A nontrivial factor in determining current distribution in an ac HTS cable-proximity effect 被引量：6

A nontrivial factor in determining current distribution in an ac HTS cable-proximity effect

导出

摘要 A superconductor has zero resistance at the superconducting state. This unique property creates many exceptional phenomena, of which some are known and the others are not. Our experiments with multilayer high temperature superconductor (HTS) cable samples revealed a new phenomenon that alternating current had a tendency to flow in the inner and outer layers of the cables. We attribute the cause of this phenomenon to the electromagnetic interaction in an infinite electrical conductivity medium and term it "super-proximity-effect". This effect will greatly affect the performance of a multilayer superconducting cable and other superconducting devices which are involved with alternating current transportation. A superconductor has zero resistance at the superconducting state. This unique property creates many exceptional phenomena, of which some are known and the others are not. Our experiments with multilayer high temperature superconductor (HTS) cable samples revealed a new phenomenon that alternating current had a tendency to flow in the inner and outer layers of the cables. We attribute the cause of this phenomenon to the electromagnetic interaction in an infinite electrical conductivity medium and term it "super-proximity-effect". This effect will greatly affect the performance of a multilayer superconducting cable and other superconducting devices which are involved with alternating current transportation.

作者 XIN Ying,GONG WeiZhi & ZHANG JingYin Innopower Superconductor Cable Co.,Ltd.,7 E.Rongchang Rd.,Longsheng Industrial Park,Beijing Economic & Technological Development Area,Beijing 100176,China

出处《Science China(Technological Sciences)》 SCIE EI CAS 2010年第4期922-928,共7页 中国科学（技术科学英文版）

基金 supported by the Chinese Ministry of Science and Technology (Grant Nos 2002AA306154, 2004AA306110) the Beijing Municipal Science and Technology Commission (Grant No H020420010210) the Yunnan Provincial Science and Technology Department (Grant No 2003BABCA05A041)

关键词 HTS cables proximity-effect SUPERCONDUCTIVITY ELECTROMAGNETIC interaction HTS cables proximity-effect superconductivity electromagnetic interaction

分类号 TM248 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献4

1赵臻,邱捷,王曙鸿,宫瑞磊.高温超导交流电缆电流分布及结构优化的研究[J].西安交通大学学报,2004,38(4):352-356. 被引量：16
2戴训江,李敬东,唐跃进,程时杰.高温超导电缆的磁场计算[J].华中科技大学学报（自然科学版）,2003,31(12):38-40. 被引量：7
3林良真,肖立业.高温超导输电电缆的现状与发展[J].电力设备,2007,8(1):1-4. 被引量：33
4李健,林良真.高温超导交流输电电缆导体层电流分布研究[J].电工电能新技术,2000,19(2):7-10. 被引量：12

二级参考文献23

1林良真.我国超导技术研究进展及展望[J].电工技术学报,2005,20(1):1-7. 被引量：56
2[1]Tominaka T, Okamura M, Katayama T. Analytical field calculation of helical dipole magnets for RHIC. Proceedings of the 1997 Particle Accelerator Conference, 1997, 3 437～3 439
3[2]Lee Ji-kwang, Cha Gueesoo. Magnetization loss calculation in superconducting power transmission cable Cryogenics, 2001, 41: 157～161
4[3]Kruger S. Loss and inductance investigation in a 4-layer superconducting prototype cable conductor. IEEE Trans. AS, 1999, 9(2): 833～836
5[3]Masuda T,Yumura H,Watanabe M,et al.High-temperature superconducting cable technology and development trends.SEI Technical Review,2005,(59):7 ～ 13.
6[4]Lin Y B,Gao Z Y,Ning Z,et al.Development and testing of 10.5 kV/1.5 kA HTS power cable.Proceedings of ICEC 20,Beijing,2004,London:Elsevier,649 ～ 652.
7[5]Fan Y F,Gong L H,Xu X D,et al.Test results and analysis of cryogenic system for cooling HTS cables and the next stage plan.Proceedings of ICEC 20,Beijing,2004,London:Elsevier,71 ～ 74.
8[6]Balachandran U.Recent advances in development of high Tc superconductors for electric power applications.ISTEC Journal,1998,11(1):35 ～42.
9[7]Hassenzahl W V.Applications of superconductivity to electric power systems.IEEE Power Engineering Review,2000,20 (5):4 ～ 7.
10[8]Sato K,Isojima S,Watanabe M,et al.The lastest development of high Tc superconducting cable.Proceedings of ICEC 19,Grenoble,2002,225 ～ 232.

共引文献55

1于立佳,王银顺,朱承治,王腾岩,乔玉凯.±100kV/1kA能源管道双极直流高温超导电缆导体设计[J].低温与超导,2020,0(2):37-43. 被引量：5
2李继春,张立永,曹雨军,夏芳敏,叶新羽,朱红亮.冷绝缘高温超导电缆循环冷却系统设计及运行分析[J].低温与超导,2020,0(2):7-11. 被引量：8
3史海青.超导[J].科技风,2010(14).
4郑万杰.高温超导电缆中各层导体电流分布及其影响因素分析[J].广东输电与变电技术,2006(6):1-5. 被引量：1
5张俊莲,金建勋.高温超导电缆技术探讨与应用[J].华中电力,2006,19(6):16-20. 被引量：9
6刘新颖,王曙鸿,邱捷.改进粒子群算法及其在超导电缆参数优化中的应用[J].西安交通大学学报,2007,41(2):219-222. 被引量：5
7李凤华,樊占国,杨中东,徐克.Ag包套法制备YBaCuO带材及其后处理研究[J].功能材料,2007,38(A02):471-473.
8张俊莲,金建勋.直流输电高温超导电缆电磁特性分析与仿真[J].电线电缆,2008(2):20-23. 被引量：3
9任丽,唐跃进,邹涵,胡毅,蔡伟,李敬东,程时杰.超导电缆的性能检测方法研究[J].低温与超导,2008,36(5):21-26. 被引量：3
10信赢,龚伟志,张敬因.影响多层交流超导电缆电流分布不可忽略的因素-邻近效应[J].中国科学：技术科学,2010,40(7):786-793. 被引量：5

同被引文献100

1李胜兵,方杰,危贤光,方晓红,曹春建,师晓岩,黄晓敢.白鹤滩水电站1000 MW机组关键技术指标研究[J].人民长江,2021,52(S01):362-365. 被引量：2
2HE JinLiang,ZHANG XueWei,DONG Lin,ZENG Rong,LIU ZeHong.Fractal model of lightning channel for simulating lightning strikes to transmission lines[J].Science China(Technological Sciences),2009,52(11):3135-3141. 被引量：12
3JIANG John N.Novel approach for evaluation of service reliability for electricity customers[J].Science China(Technological Sciences),2009,52(9):2585-2590. 被引量：1
4YANG Yu,WANG ZanJi.Wide band modeling of large power transformer windings for very fast transient overvoltage (VFTO) analysis[J].Science China(Technological Sciences),2009,52(9):2597-2604. 被引量：4
5XU ZhaoDong,SHI BenQiang,WU KeYi,ZENG Xiao.Vertical shaking table tests on the structure with viscoelastic multi-dimensional earthquake isolation and mitigation devices[J].Science China(Technological Sciences),2009,52(10):2869-2876. 被引量：4
6HE GuangYu,SUN YingYun,RUAN QianTu,WANG Wei,DONG ShuFeng.Modern power systems control centers:From EMS to AEMS[J].Science China(Technological Sciences),2009,52(2):413-419. 被引量：5
7ZhenXiang Han, QuanYuan Jiang,YiJia Cao.Sequential feasible optimal power flow in power systems[J].Science China(Technological Sciences),2009,52(2):429-435. 被引量：1
8DUAN XianZhong,WEN JinYu,CHENG ShiJie.Bifurcation analysis for an SMIB power system with series capacitor compensation associated with sub-synchronous resonance[J].Science China(Technological Sciences),2009,52(2):436-441. 被引量：3
9ZHAO ZhengMing,BAI Hua,YUAN LiQiang.Analysis of cutting-edge techniques in the high voltage and high power adjustable speed drive systems[J].Science China(Technological Sciences),2009,52(2):442-449. 被引量：3
10HE JinLiang,HU Jun,MENG BoWen,ZHANG Bo,ZHU Bin,CHEN ShuiMing,ZENG Rong.Requirement of ultra-high voltage GIS arrester to voltage gradient of metal-oxide varistor[J].Science China(Technological Sciences),2009,52(2):450-455. 被引量：10

引证文献6

1Jia Wang,Qiang Zhang,Bin Cui,Jin Guo,YongBo Bian,XiaoFeng He,ChunGuang Li,XueQiang Zhang,Hong Li,WuXia Li,et al..An L-band HTS duplexer with improved performance[J].Chinese Science Bulletin,2010,55(31):3527-3532. 被引量：2
2AN Mei.Some new results of electric power science[J].Science China(Technological Sciences),2011,54(7):1940-1942. 被引量：2
3MEI ShengWei,CHEN LaiJun.Research focuses and advance technologies of smart grid in recent years[J].Chinese Science Bulletin,2012,57(22):2879-2886. 被引量：3
4TANG Mei,GUO YingQing,YUAN Jie,WEI Qin,SUN ShuJun,ZHOU Wei,ZHANG Yue.Review of some recent progress on materials science researches in China[J].Science China Chemistry,2012,55(12):2497-2502. 被引量：5
5何清,何杰,周世平,金涛,伍科,王利琴,任丽,李晓群.高温超导电缆研究进展综述[J].低温与超导,2013,41(5):31-34. 被引量：9
6张馨丹,王银顺,李冠华,王佳雯,鲁旭臣.700MVA/20kV单相高载流低损耗高温超导电缆设计[J].低温与超导,2022,50(12):6-13. 被引量：1

二级引证文献22

1曲景影,金梦彤,刘勇,王松超,朴尹成,何明,张旭.C波段卫星通信中高温超导双工器的研制[J].低温与超导,2012,40(9):51-54.
2SHI TingNa,WANG Jian,ZHANG Ce,XIA ChangLiang.Direct power control for three-level PWM rectifier based on hysteresis strategy[J].Science China(Technological Sciences),2012,55(11):3019-3028. 被引量：5
3HE ShiEn,SUONAN JaLe,KANG XiaoNing,JIAO ZaiBin.Fault component integrated impedance-based pilot protection scheme for EHV/UHV transmission line with thyristor controlled series capacitor(TCSC) and controllable shunt reactor(CSR)[J].Science China(Technological Sciences),2013,56(2):342-350. 被引量：1
4逯康康,方进,黄晓华,申政,宋文娟,郑晓东,刘斌,周伟.高温超导电缆终端预制式应力锥缺陷的研究分析[J].低温与超导,2014,42(4):31-35. 被引量：6
5高永吉.超导材料的应用及前景展望[J].科教导刊（电子版）,2014(7):134-134.
6FAN LingCong,XU Jian,SHI Ying,XIE JianJun,LEI Fang.Lower temperature synthesis of cerium-doped polycrystalline lutetium pyrosilicate powders by a novel sol-gel processing[J].Science China(Technological Sciences),2014,57(8):1610-1615. 被引量：3
7夏芳敏,郭慧,林中山,王醒东.二代高温超导电缆在电网中的应用前景[J].电工材料,2014(4):24-27. 被引量：3
8SHEN JunHai,CHEN KeYu,LI LiangChao,DING Yan,LI JuanBi,KONG WeiQiu.Fabrication of Z-type barium ferrite/silica composites with enhanced microwave absorption[J].Science China(Technological Sciences),2014,57(9):1858-1864.
9CHENG XingGuo,LI FuAn,ZHANG ZongYang,LIU Sheng.Design, optimization, and measurement of closed-loop Hall effect current sensor[J].Science China(Technological Sciences),2014,57(9):1877-1882. 被引量：3
10Yuming Gong,Gang Liang,Lifeng Zhao,Yong Zhang,Yong Zhao,Xuyong Chen.Magnetic levitation performance of high-temperature superconductor over three magnetic hills of permanent magnet guideway with iron shims of different thicknesses[J].Journal of Modern Transportation,2014,22(3):187-193.

1张建明.新型HTS集成电路温度传感器[J].电子产品维修与制作,1997(3):33-34.
2GUAN XiaoJin1,2, WANG YinShun1 & ZHOU WeiWei3 1 Key Laboratory of HV and EMC Beijing, North China Electric Power University, Beijing 102206, China,2 Department of Physics, Baoding University, Baoding 071000, China,3 Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing 100190, China.Current distribution and stability of LTS/HTS hybrid superconducting conductors[J].Science China(Technological Sciences),2010,53(7):2000-2007. 被引量：6
3Gingold Harry,Gera Dinesh West Virginia University U. S. A.MODELING A SOLID BOUNDARY AS A FLUID OF INFINITE VISCOSITY[J].Chinese Journal of Mechanical Engineering,2000,13(1):2-9.
4Abbas A.Essa XU Qin jun XU Ke xi ZHOU Shi ping BAO Jia shan (College of Sciences, Shanghai University).TlBaCaCuO High Temperature Superconducting Bolometer[J].Advances in Manufacturing,1999(4):339-341.
5Reemergence of superconductivity at 48K in Compressed Iron Selenide Based Superconductors[J].Science Foundation in China,2012,20(1):22-23.
6张炳泉,毕凤飞.液晶空间光调制器在阿达玛变换光谱仪中的应用研究——快速精确的解码方法[J].光学学报,1992,12(7):602-605. 被引量：1
7毕凤飞.液晶空间光调制器在HTS中的应用研究——快速精确的解码方法[J].盐城工学院学报（自然科学版）,2003,16(1):35-37.
8李慧敏,李艳,何勇.Dynamic Response during the Online Compensation of Misalignment Based on Auxiliary Electromagnetic Support[J].Journal of Donghua University(English Edition),2008,25(4):395-399.
9WANG YinShun,GUAN XiaoJin,ZHANG HuiYuan,LIU HongWei.Progress in inhomogeneity of critical current and index n value measurements on HTS tapes using contact-free method[J].Science China(Technological Sciences),2010,53(8):2239-2246. 被引量：8
10经典联网计时器西铁城Proximity手表[J].数字时代,2012(11):18-18.

Science China(Technological Sciences)

2010年第4期

浏览历史

内容加载中请稍等...