子分类:
- H01F2006/001: .感应电流限制器的结构部件
- H01F6/003: .{超导储能的放电方法和手段(超导合金入C22C;具有超导元件的静态存储器入G11C11/44;带有触点的超导断路器入H01H33/004;超导材料入H01L39/00;功率冷子管入H01L39/20;低功率超导开关入H03K17/92)}
- H01F6/005: .{通过增量(磁通泵)增加超导线圈储能的方法和手段}
- H01F6/006: .{供给激励电流或去激励电流的;磁通泵}
- H01F6/02: .骤冷;骤冷时的保护装置{(保护电路入H02H7/001)}
- H01F6/04: .冷却
- H01F6/06: .线圈,如绕组、绝缘、接线柱或外壳
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | 一种无变压器电感储能拓扑结构 | CN201010233716.8 | 2010-07-22 | CN102013696A | 2011-04-13 | 魏西平; 赵淑玉; 张跃平; 胡涛; 张坤; 李太峰; 杨洋; 王振 |
| 本发明涉及一种无变压器电感储能拓扑结构,该拓扑结构包括三相,每相由多个H桥功率模块与电感储能模块构成的子单元串联在一起,经缓冲电感接入电网。电感储能模块由超导线圈Lc、开关器件IGBT5、开关器件IGBT6、二极管D1、二极管D2组成,超导线圈Lc与二极管D1、开关器件IGBT5构成存储能量回路,超导线圈Lc还与二极管D2、开关器件IGBT6构成存储能量回路,该电感储能模块与电容C相并联。该拓扑并联在电网上,输入端无变压器,体积小、重量轻、成本低;可抑制电网的那些电力污染,可补偿光伏或风能发电的不稳定性,给电网上的负载提供不间断、干净、稳定、无频率突变、高质量的正弦波电压;且转换效率高、响应速度快。 | ||||||
| 62 | 具有浸没的相位线圈的高压故障限流器 | CN200880118087.5 | 2008-11-27 | CN101878572A | 2010-11-03 | 弗朗西斯·安东尼·达曼 |
| 本发明公开一种故障限流器,该限流器包括:铁磁线路,该铁磁线路由铁磁材料制成,且包括至少第一芯柱和第二芯柱;围绕所述一个芯柱的饱和机构,用于使所述铁磁材料磁饱和;卷绕所述第二芯柱的相位线圈;包围所述相位线圈的介电流体,包围所述饱和机构的气体环境。 | ||||||
| 63 | 爆破片更换装置 | CN200910006371.X | 2009-02-16 | CN101509602A | 2009-08-19 | 特雷弗·B·赫斯本德; 菲利普·A·C·沃尔顿 |
| 一种爆破片更换装置(100),包括携带第一爆破片(232)和第二爆破片(234)的盒(122)。穿过该装置(100)的用于泄流的流动路径(104)。第一爆破片(232)位于该流动路径内(104内)。平移机构(112,144,146,200,214,220,222)被设置用于响应第一爆破片(232)的一侧的流体压力超过与第一爆破片(232)的破裂相对应的预定压力,把第二爆破片(234)移动到流动路径(104)内代替第一爆破片(232)。 | ||||||
| 64 | 爆破片更换设备 | CN200910005839.3 | 2009-02-05 | CN101509601A | 2009-08-19 | 马修·霍布斯; 特雷弗·B·赫斯本德; 菲利普·A·C·沃尔顿 |
| 一种爆破片更换设备(102),包括:一个片架(114),其承载一第一爆破片(116)和一第二爆破片(118)。所述设备还包括一条穿过所述片架(114)的流动路径(104),其用于排放流体。所述第一爆破片(116)位于所述流动路径(104)中,且所述第二爆破片(118)位于所述流动路径(104)外。还提供一个平移机构,其耦合到所述片架(114),且经布置以允许手动平移所述片架(114),使得所述第二爆破片(118)在使用中时移动到所述流动路径(104)中以代替所述第一爆破片(116)。 | ||||||
| 65 | 用于利用超导磁体设置传感器反铁磁的方法和设备 | CN200610073269.8 | 2006-04-06 | CN100394478C | 2008-06-11 | 李文扬; 李晋山 |
| 本发明涉及利用水平设置的超导磁设备构造磁致电阻传感器的方法。该超导磁设备能产生持续时段的很高磁场从而有效地设置具有很高钉扎场的磁致电阻传感器的磁化。该超导磁设备具有被超导线圈围绕的陶瓷管。该管具有水平取向的纵轴,从而提供很多重要的优点,诸如:便于该设备内含有传感器的晶片的操纵;便于将晶片装载到该设备中;防止退火期间该晶片内的温度和磁场的梯度;以及通过限制该设备的高度便于该设备的维护和存放。 | ||||||
| 66 | 拉晶装置用的超导磁体装置 | CN200310124830.7 | 1999-02-13 | CN1320172C | 2007-06-06 | 佐佐木高士; 新政宪 |
| 本发明提供一用于拉晶装置的超导磁体装置,包括:一对相互对向的环形超导线圈,它们之间配置拉晶装置,包围超导线圈的防辐射屏,包围此防辐射屏的真空容器,其中,在面向拉晶装置侧的真空容器部件51由非磁性物质制成,而在其他侧的真空容器部件52由磁性物质制成。 | ||||||
| 67 | 用于利用超导磁体设置传感器反铁磁的方法和设备 | CN200610073269.8 | 2006-04-06 | CN1877701A | 2006-12-13 | 李文扬; 李晋山 |
| 本发明涉及利用水平设置的超导磁设备构造磁致电阻传感器的方法。该超导磁设备能产生持续时段的很高磁场从而有效地设置具有很高钉扎场的磁致电阻传感器的磁化。该超导磁设备具有被超导线圈围绕的陶瓷管。该管具有水平取向的纵轴,从而提供很多重要的优点,诸如:便于该设备内含有传感器的晶片的操纵;便于将晶片装载到该设备中;防止退火期间该晶片内的温度和磁场的梯度;以及通过限制该设备的高度便于该设备的维护和存放。 | ||||||
| 68 | 有效屏蔽高磁性谐振成像装置开口磁体的低温整体支撑体 | CN200310120733.0 | 2003-11-25 | CN1523369A | 2004-08-25 | E·拉斯卡里斯; X·黄; M·D·奥勒; M·A·帕尔莫; P·S·汤普森 |
| 有效屏蔽高磁性谐振成像装置开口磁体的低温整体支撑体。本发明公开一种开口磁性谐振成像(MRI)装置(100),设置了至少一个主线圈(110,115),用于产生可对物体成像的磁场;和至少一个成形线圈(150,152,153,154,155,156,157,158)。至少一个成形线圈(150,152,153,154,155,156,157,158)相对至少一个主线圈(110,115)设置,可使物体中的磁场成形。 | ||||||
| 69 | 拉晶装置用的超导磁体装置 | CN200310124830.7 | 1999-02-13 | CN1508298A | 2004-06-30 | 佐佐木高士; 新政宪 |
| 本发明提供一用于拉晶装置的超导磁体装置,包括:一对相互对向的环形超导线圈,它们之间配置拉晶装置,包围超导线圈的防辐射屏,包围此防辐射屏的真空容器,其中,在面向拉晶装置侧的真空容器部件51由非磁性物质制成,而在其他侧的真空容器部件52由磁性物质制成。 | ||||||
| 70 | 超导磁铁装置 | CN98109524.0 | 1998-05-29 | CN1201843A | 1998-12-16 | 佐々木高士; 伊藤孝治; 新政宪; 河合正道; 十桥隆博; 小口义広 |
| 一种超导磁铁装置,包括:真空容器;两个沿真空容器轴向相互对置的环形超导线圈;以及支承两个超导线圈的支承结构。支承结构包括沿真空容器轴向将两个超导线圈连接起来的线圈连接体和整体支承两个经线圈连接体相连的超导线圈的支承体,通过支承体把两个超导线圈安装到真空容器中。 | ||||||
| 71 | ELECTRICAL MACHINE AND METHOD FOR OPERATING IT | PCT/EP2012064088 | 2012-07-18 | WO2013014043A2 | 2013-01-31 | FRANK MICHAEL; FRAUENHOFER JOACHIM; GRUNDMANN JOERN; HERKERT WERNER; KUMMETH PETER; NICK WOLFGANG; SCHMIDT HEINZ; VAN HASSELT PETER |
| Electrical machine (1) comprising, as components, a stator (3) and a rotor (4) which can be rotated in relation to the stator (3), wherein the poles (14) of one component, in particular of the rotor (4), comprise superconducting coils (6) for generating a magnetic flux, wherein at least one high-temperature superconducting material block (7, 8, 9) with a heating means (10, 11, 12), which is associated with said high-temperature superconducting material block and is designed to temporarily increase the temperature of the high-temperature superconducting material block (7, 8, 9) above the critical temperature of the material of the high-temperature superconducting material block (7, 8, 9) in the superconducting coil (6), is arranged in the path of the magnetic flux. | ||||||
| 72 | ROTATING MAGNETEC FIELD AND FIXED CONDUCTING WIRE COIL GENERATOR | PCT/US2006033496 | 2006-08-29 | WO2007032898A3 | 2009-06-04 | MINER STEVEN |
| A system and method for generating power. A plurality of superconductive electromagnet pairs are disposed around a stationary coil in a circular pattern. The electromagnets of each respective electromagnet pair are positioned on opposing sides of the circular pattern. A control processor is connected to each electromagnet pair. When the control processor applies power to turn on and off the electromagnet pairs in a predetermined sequence, rotational and magnetic fields are generated and a current flow is induced in the stationary coil. The resulting current may be used to provide power to external systems and to operate the power generating system. | ||||||
| 73 | MAGNET SYSTEM FOR MAGNETIC RESONANCE SPECTROSCOPY COMPRISING SUPERCONDUCTING ANNULI | PCT/US2006038519 | 2006-10-03 | WO2007041532A3 | 2007-06-21 | IWASA YUKIKAZU; TOMITA MASARU |
| A persistent-mode magnet, assembled from superconducting annuli, provides a micro coil NMR, in which compactness and manufacturability are provided for a variety of applications . An annular magnet for micro NMR can include a YBCO-annulus Helmholtz coil, for example, that can energized by a magnet system and then at a first site transported for use at a second location with an operating system. | ||||||
| 74 | CRYOGENIC CONTAINER, SUPERCONDUCTIVITY MAGNETIC ENERGY STORAGE (SMES) SYSTEM, AND METHOD FOR SHIELDING A CRYOGENIC FLUID | PCT/US2005017585 | 2005-05-19 | WO2006083274A2 | 2006-08-10 | EGAN GREGORY J |
| A cryogenic container (10) includes an inner vessel (14) for containing a cryogenic fluid (16), and an outer vessel (12) for insulating the cryogenic fluid from the environment. The inner vessel (14) includes a superconductive layer (22) formed of a material having superconducting properties at the temperature of the cryogenic fluid (16). The superconductive layer (22) forms a magnetic field around the cryogenic container (10), that repels electromagnetic energy, including thermal energy from the environment, keeping the cryogenic fluid (16) at low temperatures. The cryogenic container (10) has a portability and a volume that permits its' use in applications from handheld electronics to vehicles such as alternative fueled vehicles (AFVs). A SMES storage system (24) includes a cryogenic container (26), and a SMES magnet (38) suspended within a cryogenic fluid (34). The SMES storage system 24 can also include a recharger (42) and a cryocooler (40) configured to recharge the cryogenic container (26) with the cryogenic fluid (34). | ||||||
| 75 | SYSTEMS AND METHODS FOR ACTIVATION OF TRAPPED FIELD MAGNETS | PCT/US2015012232 | 2015-01-21 | WO2015156883A3 | 2016-05-26 | PARKS DREW PAUL; WEINSTEIN ROY; SAWH RAVI-PERSAD; CARPENTER KEITH |
| A system for activating trapped field magnets in a superconducting material may include a superconducting material element and an electromagnet source disposed proximate the superconducting material element. The electromagnet source may be configured to produce a magnetic field pulse sufficient to activate the superconducting material element. The superconducting material element may be configured to retain a trapped magnetic field that is substantially equal to a magnetic field generated by the magnetic field pulse. | ||||||
| 76 | TECHNIQUE FOR LIMITING TRANSMISSION OF FAULT CURRENT | PCT/US2010039646 | 2010-06-23 | WO2010151583A2 | 2010-12-29 | TEKLETSADIK KASEGN D; FISH ROGER B; MURPHY PAUL J |
| A new type of superconducting fault current limiter is disclosed, which can advantageously be used with high voltage transmission networks. The circuit is electrically connected to two terminals, which connect to the transmission network. The superconducting circuit is located within an enclosure or tank, which is electrically isolated from ground. Therefore, the voltage difference between the enclosure and the superconducting circuit, and between the enclosure and the terminals are significantly less than exist in current deployments. In some embodiments, the enclosure is electrically connected to one of the terminals, while in other embodiments, the enclosure is electrically isolated from the terminals. The circuit can be combined with other like circuits to address a wide range of current transmission network configurations. | ||||||
| 77 | SELF FIELD TRIGGERED SUPERCONDUCTING FAULT CURRENT LIMITER | PCT/US2006020939 | 2006-05-30 | WO2008045013A3 | 2008-10-23 | |
| A superconducting fault current limiter array (10) with a plurality of superconductor elements (scn) arranged in a meanding array having an even number of supconductors parallel to each other and arranged in a plane that is parallel to an odd number of the plurality of superconductors, where the odd number of supconductors are parallel to each other and arranged in a plane that is parallel to the even number of the plurality of superconductors, when viewed from a top view. The even number of superconductors are coupled at the upper end to the upper end of the odd number of superconductors. A plurality of lower shunt coils (rbn) each coupled to the lower end of each of the even number of superconductors and a plurality of upper shunt coils (rcn) each coupled to the upper end of each of the odd number of superconductors so as to generate a generally orthoganal uniform magnetic field (6) during quenching using only the magenetic field generated by the superconductors. | ||||||
| 78 | SUPERCONDUCTIVE MAGNET FOR PERSISTENT CURRENT AND METHOD FOR MANUFACTURING THE SAME | PCT/KR2006002017 | 2006-05-26 | WO2007004787A2 | 2007-01-11 | HONG GYE-WON; LEE HEE-GYOUN |
| Disclosed are a superconductive magnet manufactured by winding a thin superconductive rod wire in a coil without joint for maintaining a persistent current mode, and a method for manufacturing the same. The method includes winding both ends of a superconductive rod wire (10) on a first bobbin (21) and a second bobbin (22) respectively; forming a first unit rod wire (10a) and a second unit rod wire (10b) by slitting the superconductive rod wire (10) i n the lengthwise direction; producing a pancake coil by winding the first and second unit rod wires (10a, 10b) on third bobbins (25) in one direction; and arranging the first and second unit rod wires (10a, 10b) such that magnetic fields (B, B') in t he same direction are generated from the pancake coil, by reversing one of the third bobbins (25) on which the first and second unit rod wires (10a, 10b) are wound. | ||||||
| 79 | 자기장 변위를 이용한 초전도 직류 유도가열 장치 | KR1020160074046 | 2016-06-14 | KR101877118B1 | 2018-07-10 | 박민원; 최종호; 유인근 |
| 본발명은자기장변위를이용한초전도직류유도가열장치에관한것으로서, 더욱상세하게는, 본발명의실시예에따른자기장변위를이용한초전도직류유도가열장치는, 가열대상부재를중심으로기설정된거리만큼서로대칭되게위치하고, 인가되는직류전류에따라자기장을발생시키는초전도자석; 상기초전도자석의내부를관통하고, 상기가열대상부재와마주보는끝부분형상에길이방향으로의각도가형성되어길이방향으로의각도에따른자기장변위를상기가열대상부재에유도시키는이동형부재; 및상기가열대상부재와회전축을통해연결되어상기가열대상부재를회전시키는회전부를포함한다. | ||||||
| 80 | 초전도 전력기기용 압력 발생 장치 및 방법 | KR1020160121622 | 2016-09-22 | KR1020180032417A | 2018-03-30 | 한영희; 박병준; 양성은; 김혜림 |
| 본발명은초전도전력기기용압력발생장치및 방법에관한것으로써보다상세하게는, 초전도전력기기에서액체질소를가압하기위하여별도로구성되는가압시스템을압력용기의내부에구성한초전도전력기기용압력발생장치및 방법에관한발명이다. | ||||||
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