Title :
Speed sensorless torque control of induction motor for EV´s
Author_Institution :
Fac. of Electr. Eng. & Comput. Sci., Maribor Univ., Slovenia
Abstract :
A novel induction motor speed sensorless torque control scheme optimizing both torque response and efficiency is proposed. The control is quite different than the conventional field-oriented or direct torque control. First, the produced torque is an explicitly continuous output variable of control. Second, a new rotor flux observer, which allows speed sensorless operation of IM by low and zero speed, was developed. A new stator and rotor flux controller/observer based on the continuous sliding mode and Lyapunov theory are developed. The proposed robust control scheme allows a smooth transition into the field weakening region and the full utilization of the inverter current and voltage capability during acceleration or regenerative braking of EV. The drive system including an 18 kW, 4 pole, 120 V battery-powered IM and a 30 kW IGBT inverter has been applied to a pick up truck (EV).
Keywords :
Lyapunov methods; control system synthesis; electric vehicles; induction motors; machine theory; machine vector control; observers; torque control; traction motors; variable structure systems; velocity control; 120 V; 18 kW; 30 kW; IGBT inverter; Lyapunov theory; acceleration; continuous sliding mode theory; control design; control performance; control simulation; efficiency optimisation; electric vehicles; field weakening region; inverter current capability; inverter voltage capability; regenerative braking; robustness; rotor flux observer; speed sensorless torque control; stator flux observer; torque response optimisation; traction induction motors; Acceleration; Induction motors; Insulated gate bipolar transistors; Inverters; Robust control; Rotors; Sensorless control; Sliding mode control; Stators; Torque control;
Conference_Titel :
Advanced Motion Control, 2002. 7th International Workshop on
Print_ISBN :
0-7803-7479-7
DOI :
10.1109/AMC.2002.1026923
