Title :
A combined finite element-state space modeling environment for induction motors in the ABC frame of reference: the blocked-rotor and sinusoidally energized load conditions
Author :
Baldassari, P. ; Demerdash, N.A.
Author_Institution :
Dept. of Electr. & Comput. Eng., Clarkson Univ., Potsdam, NY, USA
fDate :
12/1/1992 12:00:00 AM
Abstract :
The combined finite element-state space (CFE-SS) modeling environment was used to predict the performance of a 1.2 hp, three-phase case-study squirrel cage induction motor under blocked rotor and typical load operating conditions. The nature of this CFE-SS environment allows one to rigorously account for the impact of space harmonics generated by the magnetic circuit, winding, and cage geometric, as well as layout peculiarities and magnetic saturation, on the current and torque profiles, and ohmic losses in the stator armature and cage. This includes the ability to predict the profiles of connector and bar currents. The results of the CFE-SS simulations compare favorably with blocked rotor and load experimental test data. Potential capabilities of this CFE-SS modeling environment, and its use in impacting motor design decisions, are discussed in the light of reported findings
Keywords :
finite element analysis; harmonics; load (electric); machine theory; magnetic circuits; rotors; squirrel cage motors; state-space methods; stators; 1.2 hp; ABC frame of reference; FEM; blocked rotor; connector; current; design; induction motors; machine theory; magnetic circuit; magnetic saturation; modeling; ohmic losses; performance; sinusoidally energized load; space harmonics; squirrel cage; state-space methods; stator armature; three-phase; torque; winding; Connectors; Finite element methods; Induction generators; Induction motors; Magnetic circuits; Predictive models; Rotors; Saturation magnetization; Stator windings; Torque;
Journal_Title :
Energy Conversion, IEEE Transactions on
