Authors: O. S. Ebrahim, M. A. Badr, A. S. Elgendy, K. O. Shawky, P. K. Jain

Abstract:

This paper demonstrates an improved Loss Model Control (LMC) for a 3-phase induction motor (IM) driving pump load. Compared with other power loss reduction algorithms for IM, the presented one has the advantages of fast and smooth flux adaptation, high accuracy, and versatile implementation. The performance of LMC depends mainly on the accuracy of modeling the motor drive and losses. A loss-model for IM drive that considers the surplus power loss caused by inverter voltage harmonics using closed-form equations and also includes the magnetic saturation has been developed. Further, an Artificial Neural Network (ANN) controller is synthesized and trained offline to determine the optimal flux level that achieves maximum drive efficiency. The drive’s voltage and speed control loops are connecting via the stator frequency to avoid the possibility of excessive magnetization. Besides, the resistance change due to temperature is considered by a first-order thermal model. The obtained thermal information enhances motor protection and control. These together have the potential of making the proposed algorithm reliable. Simulation and experimental studies are performed on 5.5 kW test motor using the proposed control method. The test results are provided and compared with the fixed flux operation to validate the effectiveness.

Keywords: Artificial neural network, ANN, efficiency optimization, induction motor, IM, Pulse Width Modulated, PWM, harmonic losses.

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 274

References:

[1] US Department of Energy, Lawrence Berkeley National Laboratory, “Variable speed pumping: A guide to successful applications,” 2004.
[2] Y. Jiang; W. Wu; Y. He; H. Chung; and F. Blaabjerg, “New Passive Filter Design Method for Overvoltage Suppression and Bearing Currents Mitigation in a Long Cable Based PWM Inverter-Fed Motor Drive System,” IEEE Trans. on Power Electronics, Vol. 32, Issue 10, pp. 7882-7893, 2017.
[3] O. S. Ebrahim, K. O. Shawky, M. A. Badr, P. K. Jain, “An Induction Motor Drive System with Intelligent Supervisory Control for Water Networks Including Storage Tank,” World Academy of Science, Engineering and Technology Inter. Journal of Mechanical and Industrial Eng.,, Vol. 17, No. 3, 2023.
[4] I. Kioskesidis and N. Margaris, “Loss minimization in scalar controlled induction motor drives with search controller,” IEEE Trans. Power Electron., vol. 11, no. 2, pp. 213-220, 1996.
[5] B. K. Bose, N. R. Patel, and K. Rajashekara, “A neuro-fuzzy-based on-line efficiency optimization control of a stator flux-oriented direct vector-controlled induction motor drive,” IEEE Trans. Ind. Electron., vol. 44, no. 2, pp. 270-273, Apr. 1997.
[6] M. N. Uddin and S. W. Nam, “New online loss minimization-based control of an induction motor drive,” IEEE Trans. Power Electron., vol. 23, no. 2, pp. 926-033, Mar. 2008.
[7] H. Rasmussen, P. Vadstrup, and H. Borsting, “Rotor field oriented control with adaptive iron loss compensation,” in Proc. IEEE IAS Ann. Meeting, vol. 2, pp. 1253–1258, Oct. 1999.
[8] F. Fernandez-Bernal, A. Garcia-Cerrada, and R. Faure, “Model based loss minimization for DC and AC vector-controlled motors including core saturation,” IEEE Trans. Ind. Appl., vol. 36, no. 3, pp. 755–763, May/Jun. 2000.
[9] C. Chakraborty and Y. Hori, “Fast efficiency optimization techniques for the indirect vector-controlled induction motor drives,” IEEE Trans. Ind. Appl., vol. 39, no. 4, pp. 1070–1076, Jul./Aug. 2003.
[10] S. K. Sul and M. H. Park, “A novel technique for optimal efficiency control of a current-source inverter-fed induction motor,” IEEE Trans. Power Electron., vol. 3, no. 2, pp. 192-199, Apr. 1988.
[11] I. Kioskeridis and N. Margaris, “Loss minimization induction motor adjustable-speed drives,” IEEE Trans. Ind. Elec., vol. 43, no. 1, pp. 226-231, Feb. 1996.
[12] F. Abrahamsen, F. Blaabjerg, J. K. Pedersen, and P. B. Thoegersen, “Efficiency-optimized control of medium-size induction motor drives,” IEEE Trans. Ind. Appl., vol. 37, no. 6, pp. 1761–1767, Nov./Dec. 2001.
[13] T. W. Jian, N. L. Schmitz, and D. W. Novotny, “Characteristic induction motor slip values for variable voltage part load performance optimization,” IEEE Trans. Power App. Sysr., vol. PAS-102, no. 1, pp. 38-46, Jan. 1984.
[14] C. A. Hernandez-Aramburo, T. C. Green, and S. Smith, “Assessment of power losses of an inverter-driven induction machine with its experimental validation,” IEEE Trans. Ind. Appl., vol. 39, no. 4, pp. 994-1004, July/Aug. 2003.
[15] A. Boglietti, P. Ferraris, M. Lazzari and F. Profumo, “Effects of different modulation index on the iron losses in soft magnetic materials supplied by PWM inverter,” IEEE Trans. Magn., vol. 29, no. 6, pp. 3234-3236, Nov. 1993.
[16] A. Boglietti, “PWM Inverter fed induction motor losses evaluation,” Electric Machines and Power Systems, no. 22, pp. 439-449, 1994.
[17] O. S. Ebrahim, A. S. Elgendy, M. A. Badr, and P. K. Jain," ANN-Based Optimal Energy Control of Induction Motor in Pumping Applications," IEEE Trans. on Energy Conversion, no.3.1, Oct. 2010.
[18] H. M. Jabr and N. C. Kar, “Leakage flux saturation effects on the transient performance of wound-rotor induction motors,” Elsevier Electr. Power Sys. Research, vol. 78, no. 7, 1280–1289, 2008.
[19] R. Kaczmarek, M. Amar, and F. Protat, “Iron loss under PWM voltage supply on Epstein frame and in induction motor core,” IEEE Trans. Magn., vol. 32, no. 1, pp. 189-194, Jun. 1996.
[20] M. G. Say, "Alternating Current Machines", John Wiley & Sons, 5th edition, 1968.
[21] H. Zhao; C. Liu; Y. Zhan; and G. Xu,’ Loss and Starting Performance of Inverter-Fed Induction Motors Considering Semi-Closed Effect of Closed Slot,’ 2019 Inter. Applied Computational Electromagnetics Society Symposium (ACES), 2019.
[22] Bin Chen,’ Analysis of Effect of Winding Interleaving on Leakage Inductance and Winding Loss of High Frequency Transformers,’ Journal of Electrical Engineering & Technology, vol. 14, pp.1211–1221, 2019.
[23] D. G. Holmes and T. A. Lipo, “Pulse width modulation of power converters: Principles and practice,” IEEE Press Series on Power Eng., John Wiley, 2003.
[24] J. A. Snyman, “Practical mathematical optimization: an introduction to basic optimization theory and classical and new gradient-based algorithms,” Springer Publishing, 2005.
[25] Bimal K. Bose, “Neural network applications in power electronics and motor drives—An introduction and perspective,” IEEE Trans. Ind. Electron., vol. 54, no. 1, pp. 14-33, Feb. 2007.
[26] P. Vas, “Artificial intelligence-based electrical machines and drives: Application of fuzzy, neural, fuzzy neural, and genetic algorithm based techniques,” Oxford Science Publications, Oxford university press, 1999.
[27] MathWorks Neural Network Toolbox User’s Guide, 2001.
[28] J. R. Pottebaum, “Optimal characteristics of a variable-frequency centrifugal pump motor drive,” IEEE Trans. Ind. Appl., vol. IA-20, no. 1 , pp. 23-31, Jan./Feb. 1984.
[29] N. Mohan, T. M. Undeland, and W. P. Robbins, ‘Power Electronics: Converters, Applications, and Design,’ 3rd Ed., Wiley publisher, 2002.
[30] Hitachi L100 Series Inverter Manual, 2002.
[31] K. Smith and S. Jain, "The Necessity and Challenges of Modeling and Coordinating Microprocessor Based Thermal Overload Functions for Device protection," The 70 Ann. Conf. On Protective Relay Engineers (CPRE), 2017.
[32] J. Holtz, 'Sensorless control of induction motor drives,' Proc. of the IEEE, Vol. 90, Issue 8, 2002.