Model of reactor based on the Finite Element Method (FEM) is built on base of a controllable reactor model with self-excitation structure. ANSYS simulation model of a 380 V/13A controllable reactor is built. The results show that the two small section segments of the cores of traditional controllable reactor saturate by turns, it increases the consumption of the cores and windings of controllable reactor, by separating the cores can it reduce the consumption of the controllable reactor.
The physical coupled field of the 380 V/13A experimental prototype is systematically analyzed in this paper. A precise 2-D field-circuit coupled model is established in ANASYS platform which is based on finite element theory. Both magnetic circuit equations and electric circuit equations obeying specific circuit configuration are included in this field-circuit coupled model upon which it explicates the real electromagnetic transient process; and upon which an accurate computation of electromagnetic field intensity and electric magnetic induction intensity is given. Simulation results coincide with that of the basic principle's derivation through which the correctness of the field-circuit coupled model is substantiated. The 2-D field-circuit coupled model of 380 V/13A MCR prototype presented here is a solid foundation for reactor design and its performance analysis.
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