Title :
Tradeoff Modeling of Superconducting Levitation Machines: Theory and Experiment
Author :
Badia-Majos, Anonio ; Aliaga, A. ; Letosa-Fleta, Jesus ; Mora Alfonso, Mario ; Pena Roche, Jorge
Author_Institution :
Dept. of Condensed Matter Phys., Univ. of Zaragoza, Zaragoza, Spain
Abstract :
Based on the critical state model for the superconducting components, we develop a set of theoretical tools that allow extracting relevant engineering parameters of a superconducting levitation machine. We provide a number of analytical and numerical expressions for the evaluation of the electromagnetic quantities, energies, and forces in 2-D problems. This assumption includes the following: 1) rotational symmetric systems, as those in bearings and motors, and the case of 2) translational symmetry, as in long transportation lines. The theory, which trades off simplicity and predictive power, builds on the vector potential/current density formulation of the Maxwell equations (A, J) and is validated by comparison against experimental tension-compression data in our universal test machine. As shown, very simple computer coding is required to implement the method.
Keywords :
Maxwell equations; current density; magnetic levitation; superconducting machines; Maxwell equation; bearing; computer coding; critical state model; current density; electromagnetic quantity; motor; predictive power; rotational symmetric system; superconducting component; superconducting levitation machine; tension-compression data; tradeoff modeling; translational symmetry; transportation line; Current density; Electromagnetics; Magnetic levitation; Mathematical model; Superconducting magnets; Critical State Model; Critical state model; Magnetic Levitation Force; Superconducting Modeling; magnetic levitation force; superconducting modeling;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2015.2448456
