AC loss calculation in REBCO coils or stacks by solving the equation of motion for current using an integration approach

被引:22
作者
Lai, Lingfeng [1 ]
Gu, Chen [2 ]
机构
[1] Eastforce Superconducting Technol Co Ltd, Beijing 100085, Peoples R China
[2] Tsinghua Univ, Teaching Ctr Expt Phys, Beijing 100084, Peoples R China
来源
SUPERCONDUCTOR SCIENCE & TECHNOLOGY | 2021年 / 34卷 / 01期
基金
中国国家自然科学基金;
关键词
YBCO; AC loss; integral method; J model; FINITE THICKNESS; SUPERCONDUCTORS; COMPUTATION;
D O I
10.1088/1361-6668/abc567
中图分类号
O59 [应用物理学];
学科分类号
摘要
The flux motion and its collective behaviour known as AC loss is the basic characteristic of high temperature superconducting (HTS) materials and controls the economic efficiency, stability and magnetic field uniformity of superconducting equipment. In so far, we have no method to calculate the AC loss of HTS devices in an efficient way. Normally, it will take days to simulate AC loss of HTS coils even with moderate number of turns. In this paper, we surprisingly found that an integral method is remarkably efficient in calculating AC loss of the coils in large scale. By comparing with the fastest method at present, the integral method is proved to be 4.4 times faster than the present one. We give the calculation details and discuss why this method has an advantage in calculating AC loss of the coil with a large number of turns.
引用
收藏
页数:7
相关论文
共 21 条
[1]   Numerical modelings of superconducting wires for AC loss calculations [J].
Amemiya, N ;
Murasawa, S ;
Banno, N ;
Miyamoto, K .
PHYSICA C, 1998, 310 (1-4) :16-29
[2]   Integral equations for the current density in thin conductors and their solution by the finite-element method [J].
Brambilla, Roberto ;
Grilli, Francesco ;
Martini, Luciano ;
Sirois, Frederic .
SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 2008, 21 (10)
[3]   Superconductors of finite thickness in a perpendicular magnetic field: Strips and slabs [J].
Brandt, EH .
PHYSICAL REVIEW B, 1996, 54 (06) :4246-4264
[4]   An Introduction to Numerical Methods in Superconductors [J].
Campbell, A. M. .
JOURNAL OF SUPERCONDUCTIVITY AND NOVEL MAGNETISM, 2011, 24 (1-2) :27-33
[5]   Numerical Modeling of HTS Applications [J].
Grilli, Francesco .
IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 2016, 26 (03)
[6]   AC Losses in HTS Tapes and Devices With Transport Current Solved Through the Resistivity-Adaption Algorithm [J].
Gu, Chen ;
Qu, Timing ;
Li, Xiaofen ;
Han, Zhenghe .
IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 2013, 23 (02)
[7]   Numerical solution of critical state in superconductivity by finite element software [J].
Hong, Z. ;
Campbell, A. M. ;
Coombs, T. A. .
SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 2006, 19 (12) :1246-1252
[8]   3D modelling of macroscopic force-free effects in superconducting thin films and rectangular prisms [J].
Kapolka, M. ;
Pardo, E. .
SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 2019, 32 (05)
[9]   finite element model for simulating second generation high temperature superconducting coils/stacks with large number of turns [J].
Liang, Fei ;
Venuturumilli, Sriharsha ;
Zhang, Huiming ;
Zhang, Min ;
Kvitkovic, Jozef ;
Pamidi, Sastry ;
Wang, Yawei ;
Yuan, Weijia .
JOURNAL OF APPLIED PHYSICS, 2017, 122 (04)
[10]   A-V formulation for numerical modelling of superconductor magnetization in true 3D geometry [J].
Mykola, Solovyov ;
Fedor, Gomory .
SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 2019, 32 (11)
123