Modeling cross-field demagnetization of superconducting stacks and bulks for up to 100 tapes and 2 million cycles

Dadhich, Anang; Pardo, Enric

doi:10.1038/s41598-020-76221-z

Cited by 9 publications

(23 citation statements)

References 59 publications

(75 reference statements)

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“…In some machinery applications, HTS materials after magnetisation work as permanent magnets by carrying a persistent DC circulating current, and there are mainly three types: bulks, tape stacks, and closed-loop coils. The main issue with this technology is the demagnetization of the HTS permanent magnets caused by the AC fields they experienced in the rotor that transverse to their magnetisation [10,[13][14][15][16]. Dynamic resistance was considered as a mechanism to explain this demagnetization effect [10,13,14,16].…”

Section: Introduction and Theoretical Conjecturementioning

confidence: 99%

“…The main issue with this technology is the demagnetization of the HTS permanent magnets caused by the AC fields they experienced in the rotor that transverse to their magnetisation [10,[13][14][15][16]. Dynamic resistance was considered as a mechanism to explain this demagnetization effect [10,13,14,16]. For closed-loop coils, the effect of dynamic resistance on the acceleration of the decay of persistent current can be expressed as [10]:…”

Section: Introduction and Theoretical Conjecturementioning

confidence: 99%

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Sharp demagnetization of closed-loop HTS coil in first cycle of external AC fields induced by unexpected dynamic resistance

Zhong

Jin

2021

Supercond. Sci. Technol.

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Dynamic resistance leads to the demagnetization of high-T c superconducting (HTS) permanent magnets (such as closed-loop coils and tape stacks) when exposed to AC fields. This letter reports on the systematic study of an unexpected dynamic resistance occurring in first cycle AC field, which can be induced by any weak AC field-even below the threshold value 'conventionally' defined for generating dynamic resistance. This resistance is predicted by a critical-state analytical calculation, and its physical origin is shown to be from the asymmetrical flux penetration. Numerically, this resistance is verified, and simulated for a closed-loop HTS coil, showing a non-negligible demagnetization effect. Experimentally, the current decay (i.e. demagnetization) characteristics of a closed-loop HTS coil in a sufficient range of AC fields are measured. This resistance manifests itself in the closed-loop coil as a relatively sharp current decay in the first cycle of the applied field; this observation is in qualitative agreement with the simulation. A comparative experiment is performed to eliminate the contribution from the index loss or 'conventional' dynamic resistance that also possibly results in a greater demagnetization in the first cycle owing to the larger coil current. As the result, this unexpected dynamic resistance is verified. The unexpected, sharp demagnetization caused by this resistance might need to be considered when designing HTS closed-loop coil applications.

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Section: Introduction and Theoretical Conjecturementioning

confidence: 99%

Section: Introduction and Theoretical Conjecturementioning

confidence: 99%

Sharp demagnetization of closed-loop HTS coil in first cycle of external AC fields induced by unexpected dynamic resistance

Zhong

Jin

2021

Supercond. Sci. Technol.

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“…Although the stacks will use low tape-to-tape separation and high number of tapes, the average electromotive force due to the ripple field will be the same. Thus, we expect the same qualitative (and maybe even quantitative) behavior as for our simpler 5-tape stack, but the stationary state in actual stacks will likely require higher number of cycles due to the inductive effects caused by the higher number of tapes 16,39 .…”

Section: Modeling Configurationmentioning

confidence: 66%

“…When the motor is operating, in the air gap of an electric motor there are always excessive harmonics caused by the differences in permeability of the magnetic circuit (slot harmonics) and the discrete distribution of the stator coils (winding harmonics). It has been reported from laboratory testing and computer modeling that the cross-field is of the same order of magnitude as the parallel penetration field in each layer, which could demagnetize the stack in just a few minutes 15,16 . The cross-field that the stacks experience in the rotor causes demagnetization of the trapped field, which reduces the performance of the motor 17,18 .…”

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confidence: 99%

“…It is technically possible to make isolated stacks, which are already used in the ASuMED project 24 . The motivation for studying soldered stacks is that bulks with the same engineering current density are much less sensitive to cross-field demagnetization, as shown in 16 . We expect that soldered stacks will behave as bulk for large enough frequencies of the ripple field.…”

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confidence: 99%

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Numerical modelling of soldered superconducting REBCO stacks of tapes suggests strong reduction in cross-field demagnetization

Pardo

2023

Sci Rep

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Stacks of superconducting REBCO tapes (or “stacks”) can trap high magnetic fields, above 17 T. However, relatively low oscillating transverse magnetic fields can fully demagnetize the stacks. This is an issue if the stacks act as poles in the rotor of a superconducting motor, for instance. Here, we study the drastic suppression of cross-field demagnetization in stacks by soldering the tapes at the ends using a normal conductor. In particular, we analyzed by numerical modeling a stack of five REBCO thin films connected at the ends by resistances. The computed trapped field of a stack with zero solder resistance decays very fast at the beginning but then tends to stabilize to relatively high values, while the trapped field of an isolated stack (infinite resistance at the ends) decays further (it decays to zero if the transverse field is above the parallel penetration field). For intermediate solder resistances, the stable value of the trapped magnetic field is in between those of the isolated and zero-resistance configurations. Since the stable trapped field in soldered stacks increases with the number of tapes, stacks of sufficiently high number of soldered tapes could be immune to cross-field demagnetization. This opens the gate for a new kind of superconductors that mostly behave as bulks, especially if the stacks are made of delaminated tapes or it is possible to solder the tapes by very low resistance.

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Electromagnetic properties of curved HTS trapped field stacks under high-frequency cross fields for high-speed rotating machines

Zhang

Mueller

2021

Supercond. Sci. Technol.

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Superconducting electric propulsion systems, characterized by high power densities and efficiencies, provide a possibility to zero carbon emission for future aviation. Stacks of high temperature superconductor (HTS) coated conductors (CCs) have become an alternative for high field magnets applied to superconducting machines, given their excellent field trapping ability and thermal stability. High-frequency ripple fields always exist in high-speed electric machines. Most research work regarding HTS trapped field stacks (TFSs) was focused on their magnetization methods and amplitude of trapped flux density; however, their performance in the high-frequency environment remains unclear. Despite several numerical models established for flat HTS TFSs, a comprehensive analysis of curved ones is still lacking, which possess geometrical applicability for cylindrical rotating shafts. Aimed at exploring the electromagnetic properties of curved HTS TFSs applied to high-speed rotating machines, a 3D numerical model considering both the multilayer structure and the Jc(B) dependence of HTS CCs has been built. Current and magnetic flux density distributions, as well as loss properties of a curved HTS TFS have been studied in detail, under perpendicular and cross fields with varying frequencies ranging from 50 Hz to 20 kHz. Results have shown that, the widely adopted 2D-axisymmetric models are inapplicable to study the electromagnetic distributions of TFSs because of the emergence of the electromagnetic crisscross defined in this paper. High-frequency ripple fields can drive induced current towards the periphery of the HTS TFS due to the skin effect, leading to a fast rise of AC loss and even an irreversible demagnetization of the stack. This paper has qualified and quantified the highfrequency electromagnetic hehaviours of curved HTS TFSs, providing a useful reference for their loss controlling and anti-demagnetization design in high-speed propulsion machines.

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Modeling cross-field demagnetization of superconducting stacks and bulks for up to 100 tapes and 2 million cycles

Cited by 9 publications

References 59 publications

Sharp demagnetization of closed-loop HTS coil in first cycle of external AC fields induced by unexpected dynamic resistance

Sharp demagnetization of closed-loop HTS coil in first cycle of external AC fields induced by unexpected dynamic resistance

Numerical modelling of soldered superconducting REBCO stacks of tapes suggests strong reduction in cross-field demagnetization

Electromagnetic properties of curved HTS trapped field stacks under high-frequency cross fields for high-speed rotating machines

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