Optimized Field/Circuit Coupling for the Simulation of Quenches in Superconducting Magnets
For engineers simulating quenches in superconducting magnets, this work offers an incremental improvement in coupling efficiency.
The paper proposes an optimized field/circuit coupling method to improve convergence in simulating magnetothermal transients in superconducting magnets, demonstrated on an accelerator dipole magnet with protection system.
In this paper, we propose an optimized field/circuit coupling approach for the simulation of magnetothermal transients in superconducting magnets. The approach improves the convergence of the iterative coupling scheme between a magnetothermal partial differential model and an electrical lumped-element circuit. Such a multi-physics, multi-rate and multi-scale problem requires a consistent formulation and a dedicated framework to tackle the challenging transient effects occurring at both circuit and magnet level during normal operation and in case of faults. We derive an equivalent magnet model at the circuit side for the linear and the non-linear settings and discuss the convergence of the overall scheme in the framework of optimized Schwarz methods. The efficiency of the developed approach is illustrated by a numerical example of an accelerator dipole magnet with accompanying protection system.