Real-time simulation of large-scale HTS systems: multi-scale and homogeneous models using the T–A formulation

The emergence of second-generation high temperature superconducting tapes has favored the development of large-scale superconductor systems. The mathematical models capable of estimating electromagnetic quantities in superconductors have evolved from simple analytical models to complex numerical models. The available analytical models are limited to the analysis of single wires or infinite arrays that, in general, do not represent real devices in real applications. The numerical models based on finite element method using the H formulation of the Maxwells equations are useful for the analysis of medium-size systems, but their application in large-scale systems is problematic due to the excessive computational cost in terms of memory and computation time. Then it is necessary to devise new strategies to make the computation more efficient. The homogenization and the multi-scale methods have successfully simplified the description of the systems allowing the study of large-scale systems. Also, efficient calculations have been achieved using the T-A formulation. In the present work, we propose a series of adaptations to the multi-scale and homogenization methods so that they can be efficiently used in conjunction with the T-A formulation to compute the distribution of current density and hysteresis losses in the superconducting layer of superconducting tapes. The computation time and the amount of memory are substantially reduced up to a point that it is possible to achieve real-time simulations of HTS large-scale systems under slow ramping cycles of practical importance on personal computers.

[1]  Steven C. Chapra,et al.  Numerical Methods for Engineers , 1986 .

[2]  M R Halse,et al.  AC FACE FIELD LOSSES IN A TYPE-II SUPERCONDUCTOR. , 1970 .

[3]  Luciano Martini,et al.  Development of an edge-element model for AC loss computation of high-temperature superconductors , 2006 .

[4]  Kai Strunz,et al.  Real-Time Simulation Technologies for Power Systems Design, Testing, and Analysis , 2015, IEEE Power and Energy Technology Systems Journal.

[5]  Leonid Prigozhin,et al.  Computing AC losses in stacks of high-temperature superconducting tapes , 2011 .

[6]  John R. Clem Field and current distributions and ac losses in a bifilar stack of superconducting strips , 2008 .

[7]  H. Ohsaki,et al.  AC Losses of a Grid-Connected Superconducting Wind Turbine Generator , 2013, IEEE Transactions on Applied Superconductivity.

[8]  Francesco Grilli,et al.  Potential and limits of numerical modelling for supporting the development of HTS devices , 2014, 1412.2312.

[9]  J. H. Claassen,et al.  AC losses in a finite Z stack using an anisotropic homogeneous-medium approximation , 2007, 0708.4024.

[10]  Youhe Zhou,et al.  Electromagnetic modeling of REBCO high field coils by the H-formulation , 2015 .

[11]  F. Sirois,et al.  Analytical Methods and Formulas for Modeling High Temperature Superconductors , 2013, IEEE Transactions on Applied Superconductivity.

[12]  J. Bastos,et al.  Electromagnetic Modeling by Finite Element Methods , 2003 .

[13]  Ashish Raj,et al.  Frequency dependent magnetization of superconductor strip , 2011 .

[14]  Bertrand Dutoit,et al.  Finite element method simulation of AC loss in HTS tapes with B-dependent E-J power law , 2001 .

[15]  Jakob Rhyner,et al.  Magnetic properties and AC-losses of superconductors with power law current-voltage characteristics , 1993 .

[16]  Min Zhang,et al.  An efficient 3D finite element method model based on the T–A formulation for superconducting coated conductors , 2017 .

[17]  C. F. Hempstead,et al.  CRITICAL PERSISTENT CURRENTS IN HARD SUPERCONDUCTORS , 1962 .

[18]  A. Romanyuk,et al.  Hysteresis losses in superconductors of round cross-section with collective interaction , 1978 .

[19]  W. R. Sheppard,et al.  Design of a Superconducting 32 T Magnet With REBCO High Field Coils , 2012, IEEE Transactions on Applied Superconductivity.

[20]  Enric Pardo,et al.  Electromagnetic modelling of superconductors with a smooth current–voltage relation: variational principle and coils from a few turns to large magnets , 2014, 1410.0772.

[21]  Francesco Grilli,et al.  Numerical models for ac loss calculation in large-scale applications of HTS coated conductors , 2015, 1509.05560.

[22]  Nenad Mijatovic,et al.  Calculation of alternating current losses in stacks and coils made of second generation high temperature superconducting tapes for large scale applications , 2013, 1308.2568.

[23]  Anders Logg,et al.  Solving PDEs in Python: The FEniCS Tutorial I , 2017 .

[24]  Weijia Yuan,et al.  Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents , 2013, IEEE Transactions on Applied Superconductivity.

[25]  A. Stenvall,et al.  Ripple field losses in direct current biased superconductors: Simulations and comparison with measurements , 2013, 1308.6757.

[26]  A. Kudymow,et al.  SmartCoil—Concept of a Full-Scale Demonstrator of a Shielded Core Type Superconducting Fault Current Limiter , 2017, IEEE Transactions on Applied Superconductivity.

[27]  K. Müller,et al.  Self-field hysteresis loss in periodically arranged superconducting strips , 1997 .

[28]  Hongyu Bai,et al.  Progress in the Development and Construction of a 32-T Superconducting Magnet , 2016, IEEE Transactions on Applied Superconductivity.

[29]  Naoyuki Amemiya,et al.  Numerical modelings of superconducting wires for AC loss calculations , 1998 .

[30]  Ziad Melhem,et al.  High temperature superconductors (HTS) for energy applications , 2012 .

[31]  F. Gomory,et al.  Current distribution and ac loss for a superconducting rectangular strip with in-phase alternating current and applied field , 2005, cond-mat/0510314.

[32]  Jian-Ming Jin,et al.  The Finite Element Method in Electromagnetics , 1993 .

[33]  Francesco Grilli,et al.  Iterative multi-scale method for estimation of hysteresis losses and current density in large-scale HTS systems , 2018, Superconductor Science and Technology.

[34]  Brandt Thin superconductors in a perpendicular magnetic ac field: General formulation and strip geometry. , 1994, Physical review. B, Condensed matter.

[35]  Jozef Kvitkovic,et al.  Frequency-dependent critical current and transport ac loss of superconductor strip and Roebel cable , 2011 .

[36]  Francesco Grilli,et al.  Numerical Modeling of HTS Applications , 2016, IEEE Transactions on Applied Superconductivity.

[37]  Karl-Heinz Müller AC losses in stacks and arrays of YBCO/hastelloy and monofilamentary Bi-2223/Ag tapes , 1999 .

[38]  Antonio Morandi,et al.  Comparison of Constitutive Laws for Modeling High-Temperature Superconductors , 2019, IEEE Transactions on Applied Superconductivity.

[39]  Michael Frankfurter,et al.  High Temperature Superconductors Hts For Energy Applications , 2016 .

[40]  M Sander,et al.  FEM-calculations on the frequency dependence of hysteretic losses in coated conductors , 2010 .

[41]  Mawatari Critical state of periodically arranged superconducting-strip lines in perpendicular fields. , 1996, Physical review. B, Condensed matter.

[42]  Jianming Jin Theory and Computation of Electromagnetic Fields , 2010 .

[43]  T. A. Coombs,et al.  A model for calculating the AC losses of second-generation high temperature superconductor pancake coils , 2009 .

[44]  Miquel Carrera,et al.  H-Formulation FEM Modeling of the Current Distribution in 2G HTS Tapes and Its Experimental Validation Using Hall Probe Mapping , 2016, IEEE Transactions on Applied Superconductivity.

[45]  Min Zhang,et al.  A finite element model for simulating second generation high temperature superconducting coils/stacks with large number of turns , 2017 .

[46]  Enric Pardo,et al.  Calculation of AC loss in coated conductor coils with a large number of turns , 2013, 1304.5148.

[47]  W. T. Norris,et al.  Calculation of hysteresis losses in hard superconductors carrying ac: isolated conductors and edges of thin sheets , 1970 .