Predicting AC loss in practical superconductors

Gömöry, Fedor; Šouc, J; Vojenčiak, M.; Seiler, E; Klinčok, B; Ceballos, J M; Pardo, Enric; Sanchez, Alvaro; Navau, Carles; Farinon, S.; Fabbricatore, P.

doi:10.1088/0953-2048/19/3/009

Cited by 33 publications

(36 citation statements)

References 53 publications

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“…Coupling loss simulations that take into account the real conductor geometry need in general to be performed with models having three spatial dimensions [257]. Important characteristics for the simulations that represent real world cases are at a minimum the modeling of superconducting domain, of the normal metal matrix and of the contact resistances between these two [258], [256].…”

Section: A Simulating Filament-coupling Effectsmentioning

confidence: 99%

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Grilli

Pardo

Stenvall

et al. 2014

IEEE Trans. Appl. Supercond.

295

263

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Numerical modeling of superconductors is widely recognized as a powerful tool for interpreting experimental results, understanding physical mechanisms and predicting the performance of high-temperature superconductor (HTS) tapes, wires and devices. This is especially true for ac loss calculation, since a sufficiently low ac loss value is imperative to make these materials attractive for commercialization. In recent years, a large variety of numerical models, based on different techniques and implementations, have been proposed by researchers around the world, with the purpose of being able to estimate ac losses in HTSs quickly and accurately. This article presents a literature review of the methods for computing ac losses in HTS tapes, wires and devices. Technical superconductors have a relatively complex geometry (filaments, which might be twisted or transposed, or layers) and consist of different materials. As a result, different loss contributions exist. In this paper, we describe the ways of computing such loss contributions, which include hysteresis losses, eddy current losses, coupling losses, and losses in ferromagnetic materials. We also provide an estimation of the losses occurring in a variety of power applications.

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Section: A Simulating Filament-coupling Effectsmentioning

confidence: 99%

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Grilli

Pardo

Stenvall

et al. 2014

IEEE Trans. Appl. Supercond.

295

263

View full text Add to dashboard Cite

show abstract

“…Note that the experimental Q can be maximum ͑minimum͒ when 0 0 ͑ 0 /2͒, as reported in Refs. [17][18][19]. The reason for the shifts in 0 for maximum and minimum Q is that the ac magnetic field was large ͑i.e., h 0 Ͼ 1͒ in those measurements.…”

Section: ͑14͒mentioning

confidence: 99%

Hysteretic ac loss of superconducting strips simultaneously exposed to ac transport current and phase-different ac magnetic field

Mawatari

Komori

2007

Applied Physics Letters

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A simple analytical expression is presented for hysteretic ac loss Q of a superconducting strip simultaneously exposed to an ac transport current I0 cos ωt and a phase-different ac magnetic field H0 cos(ωt + θ0). On the basis of Bean's critical state model, we calculate Q for small current amplitude I0 ≪ Ic, for small magnetic field amplitude H0 ≪ Ic/2πa, and for arbitrary phase difference θ0, where Ic is the critical current and 2a is the width of the strip. The resulting expression for Q = Q(I0, H0, θ0) is a simple biquadratic function of both I0 and H0, and Q becomes maximum (minimum) when θ0 = 0 or π (θ0 = π/2).

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“…2,3 The magnetic behavior of ferromagnetic substrates can strongly affect the electromagnetic response of superconducting coated conductors. Although the effects of ferromagnetic substrates on ac losses of superconducting coated conductors have been extensively investigated experimentally and numerically, [4][5][6][7][8][9][10][11][12][13] ac losses in superconducting strips on ferromagnetic substrates have not been investigated analytically. Genenko et al 14 analytically investigated the magnetic field and current distributions in superconducting strips surrounded by soft magnets, but they did not consider realistic geometries similar to those of coated conductors.…”

Section: Introductionmentioning

confidence: 99%

Magnetic field distributions around superconducting strips on ferromagnetic substrates

Mawatari

2008

Phys. Rev. B

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The complex-field approach is developed to derive analytical expressions of the magnetic field distributions around superconducting strips on ferromagnetic substrates ͑SC/FM strips͒. We consider the ferromagnetic substrates as ideal soft magnets with an infinite magnetic permeability, neglecting the ferromagnetic hysteresis.On the basis of the critical state model for a superconducting strip, the ac susceptibility 1 Ј+i 1 Љ of a SC/FM strip exposed to a perpendicular ac magnetic field is theoretically investigated, and the results are compared with those for superconducting strips on nonmagnetic substrates ͑SC/NM strips͒. The real part 1 Ј for H 0 / j c d s → 0 ͑where H 0 is the amplitude of the ac magnetic field, j c is the critical current density, and d s is the thickness of the superconducting strip͒ of a SC/FM strip is 3 / 4 of that of a SC/NM strip. The imaginary part 1 Љ ͑or ac loss Q͒ for H 0 / j c d s Ͻ 0.14 of a SC/FM strip is larger than that of a SC/NM strip, even when the ferromagnetic hysteresis is neglected, and this enhancement of 1 Љ ͑or Q͒ is due to the edge effect of the ferromagnetic substrate.

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Predicting AC loss in practical superconductors

Cited by 33 publications

References 53 publications

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Hysteretic ac loss of superconducting strips simultaneously exposed to ac transport current and phase-different ac magnetic field

Magnetic field distributions around superconducting strips on ferromagnetic substrates

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