DocumentCode
1104229
Title
Development of 100 kVA AC superconducting coil using NbTi cables with a CuSi alloy matrix
Author
Kasahara, Hirofumi ; Akita, Shirabe ; Torii, Shinji ; Sugimoto, Masahiro ; Matsumoto, Kaname ; Tanaka, Yasuzou ; Tachikawa, Kyoji
Author_Institution
Central Res. Inst. of Electr. Power Ind., Tokyo, Japan
Volume
32
Issue
4
fYear
1996
fDate
7/1/1996 12:00:00 AM
Firstpage
2751
Lastpage
2755
Abstract
For implementation of AC superconducting equipment, it is imperative to develop low loss cables having highly stable characteristics. Here, newly developed NbTi superconducting cables using a CuSi alloy matrix are of low loss and are very promising as cables for practical application. However, since the CuSi alloy is a new material as a matrix for NbTi superconducting cables, many unknown factors as regards to optimum conditions for the manufacture of long cables, as well as superconducting characteristics are involved. For this new superconducting cable, a long strand (km class) was manufactured as a step for practical application, and a primary twisted cable was fabricated. Using this cable, a coil of the 100 kVA class was fabricated for trial, and its performance characteristic with transport current was evaluated. This coil had no training phenomenon and had a high stabilities. Furthermore, it permitted full AC current transmission of up to DCIc. Upon analysis of the coil loss, the hysteresis loss was smaller than coupling loss, and there was little increase of loss due to the current flow to the coil. Consequently, by using CuSi alloy matrix superconducting cables, it was possible to provide an AC coil of low loss and high stability, and the present cable was found to be promising as a new AC superconducting cable in the future
Keywords
copper alloys; niobium alloys; silicon alloys; superconducting cables; superconducting coils; superconducting materials; thermal stability; titanium alloys; 100 kVA; 100 kVA AC superconducting coil; AC coil; CuSi; CuSi alloy matrix; NbTi; NbTi cables; full AC current transmission; high stability; highly stable characteristics; long cables; low loss; low loss cables; Cable insulation; Hysteresis; Manufacturing; Niobium compounds; Stability; Superconducting cables; Superconducting coils; Superconducting filaments and wires; Superconducting materials; Titanium compounds;
fLanguage
English
Journal_Title
Magnetics, IEEE Transactions on
Publisher
ieee
ISSN
0018-9464
Type
jour
DOI
10.1109/20.511444
Filename
511444
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