High Temperature Superconducting Magnetic Levitation

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Maglev books and reviews Ë 85

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[19] Brandt AH. Science. 1989;243:349.
[20] Weh H. Magnetic levitation technology and its development potential. Proceeding of
International Conference on Maglev ’89, July 7–11, 1989, Yokohama, Japan, IEE Japan, p 1–9.
[21] Song HH, Wang JS, Wang SY, Ren ZY, Wang XR, de Haas O, et al. Studies of YBCO electroma-
gnetic properties for high-temperature superconductor Maglev technology. In: Matins BP,
editor. New topics in superconductivity research. New York: Nova Science Publishers; 2006.
p. 107–156.
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2006;42:1917–1925.
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[24] Hull JR. Flywheels on a roll. IEEE Spectrum. 1997;34:20–25.
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[27] Hull JR. Superconducting bearings. Supercond Sci Technol. 2000;13:1.
[28] Hull JR. Using high-temperature superconductors for levitation applications. JOM. 1999;
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high velocity transport systems. Recent Adv Eng Sci. 1970;5:159–182.
[30] Powell JR, Danby GR. Maglev: The new mode of transport for the 21st century. 21st Century
Science and Technology. 2003;16:43–57.
[31] Powell JR, Danby GR, Jordan J, Morena J, Wagner T, editor. A national Maglev network for the
U.S. – design and capabilities. Proceeding of the 20th International Conference on Magnetic
Levitated Systems and Linear Drivers; 2008 Dec 15–18; California, USA.
[32] Wang JS, Wang SY. Applications of superconducting technology. Chengdu: University of
Science and Technology Chengdu Press; 1995.
[33] Wang JS. editor. Proceedings of International Workshop on HTS Maglev; 2002 June 25–27;
Chengdu: China.
[34] Wang JS, Wang SY. Synthesis of bulk superconductors and their properties on permanent
magnet guideway. In: Narlikar A, editor. Frontiers in superconducting materials, New York:
Springer; 2005. p. 885–912.
[35] Wang JS, Wang SY. High temperature superconducting Maglev measurement system. In: Kr
Sharma M, editor. Advances in measurement systems. InTech; 2010. p. 51–80.
[36] Wang JS. Past, present and future R&D of HTS Maglev in China. In: Proceedings of the 21st
International Conference on Magnetically Levitated Systems and Linear Drives ; 2011 October
10–13, Daejeon, Korea.
[37] Wang JS, Wang SY. High temperature superconductive Maglev vehicle. In: Fan JD, editor.
Endless Quests. Peking: Peking University Press; 2014.
[38] Glatzel K, Khurdok G, Rogg D. The development of the magnetically suspended transportation
system in the Federal Republic of Germany. IEEE Trans on Vehicular Technology. 1980;29:3–17.
[39] Strnat KJ. Modern permanent magnets for applications in electro-technology. Proceedings of
the IEEE. 1990;78:923–946.
[40] Sawada K. Outlook of the superconducting Maglev. Proceedings of the IEEE. 2009;97:
1881–1885.
[41] Sinha K. Electromagnetic suspension dynamics & control. London UK: Peter Peregrinus;
1987;53–57.

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