Title :
The Optimal Design of HTS Devices
Author :
Das, Ratan ; Oliveira, Fernando B. ; Guimaraes, Frederico ; Lowther, David A.
Author_Institution :
Dept. of Electr. & Comput. Eng., McGill Univ., Montreal, QC, Canada
Abstract :
In the design of high-temperature superconductor (HTS)-based electromagnetic devices, some of the major challenges include ac loss reduction, minimization of heat leakage, and reduction of the amount of HTS material used to decrease costs. This paper considers a computer model of HTS-based leads involving a multiphysics scenario that considers the electromagnetic and thermal behavior of the system. This paper attempts to address the requirements mentioned and provides an optimum solution by applying an approach based on multiobjective optimization. The differential evolution technique, a stochastic method, widely known for the ease of use and its ability to handle adequately non-differentiable, non-linear, and multimodal cost functions was used. The proposed framework provides a technique to optimize effectively HTS leads, which not only deals with the non-linear aspect of HTS materials, but also includes a multiphysics environment.
Keywords :
electromagnetic devices; high-temperature superconductors; stochastic programming; superconducting devices; HTS device optimal design; HTS-based leads; ac loss reduction; computer model; differential evolution technique; electromagnetic behavior; electromagnetic devices; heat leakage minimization; high-temperature superconductor; multimodal cost functions; multiobjective optimization; multiphysics environment; nondifferentiable cost functions; nonlinear cost functions; stochastic method; thermal behavior; Critical current density (superconductivity); High-temperature superconductors; Mathematical model; Optimization; Vectors; Differential evolution (DE); FEM; high-temperature superconductor (HTS); multiobjective optimization (MOO);
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2284051
