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BSCCO超导带材的工艺要点与应用 被引量:3

Technology Essentials and Application of BSCCO Superconducting Tape
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摘要 高温超导材料的发现,推进了超导技术的实用化。作为典型的高温超导材料,铋系(BSCCO)超导带材目前已在超导电缆、超导限流器和超导储能等领域实现商用。粉末套管法是制备BSCCO超导带材最常用的方法,主要工艺步骤包括装粉、拉拔、轧制和热处理等。本文介绍了粉末套管法的工艺,重点介绍了各工艺步骤中的关键点,阐述了超导带材在超导限流器和超导储能系统中的应用,提出了BSCCO超导带材未来的发展方向。 The discovery of high temperature superconducting(HTS) materials promotes the practical application of superconducting technology. As typical HTS materials, Bi-superconducting tapes(BSCCO) have achieved the commercialization and been applied in superconducting cables, superconducting fault current limiter(SFCL) and superconducting magnetic energy storage(SMES). Powder in tube(PIT) is the most commonly method, which includes some important processing steps such as powder-filling, drawing, rolling and heat treatment. PIT is introduced in this paper, especially the key point in each process step. The application of superconducting tapes in SFCL and SMES is expounded. Finally, the future development direction of BSCCO superconductor tape is indicated.
作者 王醒东
机构地区 富通集团有限公司 浙江省光纤制备技术工程技术研究中心
出处 《电工材料》 CAS 2014年第1期33-35,共3页 Electrical Engineering Materials
关键词 铋锶钙铜氧 超导带材 粉末套管法 应用 BSCCO superconducting tape powder in tube application
分类号 TM26 [一般工业技术—材料科学与工程]
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参考文献9

  • 1王醒东.商用超导材料技术概况[J].新材料产业,2013(2):51-55. 被引量:7
  • 2王醒东,张立永,孔梅梅.超导材料的发展及应用[J].广州化工,2011,39(22):8-11. 被引量:2
  • 3Bhargava A, Yamashita T, Mackinnon I. Manufacture of SpecificBSCCO Powder Compositions by Co-precipitation[J].Physica C:Superconductivity,1995,247(3-4):385-392.
  • 4Ko J W, Yoo J M, Kim Y K, et al. Effect of Starting PrecursorPowders on Microstructural Development and CriticalCurrent Density Properties of BSCCO 2223 Tapes[J].Cryogenics,2003,43(10-11):549-553.
  • 5Yurchenko I A, Alekseev A F, Yurchenko D O, et al.Intensificationof Synthesis and Examination of Technological ParametersInfluence on the Properties and Structure ofBi-(Pb)-Sr-Cu-Ca-O Ceramics[J].Physica C: Superconductivity,2003,384(1-2):111-124.
  • 6Nakamura Y, Shioiri T, Kurihara C, et al. Effect of PhaseAssemblage of Precursor on the Fabrication Process andProperties of Bi2223 Tape Sheathed With Ag-alloy[J].PhysicaC:Superconductivity,2008,468(15-20):1760-1763.
  • 7Shin H, Dizon J, Kim K, et al. Mechanical and TransportProperties of Ag Alloy/Bi-2223 Superconducting Tapes UnderAxial Fatigue Loading[J].Physica C:Superconductivity,2005,426-431(Part 2):1188-1193.
  • 8周廉,甘子钊.中国高温超导材料及应用发展战略研究[M].北京:化学工业出版社,2008.
  • 9Naoki AYAI, Masashi KIKUCHI, Kouhei YAMAZAKI, etal.Achievement of High-Temperature Superconducting WireWith Critical Current Exceeding 200A[J].Sumitomo ElectricTechnical Review,2006,169:103-108.王醒东:BSCCO超导带材的工艺要点与应用35.

二级参考文献22

  • 1K.P. Thakur, Z. Jiang, M.P. Staines, et al. Current carrying capa- bility of HTS Roebel cable [ J]. Physica C : Superconductivity, 2011, 47(1 -2) : 42 -47.
  • 2Pascal Tixador. Development of superconducting power devices in Europe [J]. Physica C: Superconductivity, 2010, 470(20): 971 -979.
  • 3John R. Kirtley. Probing the order parameter symmetry in the cuprate high temperature supe - rconductors by SQUID microscopy [ J ]. Comptes Rendus Physique, 2011, 12(5 -6) : 436 -445.
  • 4T. Maurice Rice. Chapter Seven - The Future of Superconductivity Viewed Through a Cloudy Crystal Ball [ J]. Contemporary Concepts of Condensed Matter Science, 2011,4 : 235 - 251.
  • 5F. Feng, T. M. Qu. c, et al. Comparative study on the critical cur- rent performance of Bi - 2223/Ag and YBCO wires in low magnetic fields at liquid nitrogen temperature[ J]. Physica C : Superconductivity, 2011,471(9 -10) : 293 -296.
  • 6Naoki AYAI, Masashi KIKUCHI, Kouhei YAMAZAKI, et al. Achieve- ment of High - Temperature Superconducting Wire with Critical Current Exceeding 200 A [ J ]. Sumitomo Electric Technical Review, 2006, 169 : 103 - 108.
  • 7Khaled M. Elsabawy. Superconductivity, structure visualization, mechanical strength promotion and Raman spectra of hafnium - doped - 123 - YBCO synthesized via urea precursor route[J]. Cryogenics, 2011, 51(8): 452-459.
  • 8R. Hott, R. Kleiner, T. Wolf. Superconducting Materials - a Topical Overview" in "Frontiers in Superconducting Materials", Springer Verlag, Berlin, 2004.
  • 9M. Ranot, K. Cho, W.K. Seong. Effects of B2 H6 flow rate and depo- sition time on superconducting properties of MgB2/Hastelloy tapes[ J ]. Physica C : Superconductivity, 2011,471 ( 19 - 20 ) : 582 - 585.
  • 10K. Yonekura, T. Fujiyoshi, T. Sueyoshi. Flux pinning properties of MgB2 thin films on A1 tape substrates deposited by electron beam evapo- ration [ J ]. Physica C : Superconductivity, In Press, 2011.

共引文献7

同被引文献24

  • 1闻海虎.新型高温超导材料研究进展[J].材料研究学报,2015,29(4):241-254. 被引量:10
  • 2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:58
  • 3朱志芹,赵祥,王银顺,惠东,韩军杰,李晓航.Bi-2223高温超导带材焊接接头电阻和过电流冲击性能实验研究[J].低温物理学报,2006,28(2):185-190. 被引量:6
  • 4Delft D V. History and Significance of the Discovery of Superconductivity by Kamerlingh Onnes in 1911[J]. Physica C: Superconductivity,2012,479(9):30-35.
  • 5Hwang S M, Choi J H, Park E C, et al. Development of Carbon-doped ex Situ MgB2 Wire by Mechanical Alloying [J]. Physica C: Superconductivity,2009,469(15):1523-1526.
  • 6Goodenough J B. High Temperature Superconductors[J]. Mo- lecular Sciences and Chemical Engineering, 2013:291-324.
  • 7Suzuki K, Usui H, Iimura S, et al. Theoretical Analysis on the Band Structure Variance of the Electron Doped 1111 Iron-based Superconductors[J].Physics Procedia,2014,58(58): 38-41.
  • 8Diko P, Antal V, Kave~ansky V, et al. Microstructure and Phase Transformations in FeSe Superconductor[J]. Physica C: Superconductivity,2012,476(6):29-31.
  • 9Ayai N, Kikuchi M, Yamazaki K, et al. Achievement of High-Temperature Superconducting Wire with Critical Current Exceeding 200A[J]. Sumitomo Electric Technical Review,2006,63:58-64.
  • 10郭志超,索红莉,刘志勇,刘敏,马麟.超导临界电流测量方法与原理[J].功能材料,2010,41(12):2041-2044. 被引量:17

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电工材料
2014年 第1期

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