AC Loss Reduction in HTS Coil Windings Coupled With an Iron Core

Rapid-cycling synchrotron (RCS) magnets based on a superferric design consist of high temperature superconducting (HTS) coil windings coupled with iron cores. However, the presence of iron cores significantly increases AC loss in HTS coil windings, making AC loss reduction a critical issue for applying HTS technology in RCSs. Enlarging the distance between iron cores and coil windings may reduce AC loss. In addition, magnetic materials with different saturation magnetic fields also may influence AC loss in HTS coil windings coupled with iron cores. To investigate the distance dependence, AC losses of 1DPC (double pancake coil)-, 2DPC-, 4DPC-, and 8DPC assemblies with various distances are simulated using the 3D T-A homogenization method with/without an iron core. Two magnetic materials with different saturation magnetic fields are chosen as the iron core to evaluate AC loss in HTS coil assemblies. The results show that the AC loss values in HTS coil assemblies coupled with the iron core decrease significantly with growing distance. For a given distance and current, when the iron core has a lower saturation field, the AC loss values of the 4DPC assembly are smaller than those with a higher saturation field.

[1]  M. Zhang,et al.  3D homogenization of the T-A formulation for the analysis of coils with complex geometries , 2022, Superconductor Science and Technology.

[2]  R. Badcock,et al.  Experimental and numerical study on AC loss reduction in a REBCO coil assembly by applying high saturation field powder-core flux diverters , 2022, Cryogenics.

[3]  L. Rossi,et al.  Fast cycling HTS based superconducting accelerator magnets: Feasibility study and readiness demonstration program driven by neutrino physics and muon collider needs , 2022, 2203.06253.

[4]  R. Badcock,et al.  AC Loss Simulation in HTS Coil Windings Coupled With an Iron Core , 2022, IEEE Transactions on Applied Superconductivity.

[5]  Wei Wu,et al.  Design, Fabrication and Test of a 1.5 T Cryogen-Free HTS Dipole Magnet for the Heavy Ion Spectrometer , 2022, IEEE Transactions on Applied Superconductivity.

[6]  F. Grilli,et al.  Advanced electromagnetic modeling of large-scale high-temperature superconductor systems based on H and T-A formulations , 2021, Superconductor Science and Technology.

[7]  Wenjuan Song,et al.  Design of a single-phase 6.5 MVA/25 kV superconducting traction transformer for the Chinese Fuxing high-speed train , 2020 .

[8]  B. Shen,et al.  Numerical Study on AC Loss of an HTS Coil Placed on Laminated Silicon Steel Sheets With Distorted AC Transport Currents , 2020, IEEE Transactions on Applied Superconductivity.

[9]  N. Amemiya,et al.  Reduction of AC Loss in HTS Coils of Superferric Magnets for Rapid-Cycling Synchrotrons by Changing Cross-Section of Coils and Iron Yoke Geometry , 2020, IEEE Transactions on Applied Superconductivity.

[10]  N. Amemiya,et al.  AC Losses in HTS Coils of Superferric Dipole and Combined-Function Magnets , 2019, IEEE Transactions on Applied Superconductivity.

[11]  Francesco Grilli,et al.  Real-time simulation of large-scale HTS systems: multi-scale and homogeneous models using the T–A formulation , 2018, Superconductor Science and Technology.

[12]  Zhenan Jiang,et al.  AC Loss Characteristics in REBCO Coil Assemblies With Different Geometries and Conductors , 2018, IEEE Transactions on Applied Superconductivity.

[13]  Jiansheng Yuan,et al.  Numerical Simulation and Analysis of a Saturated-Core-Type Superconducting Fault Current Limiter , 2017, IEEE Transactions on Applied Superconductivity.

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

[15]  M. Zhang,et al.  Simulation of AC Loss in Small HTS Coils With Iron Core , 2015, IEEE Transactions on Applied Superconductivity.

[16]  V. Shiltsev,et al.  Design, Construction, and Test Arrangement of a Fast-Cycling HTS Accelerator Magnet , 2014, IEEE Transactions on Applied Superconductivity.

[17]  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.

[18]  Jeffrey W. Moscrop,et al.  Increasing Energy Efficiency of Saturated-Core Fault Current Limiters With Permanent Magnets , 2013, IEEE Transactions on Magnetics.

[19]  J. Kovac,et al.  AC loss in ReBCO pancake coils and stacks of them: modelling and measurement , 2011, 1109.2526.

[20]  S. Odaka,et al.  Transport current losses in HoBaCuO-123 coated conductors with a Ni-alloy substrate , 2005 .

[21]  M. Anerella,et al.  Status of high temperature superconductor magnet R&D at BNL , 2004, IEEE Transactions on Applied Superconductivity.

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