Title :
Sensorless position control of induction motors-an emerging technology
Author_Institution :
Wuppertal Univ., Germany
fDate :
31 Aug-4 Sep 1998
Abstract :
Concepts for the sensorless position control of induction motor drives rely on anisotropic properties of the machine rotor. Such anisotropies can be incorporated as periodic variations of magnetic saliencies in various ways. The built-in spatial anisotropy is detected by injecting a high-frequency flux wave into the stator. The resulting stator current harmonics contain frequency components that depend on the rotor position. Models of the rotor saliency serve to extract the rotor position signal using phase-locked loop techniques. A different approach makes use of the parasitic effects that originate from the discrete winding structure of a cage rotor. It has the merit of providing high spatial resolution for incremental positioning without sensor. The practical implementation of sensorless position identification, and of a high-accuracy position control system are reported
Keywords :
control system synthesis; induction motor drives; machine theory; machine vector control; position control; rotors; stators; cage rotor; control design; discrete winding structure; emerging technology; high-accuracy position control system; high-frequency flux wave injection; incremental positioning; induction motor drives; magnetic saliencies; parasitic effects; phase-locked loop techniques; rotor anisotropy; rotor position signal; sensorless position control; sensorless position identification; spatial anisotropy; stator current harmonics; Anisotropic magnetoresistance; Frequency; Induction motor drives; Magnetic anisotropy; Magnetic flux; Perpendicular magnetic anisotropy; Phase locked loops; Position control; Rotors; Stators;
Conference_Titel :
Industrial Electronics Society, 1998. IECON '98. Proceedings of the 24th Annual Conference of the IEEE
Conference_Location :
Aachen
Print_ISBN :
0-7803-4503-7
DOI :
10.1109/IECON.1998.723873
