ITER TF线圈电磁特性分析
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摘要
ITER磁体由6组中心螺管线圈、18组纵场线圈、6组极向场以及18组校正场线圈组成。作为ITER线圈最基本的特性,线圈电磁场是线圈超导和热工水力性能分析的基础。利用有限元方法对ITER TF线圈在正常工作状态下以及各种故障态下的电磁行为进行分析。
The ITER magnet system was composed of 6 central solenoid coils,18 Toroidal field coils,6 poloidal field coils and 18 correction coils.The analysis of the electromagnetic field was of great importance to evaluate the superconducting and thermal-hydraulic performance of the ITER coils.The electromagnetic field of the ITER TF coils was analyzed under the normal and fault conditions by using the finite element methods.
The ITER magnet system was composed of 6 central solenoid coils,18 Toroidal field coils,6 poloidal field coils and 18 correction coils.The analysis of the electromagnetic field was of great importance to evaluate the superconducting and thermal-hydraulic performance of the ITER coils.The electromagnetic field of the ITER TF coils was analyzed under the normal and fault conditions by using the finite element methods.
引文
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[2]Mitchell N,Bessette D,Gallix R,et al.The ITER magnet system[J].IEEE Transactions on Applied Superconductivity,2008,18(2):435-440.
[3]Sborchia C,Oliva A B,Boutboul T,et al.The ITER magnet systems:Progress on construction[J].Nuclear Fusion,2013,54(1):013006.
[4]Ren Y,Zhu J,Gao X,et al.Electromagnetic,mechanical and thermal performance analysis of the CFETR magnet system[J].Nuclear Fusion,2015,55(9):093002.
[5]Ren Y,Kuang G,Chen W,et al.Quench analysis of the hybrid-magnet superconducting outsert[J].IEEE Transactions on Applied Superconductivity,2013,23(6):19-25.
[6]Ren Y,Kuang G,Chen W,et al.Quenchsimulation of the hybrid magnet superconducting outsert being built in China[J].Journal of Fusion Energy,2015,34(5):1146-1150.
[7]ITER Design Description Document Magnets:ITER_D_2MVZNX v2.2-2.TF Coils and Structures[Z].Sep,2009.
[8]Bareyt B.Annex 6A:Assessment of the TF coil circuit behavior during normal and fault conditions ITER Design Description Document DDD 11[Z].2001.
[9]Ren Y.Magnetic force calculation between misaligned coils for a superconducting magnet[J].IEEE Transactions on Applied Superconductivity,2010,20(6):2350-2353.
[10]Ren Y,Tan Y,Wang F,et al.Thermal-hydraulic analysis of a model coil for 40-T hybrid magnet superconducting outsert[J].IEEE Transactions on Applied Superconductivity,2012,22(2):4900105-4900105.
[2]Mitchell N,Bessette D,Gallix R,et al.The ITER magnet system[J].IEEE Transactions on Applied Superconductivity,2008,18(2):435-440.
[3]Sborchia C,Oliva A B,Boutboul T,et al.The ITER magnet systems:Progress on construction[J].Nuclear Fusion,2013,54(1):013006.
[4]Ren Y,Zhu J,Gao X,et al.Electromagnetic,mechanical and thermal performance analysis of the CFETR magnet system[J].Nuclear Fusion,2015,55(9):093002.
[5]Ren Y,Kuang G,Chen W,et al.Quench analysis of the hybrid-magnet superconducting outsert[J].IEEE Transactions on Applied Superconductivity,2013,23(6):19-25.
[6]Ren Y,Kuang G,Chen W,et al.Quenchsimulation of the hybrid magnet superconducting outsert being built in China[J].Journal of Fusion Energy,2015,34(5):1146-1150.
[7]ITER Design Description Document Magnets:ITER_D_2MVZNX v2.2-2.TF Coils and Structures[Z].Sep,2009.
[8]Bareyt B.Annex 6A:Assessment of the TF coil circuit behavior during normal and fault conditions ITER Design Description Document DDD 11[Z].2001.
[9]Ren Y.Magnetic force calculation between misaligned coils for a superconducting magnet[J].IEEE Transactions on Applied Superconductivity,2010,20(6):2350-2353.
[10]Ren Y,Tan Y,Wang F,et al.Thermal-hydraulic analysis of a model coil for 40-T hybrid magnet superconducting outsert[J].IEEE Transactions on Applied Superconductivity,2012,22(2):4900105-4900105.