Hollaus, K., & Schöbinger, M. (2023). Multiscale finite element formulations for 2D/1D problems. IEEE Transactions on Energy Conversion. https://doi.org/10.34726/5425
E101-03 - Forschungsbereich Scientific Computing and Modelling
-
Journal:
IEEE Transactions on Energy Conversion
-
ISSN:
0885-8969
-
Date (published):
2023
-
Number of Pages:
11
-
Publisher:
IEEE
-
Peer reviewed:
Yes
-
Keywords:
Biot-Savart field; Eddy currents; Finite element analysis; Insulation; Mathematical models; Direct solver; Iterative solver; Thin iron sheets; 2D/1D multiscale finite element method MSFEM; Edge effect
en
Abstract:
Multiscale finite element methods for 2D/1D problems have been studied in this work to demonstrate their excellent ability to solve the eddy current problem in a single iron sheet of electrical machines. We believe that these methods are much more efficient than conventional 3D finite element methods and just as accurate. The 2D/1D multiscale finite element methods are based on a magnetic vector potential or a current vector potential. Known currents for excitation can be replaced by the Biot-Savart-field. Boundary conditions allow to integrate planes of symmetry. All approaches consider eddy currents, an insulation layer and preserve the edge effect. A segment of a fictitious electrical machine has been studied to demonstrate all above options, the accuracy and the low computational costs of the 2D/1D multiscale finite element methods. Numerous simulations are presented. Direct and iterative solvers were investigated to reliably solve the system of equations from 2D/1D MSFEMs.
en
Project title:
Effektive Materialtransformation für ferromagnetische Bleche: P36395-N (FWF - Österr. Wissenschaftsfonds) Hochleistungs-Mehrskalen-Finite-Elemente-Methoden hp-MSFEMs: P 31926-N35 (FWF - Österr. Wissenschaftsfonds)