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AC losses in superconducting coils
Author(s) -
Akita Shirabe,
Ishikawa Tadao,
Tanaka Toshikatsu
Publication year - 1992
Publication title -
electrical engineering in japan
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.136
H-Index - 28
eISSN - 1520-6416
pISSN - 0424-7760
DOI - 10.1002/eej.4391120405
Subject(s) - materials science , electromagnetic coil , superconductivity , superconducting magnetic energy storage , transformer , electrical conductor , superconducting electric machine , alternating current , magnetic field , liquid helium , electrical equipment , superconducting magnet , electrical engineering , nuclear magnetic resonance , composite material , condensed matter physics , helium , engineering , voltage , physics , atomic physics , quantum mechanics
AC superconducting wire is being developed for such electrical equipment as superconducting transformers and superconducting generators. AC loss reduction is of primary concern in the development of such high‐efficiency equipment. In reducing ac losses, it is necessary to develop assessment methods for ac loss in test samples which have shapes similar to the end‐product equipment. This paper describes a least‐square calculation of ac losses of superconducting wire as a function of frequency and magnetic field strength measured in test coils. Two sample solenoid coils were made to test the influence of different capacities and winding methods on ac losses in ac superconducting coils with rated capacities of 500 kVA and 20 kVA, and impregnated (epoxy resin) and nonimpregnated windings. The ac losses in the superconducting coils were measured by a calorimetric method using the evaporating rates of liquid helium. Estimated ac losses in the superconducting wire of the two coils were compared with Joule losses of copper conductors at ambient temperature. As a result of this comparison, a low‐loss ac superconducting wire winding can be made for electrical equipment rather than employing conventional copper winding when used under low magnetic fields under 0.5 T.