2-D Analytical Prediction of Eddy Currents, Circuit Model Parameters, and Steady-State Performances in Solid Rotor Induction Motors

This paper presents a 2-D analytical method in the complex domain for the computation of magnetic field distribution, eddy currents, circuit model parameters, and steady-state performances in solid rotor induction motors. The proposed static analytical model considers stator slotting with tooth-tips. The rotor motion is simulated by varying the slip. The analytical magnetic field distribution is computed in polar coordinates from 2-D subdomain method (i.e., based on the formal resolution of Maxwell's equations applied in subdomain) in each region, i.e., semiclosed stator slots, air gap, solid rotor, and shaft. The electromagnetic torque is obtained from both the electrical equivalent circuit and Maxwell stress tensor that is given by the magnetic field distribution. Analytical results are validated by the static finite-element method.