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Prediction of 2G HTS Tape Quench Behavior by Random Forest Model Trained on 2-D FEM Simulations

Dmitry Sotnikov, M. Lyly, Tiina Salmi

2023IEEE Transactions on Applied Superconductivity20 citationsDOI

Abstract

Detailed Finite Element Method (FEM) based simulations for 2G HTS tapes return high quality results, but the computation takes a long time due to the non-linearity of superconducting properties and they needed high mesh density. This work describes a method for prediction of quench behavior in a long 2G HTS tape based on a series of 2D FEM model simulations for short length of tape in many different conditions. The random forest model is trained by the set of results from the short-pieces FEM calculations. Subsequently the model can be applied to any length of HTS tape with similar thermal characteristics. Comparison of quench simulation in 10 cm long HTS tape between a detailed FEM model and a fully trained random forest model show that the predicted temperatures are within 0.68%, while the computation time is significantly faster: The random forest model ran in less than 1 s, while the run time of the FEM model was 5:30 min.

Topics & Concepts

Finite element methodComputationComputer scienceWork (physics)Materials scienceMechanical engineeringStructural engineeringAlgorithmEngineeringPhysics of Superconductivity and MagnetismSuperconducting Materials and ApplicationsMagnetic Properties and Applications
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