DocumentCode
1481666
Title
Analysis and measurement of AC transport current loss in BSCCO tape in external magnetic field
Author
Fukui, Satoshi ; Ikeda, Makoto ; Sano, Tomomi
Author_Institution
Dept. of Eng., Niigata Univ.
Volume
11
Issue
1
fYear
2001
fDate
3/1/2001 12:00:00 AM
Firstpage
2212
Lastpage
2215
Abstract
A numerical model to calculate current distribution and AC loss in a high temperature superconducting tape carrying AC transport current exposed to an external magnetic field was developed. The model considers the electric field and current density relation and the shape of wire. The authors measured the AC transport current losses in a conventional Bi2223/Ag multifilamentary tape in a DC external magnetic field and the results were compared with the numerically calculated AC losses. The measured AC transport current losses increase as the DC external field increases. It is also shown that the measured losses per cycle decrease with increasing frequency. These characteristics cannot be explained by the critical state model. The numerical losses by their model reasonably agree with the measured data. The transport loss characteristics under the DC field and their dependence on the frequency are explained by the numerically calculated current distribution in the wire
Keywords
bismuth compounds; calcium compounds; copper compounds; current distribution; electric current measurement; electric fields; lead; lead compounds; loss measurement; magnetic fields; multifilamentary superconductors; numerical analysis; strontium compounds; superconducting cables; superconducting tapes; (BiPb)2Sr2Ca2Cu3O 8-Ag; (BiPb)2Sr2Ca2Cu3O 8-Ag multifilamentary tape; AC transport current loss; AC transport current losses measurement; BSCCO tape; current density relation; current distribution; electric field; external magnetic field; frequency; high temperature superconducting tape; numerical model; transport loss characteristics; wire shape; Bismuth compounds; Current distribution; Current measurement; Frequency; Loss measurement; Magnetic analysis; Magnetic field measurement; Numerical models; Superconducting films; Temperature distribution;
fLanguage
English
Journal_Title
Applied Superconductivity, IEEE Transactions on
Publisher
ieee
ISSN
1051-8223
Type
jour
DOI
10.1109/77.920298
Filename
920298
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