Two main options exists for modeling the non linearity of the superconductor: the power law and the critical state model. A vanishing electric field is predicted by the critical state model which does not allow to take into account relaxation phenomena. The power law model is to be used if flux creep is to be taken into account. However, detectable flux creep may not occur in many operating conditions. In these cases the critical state represents a more accurate modeling option. Existing numerical tools usually incorporate either the power law with finite n exponent or the critical state model, not both. A numerical model which incorporates both the power law and the critical state modeling of superconductors in 2D is developed in this paper. The same mathematical formulation and discretization method are used in both the cases and the same matrix equation is obtained The difference between the two models only arises when the solution of the matrix equation is dealt with. The model is implemented by means of one unique computer code. A circuit interpretation of the model is also introduced. The equivalence of the proposed method with the variational approach reported in the literature for dealing with the critical state is also discussed in the paper. Numerical results for some cases of practical interest are presented. The difference between the results obtained by means of the two models in terms of current distribution and AC loss is pointed out.

Antonio Morandi, Massimo Fabbri (2015). A unified approach to the power law and the critical state modeling of superconductors in 2D. SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 28, 024004+1-024004+10 [10.1088/0953-2048/28/2/024004].

A unified approach to the power law and the critical state modeling of superconductors in 2D

MORANDI, ANTONIO;FABBRI, MASSIMO
2015

Abstract

Two main options exists for modeling the non linearity of the superconductor: the power law and the critical state model. A vanishing electric field is predicted by the critical state model which does not allow to take into account relaxation phenomena. The power law model is to be used if flux creep is to be taken into account. However, detectable flux creep may not occur in many operating conditions. In these cases the critical state represents a more accurate modeling option. Existing numerical tools usually incorporate either the power law with finite n exponent or the critical state model, not both. A numerical model which incorporates both the power law and the critical state modeling of superconductors in 2D is developed in this paper. The same mathematical formulation and discretization method are used in both the cases and the same matrix equation is obtained The difference between the two models only arises when the solution of the matrix equation is dealt with. The model is implemented by means of one unique computer code. A circuit interpretation of the model is also introduced. The equivalence of the proposed method with the variational approach reported in the literature for dealing with the critical state is also discussed in the paper. Numerical results for some cases of practical interest are presented. The difference between the results obtained by means of the two models in terms of current distribution and AC loss is pointed out.
2015
Antonio Morandi, Massimo Fabbri (2015). A unified approach to the power law and the critical state modeling of superconductors in 2D. SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 28, 024004+1-024004+10 [10.1088/0953-2048/28/2/024004].
Antonio Morandi; Massimo Fabbri
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/429966
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