Finite-Element Formulations for Systems With High-Temperature Superconductors
In this article, we consider finite-element models for high-temperature superconductors and compare two dual formulations, either magnetic-field conforming or magnetic-flux-density conforming. The electrical resistivity of superconductors is described by a power law and is strongly nonlinear. We com...
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| Published in | IEEE transactions on applied superconductivity Vol. 30; no. 3; pp. 1 - 13 |
|---|---|
| Main Authors | , , |
| Format | Journal Article Web Resource |
| Language | English |
| Published |
New York
IEEE
01.04.2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE) Institute of Electrical and Electronics Engineers |
| Subjects | |
| Online Access | Get full text |
| ISSN | 1051-8223 1558-2515 1558-2515 |
| DOI | 10.1109/TASC.2019.2935429 |
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| Abstract | In this article, we consider finite-element models for high-temperature superconductors and compare two dual formulations, either magnetic-field conforming or magnetic-flux-density conforming. The electrical resistivity of superconductors is described by a power law and is strongly nonlinear. We compare the accuracy and the efficiency of the dual formulations by starting from simple considerations on the concavity/convexity of the constitutive law involved in each case. We then study the numerical behavior of each formulation in one-, two-, and three-dimensional problems and compare their results against benchmarks. We draw general recommendations for the choice of a formulation, an iteration scheme for treating the corresponding linearized constitutive law, and a time-stepping extrapolation scheme. This approach is extended to soft ferromagnetic materials with a saturation law. Since the outcome of our analysis shows that recommended formulations for treating ferromagnets are just the opposite of those for treating superconductors, we suggest a coupled formulation for systems where both types of materials are present. The coupled formulation is shown to be accurate and more efficient than single formulations applied indistinctly to all materials. |
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| AbstractList | In this article, we consider finite-element models for high-temperature superconductors and compare two dual formulations, either magnetic-field conforming or magnetic-flux-density conforming. The electrical resistivity of superconductors is described by a power law and is strongly nonlinear. We compare the accuracy and the efficiency of the dual formulations by starting from simple considerations on the concavity/convexity of the constitutive law involved in each case. We then study the numerical behavior of each formulation in one-, two-, and three-dimensional problems and compare their results against benchmarks. We draw general recommendations for the choice of a formulation, an iteration scheme for treating the corresponding linearized constitutive law, and a time-stepping extrapolation scheme. This approach is extended to soft ferromagnetic materials with a saturation law. Since the outcome of our analysis shows that recommended formulations for treating ferromagnets are just the opposite of those for treating superconductors, we suggest a coupled formulation for systems where both types of materials are present. The coupled formulation is shown to be accurate and more efficient than single formulations applied indistinctly to all materials. In this paper, we consider finite element models for high-temperature superconductors and compare two dual formulations, either magnetic-field conforming or magnetic-flux- density conforming. The electrical resistivity of superconductors is described by a power law and is strongly nonlinear. We com- pare the accuracy and the efficiency of the dual formulations by starting from simple considerations on the concavity / convexity of the constitutive law involved in each case. We then study the numerical behavior of each formulation in 1D, 2D, and 3D problems and compare their results against benchmarks. We draw general recommendations for the choice of a formulation, an iteration scheme for treating the corresponding linearized constitutive law, and a time-stepping extrapolation scheme. This approach is extended to soft ferromagnetic materials with a saturation law. Since the outcome of our analysis shows that recommended formulations for treating ferromagnets are just the opposite of those for treating superconductors, we suggest a coupled formulation for systems where both types of materials are present. The coupled formulation is shown to be accurate and more efficient than single formulations applied indistinctly to all materials. |
| Author | Geuzaine, Christophe Dular, Julien Vanderheyden, Benoit |
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| Snippet | In this article, we consider finite-element models for high-temperature superconductors and compare two dual formulations, either magnetic-field conforming or... In this paper, we consider finite element models for high-temperature superconductors and compare two dual formulations, either magnetic-field conforming or... |
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| SubjectTerms | Concavity Convexity Electrical & electronics engineering Engineering, computing & technology Ferromagnetic materials Finite element method Finite-element (FE) analysis Finite-Element Analysis Formulations High temperature superconductors high-temperature superconductors (HTSs) Ingénierie électrique & électronique Ingénierie, informatique & technologie Iron Iterative methods Magnetic flux Magnetic levitation magnetic materials Magnetic noise Magnetic shielding Mathematical analysis Nonlinear Equations Saturation magnetization Superconducting magnets |
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| Title | Finite-Element Formulations for Systems With High-Temperature Superconductors |
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