
| A conductor portion of the terminal portion of a cable is encased in a terminal box having an inlet and outlet provided for accommodating the circulation through the terminal box of a liquid nitrogen coolant. The conductor portion is connected to a conductor leading wire which extends through a bushing up to a normal temperature area. The terminal box and part of the bushing are housed within a tank and the tank has an inlet and outlet provided for accommodating the circulation through the tank of a liquid coolant. The bushing has an inlet and outlet provided for accommodating circulation through the bushing of liquid nitrogen coolant. With the structure so arranged the conductor of the cable is led out up to a normal temperature area with a temperature gradient formed along the conductor leading wire.
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| 96 | Method and apparatus for supercooling of electrical devices | US3795116D | 1971-03-25 | US3795116A | 1974-03-05 | BURNIER P; BRICOUT D |
| To improve efficiency and space factor, compressed gas at ambient temperature is supplied to the inside of a housing which contains electrical apparatus to be operated at cryogenic temperature, the gas being expanded and supercooled inside the housing, with possible additional cooling stages located therein; heat exchangers, in the form of heat exchange shields are located within the housing intermediate the housing walls and the electrical devices to be supercooled. Typical electric devices are superconductive coils, cables and the like, the cooling fluid being conducted, if desired, through hollow portions of the devices.
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| 97 | 超電導線用の半製品を生成する方法 | JP2017245509 | 2017-12-21 | JP2018138692A | 2018-09-06 | ヴィタル アバッシェルリ; クラウス シュレンガ; ベルント ザイラー; マンフレッド トエナー; マテウス ヴァニオア |
| 【課題】本発明の目的は、超電導線又はこのような超電導線用の半製品のNbTi材料内への人工ピン止め中心の導入を簡単にすることである。 【解決手段】超電導線用の半製品(50、51)を生成する方法に関する。半製品(50、51)は、少なくとも1つのNbTi含有構造(2)、特にNbTi含有ロッド構造を備え、NbTi含有構造(2)は、Nb及びTiを含有する粉末(6)の選択的レーザ溶融又は選択的電子ビーム溶融によって層状に生成され、NbTi含有構造(2)の少なくともいくつかの層(5、5a、5b)の生成において、当該層(5、5a、5b)それぞれの材料堆積のために設けられる照射領域(20)の生成中に、選択的レーザ溶融又は選択的電子ビーム溶融の1つ又は複数のプロセスパラメータが、照射領域(20)の1つ又は複数の第1の区間(23)内では、照射領域(20)の1つ又は複数の第2の区間(24)に比べて異なる。 【選択図】図2 |
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| 98 | 少なくとも1つの超伝導ケーブルを備えた装置 | JP2013154513 | 2013-07-25 | JP6216173B2 | 2017-10-18 | マルク・シュテムレ; シップル・クラウス; ランゲ・シュテファン; ディ・パルマ・ミヒャエル |
| 99 | Method of manufacturing an oxide superconductor for the composition, and the oxide superconducting wire | JP2013039810 | 2013-02-28 | JP5591966B2 | 2014-09-17 | 晃一 中岡; 正晃 吉積; 輝郎 和泉; 融 塩原; 達徳 中村 |
| 100 | Apparatus equipped with at least one superconductive cable | JP2013154513 | 2013-07-25 | JP2014032962A | 2014-02-20 | MARC STEMMLE; KLAUS SCHIPPL; LANGE STEPHAN; MICHELE DI PALMA |
| PROBLEM TO BE SOLVED: To simplify the constitution of an apparatus equipped with at least one superconductive cable.SOLUTION: The provided apparatus equipped with at least one superconductive cable includes at least one superconductive cable and a cryostat surrounding the superconductive cable in a state where the cryostat possesses at least one heat insulating tube and where the heat insulating tube surrounds a hollow space for guiding the superconductive cable and a refrigerant. The cryostat is constituted, as is the superconductive cable housed within the cryostat, to become connected to a fixed-position site of an electric energy transmission path. Two bellows are incorporated, via a gap in-between both, to the cryostat (KR) at the respective terminal ends of the cryostat constituted to become connected to the fixed-position site of the electric energy transmission path, whereas a tubular specimen belonging to the cryostat, thermally insulated, and extending in a curvy manner is outfitted between both bellows positioned respectively at both terminal ends of the cryostat (KR). | ||||||
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