Title :
Induction machine finite element model for field-oriented control in Electric vehicle power train
Author :
Hachicha, Mohamed Radhouan ; Ghariani, Moez ; Neji, Rafik
Author_Institution :
Electr. Vehicle & Power Electron. Group (VEEP), Univ. of Sfax, Sfax, Tunisia
Abstract :
Vector controlled drives involve a prior knowledge of the spatial orientation as well as the magnitude of the magnetic flux in the IM rotor or stator. In this context estimators or observers can be used, depending on the required robustness and accuracy as well as the sensitivity next to parameters variation. Thus, the performance of an IM drive remains dependent on the rapidity and the accuracy of the submitted parameters values. In this paper an IM finite element model based observer “FEMO” is developed. The IM finite element model “IMFEM” was designed using a two dimensional Finite Element Method “FEM” in order to identify the stator inductance, the rotor time constant and the magnetic dispersion coefficient. Field trials was undertaken to validate the IMFEM and performance of the FEMO is evaluated.
Keywords :
asynchronous machines; electric vehicles; finite element analysis; induction motor drives; machine vector control; magnetic flux; power transmission (mechanical); rotors; stators; FEMO observer; IM drive; IM rotor; electric vehicle power train; field oriented control; finite element model; induction machine; magnetic dispersion coefficient; magnetic flux; rotor time constant; stator inductance; vector controlled drives; Equations; Finite element analysis; Force; Mathematical model; Resistance; Rotors; Stators; Finite Element Method; Induction Motor; Induction Motor parameters; Parameters identification; Sensorless Induction Motor drive;
Conference_Titel :
Electrical Sciences and Technologies in Maghreb (CISTEM), 2014 International Conference on
DOI :
10.1109/CISTEM.2014.7077060
