Nonlinear Three-Phase Reluctance Synchronous Machine Modeling With Extended Torque Equation

Abstract: <p>Reluctance synchronous machines (RSMs) are characterized by high nonlinearities, cross-coupling effects and high torque ripple. This paper presents a nonlinear machine model of three-phase RSMs based on a nonlinear electromagnetic model including iron losses and a novel (extended) torque equation. The γ-component is used to consider asymmetries. The novel torque model provides a precise approximation of the machine’s torque ripple. Iron losses are covered as well. The nonlinear machine model with exte… Show more

“…(allowing for skin effects and asymmetric phase resistances), mechanical angular velocity ω m = ω p n p (i.e., electrical angular velocity ω p divided by pole pair number n p ), inertia constant Θ m , Carke transformation factor κ ∈ {2/3, 2/3} allowing for amplitude or power invariant transformation [17,Chapt. 14], average machine torque m m := 2 3κ 2 n p (i dq ) ⊤ J ψ dq [18], load torque m l and mechanical angle ϕ m (rotor position). Iron losses and temperature dependencies are neglected (although the presented approach can easily be extended to cover these scenarios as well).…”

Optimal reference voltage saturation for nonlinear current control of synchronous machine drives

“…(allowing for skin effects and asymmetric phase resistances), mechanical angular velocity ω m = ω p n p (i.e., electrical angular velocity ω p divided by pole pair number n p ), inertia constant Θ m , Carke transformation factor κ ∈ {2/3, 2/3} allowing for amplitude or power invariant transformation [17,Chapt. 14], average machine torque m m := 2 3κ 2 n p (i dq ) ⊤ J ψ dq [18], load torque m l and mechanical angle ϕ m (rotor position). Iron losses and temperature dependencies are neglected (although the presented approach can easily be extended to cover these scenarios as well).…”

Optimal reference voltage saturation for nonlinear current control of synchronous machine drives