Title :
Low-speed direct-driven sensorless control including zero-speed for switched reluctance motor based on dynamic inductance model
Author :
Xulong Zhang ; Feng Wang ; Xuanqin Wu
Author_Institution :
Dept. of Inf. & Electr. Eng., Xuzhou Inst. of Technol., Xuzhou, China
Abstract :
Accurate and reliable rotor position estimation is extremely required in low-speed direct-driven applications for switched reluctance motor/generator. Due to seriously nonlinearity of phase inductance, phase inductance changes obviously under saturation. On the basis of Fourier analysis, the relationship between dynamic inductance model coefficients and phase current is given. At zero-speed condition, excitation pulse method is proposed for estimate initial rotor position. Dynamic inductance model is proposed for low-speed operation. Sensorless control algorithm is achieved by DSP and FPGA chips. Experimental results indicate that motor start up without inversion at zero speed, sensorless operation error is less than 0.5 degree. The overall sensorless control scheme is easy to implement.
Keywords :
Fourier analysis; digital signal processing chips; field programmable gate arrays; reluctance motors; rotors; sensorless machine control; DSP chips; FPGA chips; Fourier analysis; dynamic inductance model coefficients; excitation pulse method; low-speed direct-driven sensorless control; phase current; phase inductance; rotor position estimation; switched reluctance generator; switched reluctance motor; zero-speed condition; Estimation; Inductance; Rotors; Sensorless control; Switched reluctance motors; Switched Reluctance Motor; dynamic inductance model; low-speed direct-driven; sensorless;
Conference_Titel :
Electrical Machines and Systems (ICEMS), 2014 17th International Conference on
Conference_Location :
Hangzhou
DOI :
10.1109/ICEMS.2014.7013571
