Recent Trends in Analog Design and Digital Devices

Due to their dependability, low cost, and robustness, induction motors are the most widely used electrical motors. However, induction motors is a constant speed machine; hence it speed control is difficult. Electric drive system is increasingly required to meet the higher performance and reliability requirement of motors used in industrial applications. This work presents speed control of a three-phase induction motor with constant voltage frequency (v/f) ratio scheme with peripherial intergral (PI ) controller. In this method of constant v/f ratio, by use of rectifier and pulse width modulation (PWM) inverter, the supply voltage as well as the supply frequency is varied such that the voltage and frequency ratio of the motor remains constant and the flux remains constant too. Dynamic equations of the motor were written as well as the steady state equation based on Parks two-axis theorem. The equations were validated in MATLAB.  With reference speed of 1500 rpm at diiferent load, results shows that the maximum torque of the motor remains unchanged at different operating zone for various speeds and given load, the maximul torque being 2.2 Nm at steady state opration. The work was done using a three-phase, 4-pole 50Hz, 155 volts, 1.8 kW induction motor.

Malik, N. R. (2012). Analysis and control aspects of brushless induction machines with Rotating Power Electronic Converters (Doctoral dissertation, PhD thesis, Royal Institute of Technology, Stockholm, Sweden).

Bechir, R. E. B. H. I., Mabrouka, L. A. A. B. I. D. I., & Mohamed, E. L. L. E. U. C. H. (2013). Boosting the induction motor with the Technique of discrete frequency control. Journal of Electrical Engineering, 13(2), 9-9.

Aspalli, M. S., Kumar, V., & Hunagund, P. V. Development and Analysis of Variable Frequency Three Phase Induction Motor Drive. IJ-ETA-ETS, 3(2), 129-195.

Samuel, J. D., Braide, S. L., & Idoniboyeobu, D. C. (2020). Performance Evaluation of Three Phase Induction Motor in Arbitrary Reference Frame. GSJ, 8(12).

Aspalli, M. S., Asha, R., & Hunagund, P. V. (2012). Three phase induction motor drive using IGBTs and constant V/F method. International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering, 1(5), 463-469.

Obuah, E. C., Inyenemi, M. (2018). Effect of design parameters on the performance of three-phase induction motor. International Journal of Electrical Machines and Drives, 4(1).

Luo, X., Liao, Y., Toliyat, H. A., El-Antably, A., & Lipo, T. A. (1995). Multiple coupled circuit modeling of induction machines. IEEE Transactions on industry applications, 31(2), 311-318.

Levi, E., Lamine, A., & Cavagnino, A. (2006). Impact of stray load losses on vector control accuracy in current-fed induction motor drives. IEEE Transactions on energy conversion, 21(2), 442-450.

Qu, Z., Ranta, M., Hinkkanen, M., & Luomi, J. (2012). Loss-minimizing flux level control of induction motor drives. IEEE Transactions on industry applications, 48(3), 952-961.

Tir, Z., Malik, O. P., & Eltamaly, A. M. (2016). Fuzzy logic based speed control of indirect field oriented controlled Double Star Induction Motors connected in parallel to a single six-phase inverter supply. Electric Power Systems Research, 134, 126-133.