Abstract
A backward computation method has been developed to accelerate modelling of the critical state magnetization current in a staggered-array bulk high-temperature superconducting (HTS) undulator. The key concept is as follows: (i) a large magnetization current is first generated on the surface of the HTS bulks after rapid field-cooling (FC) magnetization; (ii) the magnetization current then relaxes inwards step-by-step obeying the critical state model; (iii) after tens of backward iterations the magnetization current reaches a steady state. The simulation results show excellent agreement with the H -formulation method for both the electromagnetic and electromagnetic-mechanical coupled analyses, but with significantly faster computation speed. The simulation results using the backward computation method are further validated by the recent experimental results of a five-period Gd–Ba–Cu–O (GdBCO) bulk undulator. Solving the finite element analysis (FEA) model with 1.8 million degrees of freedom (DOFs), the backward computation method takes less than 1.4 h, an order of magnitude or higher faster than other state-of-the-art numerical methods. Finally, the models are used to investigate the influence of the mechanical stress on the distribution of the critical state magnetization current and the undulator field along the central axis.
Highlights
Research and development work on short-period and high-field staggered-array high-temperature superconducting (HTS) bulk undulators [1,2] is ongoing in a European project for the construction of compact free electron lasers (FELs) [3,4]
This indicates that the critical current density Jc should be a function of both the magnetic flux density B and the mechanical strain ε when a ReBCO bulk superconductor traps a high magnetic field and experiences the associated large Lorentz force
This paper introduces a new backward computation method to accelerate modelling the Jc(B,ε)-determined critical state magnetization current in the periodical HTS bulk undulator
Summary
Research and development work on short-period and high-field staggered-array high-temperature superconducting (HTS) bulk undulators [1,2] is ongoing in a European project for the construction of compact free electron lasers (FELs) [3,4]. This new technology utilizes a 10 T level superconducting solenoid magnet to realize field-cooling (FC) magnetization of a series of staggered-array ReBCO bulks at a temperature around 10 K. Trillaud et al (2018) showed the critical current density Jc of ReBCO bulk superconductor will degrade when the Lorentz force-induced mechanical stress is of the order of the fracture strength [10]. Regarding the short-period and high-field staggered-array HTS bulk undulator, estimation of the magnetization current that follows a Jc(B,ε)-determined critical state model [11,12], without time-dependent flux creep effects, is of great interest for the purpose of optimizing the first and the second integrals of the undulator field along the central axis
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