Main inductances of induction motor for diagnostically specialized mathematical models

• Autorzy: Węgiel T. , Weinreb K. , Sułowicz M.
• Języki publikacji: EN

Abstrakty

EN

In the paper modeling of main inductances for mathematical models of induction motors is applied to study the effects caused by a rotor eccentricity and saturation effects. All three possible types of eccentricity: static, dynamic and mixed are modeled. The most important parameters describing rotor eccentricity include self and mutual inductances of the windings. The structural changes of the permeance function as a result of eccentricity appearance and the Fourier spectra of inductances in occurrence of saturation for each case are determined in the paper. The presented algorithm can be used for the diagnostically specialized models of induction motors.

Słowa kluczowe

EN

induction motors; rotor fault diagnosis; rotor eccentricity

PL

silnik indukcyjny; uszkodzenie wirnika; diagnostyka; ekscentryczność wirnika; wirnik

• Wydawca: Polish Academy of Sciences, Committee on Electrical Engineering
• Czasopismo: Archives of Electrical Engineering
• Rocznik: 2010
• Tom: Vol. 59, nr 1-2
• Strony: 51--66
• Opis fizyczny: Bibliogr. 21 poz., rys.

Twórcy

autor

Węgiel T.

autor

Weinreb K.

autor

Sułowicz M.

• Department of Electrical and Computer Engineering, Cracow University of Technology, Cracow,

Bibliografia

• [1] T.J. Sobczyk, P. Drozdowski, Inductances of electrical machine winding with a nonuniform air-gap. Archiv fur Elektrotechnik 76: 213-218 (1993).
• [2] A. Stavron, J. Penman, The on-line quantification of air-gap eccentricity in induction machines. Proc. of ICEM’94, Paris, 2: 261-266 (1994).
• [3] F. Filippetti, G. Franceschini, C. Tassoni, P. Vas, Broken bar detection in induction machines: comparison between current spectrum approach and parameter estimation approach. IEEE 1994 Industry Applications Society Annual Meeting, Denver 1: 95-102 (1994).
• [4] H.A. Toliyat, M.S. Arefeen, A.G. Parlos, A Method for Dynamic Simulation of Air-Gap Eccentricity in Induction Machines. IEEE Trans. on Industry Applications 32(4): 910-918 (1996).
• [5] D.G. Dorrell, W.T. Thomson, S. Roach, Analysis of airgap flux, current, and vibration signals as a function of the combination of static and dynamic airgap eccentricity in 3-phase induction motors. IEEE Trans. on Industry Applications 33(1): 24-34 (1997).
• [6] W.T. Thomson, A. Barbour, C. Tassoni, F. Filipetti, An appraisal of the m.m.f. permeance method and finite element models to study static air gap eccentricity and its diagnosis in induction machines. Proc. of ICEM'98, Istanbul 2182-2187 (1998).
• [7] X. Tu, L.-A. Dessaint; M. El Kahel, A. O. Barry, A New Model of Synchronous Machine Internal Faults Based on Winding Distribution. Industrial Electronics, IEEE Transactions on 53(6): 1818-1828 (2006).
• [8] A. Bellini, G. Franceschini, C. Tassoni, A. Toscani, Assessment of induction machines rotor fault severity by different approaches. 31st Conf. of IEEE IECON’05, Raleigh, North Carolina 1461-1466 (2005).
• [9] S.D. Sudhoff, B.T. Kuhn, K.A. Corzine, B.T. Branecky, Magnetic Equivalent Circuit Modeling of Induction Motors. Energy Conversion, IEEE Transaction on 22: 259-270 (2007).
• [10] S. Bachir, S. Tnani, J.-C. Trigeassou, G. Champenois, Diagnosis by parameter estimation of stator and rotor faults occurring in induction machines. Trans. on Industrial Electronics 53(3): 963-973 (2006).
• [11] J.-H. Jung, J.-J. Lee, B.-H. Kwon, Online Diagnosis of Induction Motors Using MCSA. Industrial Electronics, IEEE Transactions on 53(6), 1842-1852 (2006).
• [12] Xianghui Huang, T.G. Habetler, R.G. Harley, E.J. Wiedenbrug, Using a Surge Tester to Detect Rotor Eccentricity Faults in Induction Motors, Industry Applications. IEEE Transactions on 43(5), 1183-1190 (2007).
• [13] Xiaodong Li, Qing Wu, S. Nandi, Performance Analysis of a Three-Phase Induction Machine With Inclined Static Eccentricity. Industry Applications, IEEE Transactions on 43(2): 531-541 (2007).
• [14] B. Heller, V. Hamata, Harmonic field effects in induction machines. Elsevier Scientific Publishing, Oxford (1977).
• [15] S. Nandi, S. Ahmed, H. Toliyat, Detection of Rotor Slot and Other Eccentricity-Related Harmonics in a Three-Phase Induction Motor with Different Rotor Cages. Power Engineering Review, IEEE 21(9): 62-62 (2001).
• [16] S. Nandi, Modeling of induction machines including stator and rotor slot effects, Industry Applications, IEEE Trans on 40(4): 1058-1065 (2004).
• [17] T.J. Sobczyk, K. Weinreb, T. Węgiel, M. Sułowicz, Theoretical Study of Effects due to Rotor Eccentricities in Induction Motors. Proc. of the 2nd IEEE SDEMPED’99, Gijon, 289-295 (1999).
• [18] J.C. Moreira, T.A. Lipo, Modeling of saturated AC machines including air gap flux harmonic components. IEEE Trans. on Industry Applications 28(2): 343-349 (1992).
• [19] T.J. Sobczyk, K. Weinreb, T. Wegiel, M. Sulowicz, A. Warzecha, Effects in stator currents of cage motors due to saturation of main magnetic circuit. Diagnostics for Electric Machines, Power Electronics and Drives, 2003. SDEMPED 2003. 4th IEEE International Symposium on 81-86 (2003).
• [20] A. Warzecha, T. Węgiel, K. Weinreb, M. Sułowicz, Non-Linear Permeance Function of Magnetic Circuit in Asynchronous Motor with Rotor Eccentricity. Czasopismo Techniczne, Z.5-E/2005, Cracow University of Technology 87-100 (2005).
• [21] S. Nandi, A detailed model of induction machines with saturation extendable for fault analysis. Industry Applications, IEEE Transactions on 40(5): 1302-1309 (2004).