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Self-Field ac Power Dissipation in High-Tc Superconducting Tapes and a Prototype Cable
By
S. A. Awan,

    Dr. S. A. Awan

    University of Newcastle upon Tyne

    UK

    Homepage

S. Sali

    Dr. S. Sali

    Department of Electrical, Electronic and Computer Engineering

    University of Newcastle

    UK

    Homepage

, Vol. 36, 81-100, 2002
doi:10.2528/PIER01060602 | Google Scholar

Abstract
The measured self-field AC power dissipation in superconducting BiSrCaCuO-2223/Ag tapes and a prototype cable is cable is compared with theoretical models. A brief overview of the theoretical background for AC loss calculations in superconductor tapes with different geometrical shapes is also discussed. New models for the harmonic components of the fundamental frequency and the current dependent non-linear inductance are also derived. It is shown that the latter models can be used to estimate current distribution and the variation of flux penetration in superconducting tapes. Two separate experimental apparatus were designed and constructed for measurements on tapes and prototype cable systems. The observed losses in tapes are reasonably well described by models based on the Critical State Model (CSM). In contrast, the measured losses in the prototype cable are found to be a factor of approximately two higher the predicted values. Further investigations showed that this may be due to inhomogeneous contact resistance between individual tapes and the current joints and the variation in critical current density (JC) distribution between tapes. The significance of current dependence of the loss component, inductive quadrature component, phase error in measurements and the definition of the critical current in the prototype cable are also discussed.
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Citation
S. A. Awan, and S. Sali, "Self-Field ac Power Dissipation in High-Tc Superconducting Tapes and a Prototype Cable," , Vol. 36, 81-100, 2002.
doi:10.2528/PIER01060602
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