Modeling Eddy Current Losses in HTS Tapes Using Multiharmonic Method

Due to the highly nonlinear electrical resistivity of high temperature superconducting (HTS) materials, computing the steady-state eddy current losses in HTS tapes, under time-periodic alternating current excitation, can be time consuming when using a time-transient method (TTM). The computation can require several periods to be solved with a small time-step. One alternative to the TTM is the multiharmonic method (MHM) where the Fourier basis is used to approximate the Maxwell fields in time. The method allows obtaining the steady-state solution to the problem with one resolution of the nonlinear problem. In this work, using the finite element method with the $H-\varphi$ formulation, the capabilities of the MHM in the computational eddy current loss modeling of HTS tapes are scrutinized and compared against the TTM.

[1]  Ziyi Huang,et al.  Electromagnetic and mechanical properties of CORC cable due to screening current , 2022, Superconductor Science and Technology.

[2]  C. Senatore,et al.  Development and large volume production of extremely high current density YBa2Cu3O7 superconducting wires for fusion , 2021, Scientific Reports.

[3]  L. Rossi,et al.  HTS Accelerator Magnet and Conductor Development in Europe , 2020, Instruments.

[4]  Wafa Ali Soomro,et al.  Advancements and Impediments in Applications of High-Temperature Superconducting Material , 2020, 2020 IEEE International Conference on Applied Superconductivity and Electromagnetic Devices (ASEMD).

[5]  H. S. Ruiz,et al.  How to Choose the Superconducting Material Law for the Modelling of 2G-HTS Coils , 2019, Materials.

[6]  W. Luo,et al.  Next-generation highly flexible round REBCO STAR wires with over 580 A mm−2 at 4.2 K, 20 T for future compact magnets , 2019, Superconductor Science and Technology.

[7]  D. Uglietti A review of commercial high temperature superconducting materials for large magnets: from wires and tapes to cables and conductors , 2019, Superconductor Science and Technology.

[8]  Alexandre Halbach,et al.  Sparselizard - the user friendly finite element c++ library , 2017 .

[9]  Antti Stenvall,et al.  A Finite Element Simulation Tool for Predicting Hysteresis Losses in Superconductors Using an H-Oriented Formulation with Cohomology Basis Functions , 2015 .

[10]  F. Grilli,et al.  Roebel cables from REBCO coated conductors: a one-century-old concept for the superconductivity of the future , 2014, 1406.4244.

[11]  Christophe Geuzaine,et al.  Homology and Cohomology Computation in Finite Element Modeling , 2013, SIAM J. Sci. Comput..

[12]  Ulrich Langer,et al.  Domain decomposition solvers for nonlinear multiharmonic finite element equations , 2010, J. Num. Math..

[13]  Christophe Geuzaine,et al.  Gmsh: A 3‐D finite element mesh generator with built‐in pre‐ and post‐processing facilities , 2009 .

[14]  Christophe Geuzaine,et al.  Harmonic-balance finite-element modeling of electromagnetic devices: a novel approach , 2002 .

[15]  A. Bossavit Whitney forms: a class of finite elements for three-dimensional computations in electromagnetism , 1988 .