论文信息 - AC loss measurement of 46 kA-13T Nb/sub 3/Sn conductor for ITER

AC loss measurement of 46 kA-13T Nb/sub 3/Sn conductor for ITER

AC losses of Nb/sub 3/Sn conductor samples with various void fractions for the ITER Central Solenoid Model Coil (CSMC) were measured by using calorimetric and magnetization techniques. The CSMC is designed to generate the magnetic field of 13 T at the operating current of 46 kA. The conductor consists of the multi-stage cable, having 1152 Nb/sub 3/Sn strands, and Incoloy 908 square jacket with circular hole. The strands are coated by chrome plating with 2 /spl mu/m layer. The last sub-cables are wrapped with Inconel tape, having high electric resistivity, to reduce the coupling current loss. The optimum void fraction for pulse coils is obtained from the relation between the coupling time constant and the void fraction. It is indicated that the sub-cable wrapping is very effective in limiting the coupling current between the sub-cables, as expected. The AC losses of the CS Insert were measured in various operating modes. From these obtained results, the validity of conductor design is demonstrated.

[1] R. J. Thome,et al. Magnet program overview for the International Thermonuclear Test Reactor , 1994 .

[2] Osamu Motojima,et al. Extra AC losses for a CICC coil due to the non-uniform current distribution in the cable , 1998 .

[3] Y. Nunoya,et al. Completion of CS insert fabrication , 1999, IEEE Transactions on Applied Superconductivity.

[4] G. Ries,et al. AC-losses in multifilamentary superconductors at technical frequencies , 1977 .

[5] M. Sugimoto,et al. Completion of the ITER CS model coil-outer module fabrication , 2000, IEEE Transactions on Applied Superconductivity.

[6] Takashi Kato,et al. Design and fabrication of superconducting cables for ITER central solenoid model coil , 1996 .

[7] Neil Mitchell,et al. Conductor fabrication for the ITER model coils , 1996 .

[8] T. Satow,et al. AC loss performance of the 100 kWh SMES model coil , 2000, IEEE Transactions on Applied Superconductivity.