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Model for three-phase induction motors with stator core faults

Model for three-phase induction motors with stator core faults

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  • Author(s): P.M. de la Barrera 1, 2 ; G.R. Bossio 1, 2 ; J.A. Solsona 1, 3 ; G.O. Garcı́a 1, 2
    • View affiliations
    • Affiliations: 1: Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), Argentina
      2: Grupo de Electrónica Aplicada (GEA), Facultad de Ingenierı́a, UNRC, Rı́o Cuarto, Argentina
      3: Departamento de Ingenierı́a Eléctrica y de Computadoras, Instituto de Investigaciones en Ingenierı́a Eléctrica ‘Alfredo Desages’, Bahı́a Blanca, Argentina
  • Source: Volume 4, Issue 8, September 2010, p. 591 – 602
    DOI:  10.1049/iet-epa.2009.0281 , Print ISSN 1751-8660, Online ISSN 1751-8679
© The Institution of Engineering and Technology
Published

A new dynamic model for an induction motor (IM) in abc machine variables is proposed in this work. This model is able to represent asymmetrical stator core faults (SCF) by modelling them as the variation of the equivalent core loss resistance per phase. One model in qd0 variables and another one in sequence components are deduced and used as tools to analyse and simulate SCF. It is demonstrated that there is a good correlation between SCF severity and the magnitude of the IM stator negative sequence current, impedance and power. The comparison of simulation and experimental results suggests the validity of the theoretical proposal.

Inspec keywords: induction motors; fault diagnosis

Other keywords: induction motor stator negative sequence current; three-phase induction motors; abc machine variables; equivalent core loss resistance; asymmetrical stator core faults

Subjects: Asynchronous machines

References

    1. 1)
      • J. Yun , K. Lee , K. Lee , S.B. Lee , J. Yoo . Detection and classification of stator turn faults and high resistance electrical connections for induction machines. IEEE Trans. Ind. Appl. , 2 , 666 - 675
    2. 2)
      • H.A. Toliyat , G.B. Kliman . (2004) Handbook of electric motors.
    3. 3)
      • Kliman, G.B., Shah, M.R., Lee, S.B.: `Differential sensor apparatus and method for laminated core fault detection', US Patent, , March 2005.
    4. 4)
      • A. Ordaz-Moreno , R.J. Romero-Troncoso , J.A. Vite-Frias , J.R. Rivera-Gillen , A. Garcia-Perez . Automatic online diagnosis algorithm for broken-bar detection on induction motors based on discrete wavelet transform for FPGA implementation. IEEE Trans. Ind. Electron. , 5 , 2193 - 2202
    5. 5)
      • C. Yung . Fit to the core: advantages of a novel method for stator core repair. IEEE Ind. Appl. Mag. , 6 , 54 - 61
    6. 6)
      • Kliman, G.B., Shah, M.R.: `Method and system for detecting core faults', US Patent, , December 2002.
    7. 7)
      • A. Moses , H. Rahmatizadeh . Effects of stress on iron loss and flux distribution of an induction motor stator core. IEEE Trans. Magn. , 5 , 4003 - 4005
    8. 8)
      • P.C. Krause . (1995) Analysis of electric machinery.
    9. 9)
      • H. Akagi , E.H. Watanabe , M. Aredes . (2007) Instantaneous power theory and applications to power conditioning.
    10. 10)
      • K. Lee , J. Hong , K.-W. Lee , S.B. Lee , E. Wiedenbrug . A stator-core quality-assessment technique for inverter-fed induction machines. IEEE Trans. Ind. Appl. , 1 , 213 - 221
    11. 11)
      • Bourgeois, J.M., Lalonde, F.: `Apparatus and method for evaluation a condition of a magnetic circuit of an electric machine', , November 1999, US Patent.
    12. 12)
      • G.C. Paap . Symmetrical components in the time domain and their application to power network calculations. IEEE Trans. Power Syst. , 2 , 522 - 528
    13. 13)
      • G.R. Bossio , C.H. De Angelo , J.M. Bossio , C.M. Pezzani , G.O. García . Separating broken rotor bars and load oscillations on IM fault diagnosis through the instantaneous active and reactive currents. IEEE Trans. Ind. Electron. , 4571 - 4580
    14. 14)
      • de la Barrera, P.M., Bossio, G.R., Solsona, J.A., García, G.O.: `Stator core fault diagnosis for induction motors based on parameters adaptation', Seventh IEEE Int. Symp. on Diagnostics for Electric Machines, Power Electronics and Drives (SDEMPED 2009), Cargèse, August–September 2009, France.
    15. 15)
      • M. Drif , A.J.M. Cardoso . Airgap-eccentricity fault diagnosis, in three-phase induction motors, by the complex apparent power signature analysis. IEEE Trans. Ind. Electron. , 3 , 1404 - 1410
    16. 16)
      • G.O. García , J.C. Mendes Luís , R.M. Stephan , E.H. Watanabe . An efficient controller for an adjustable speed induction motor drive. IEEE Trans. Ind. Electron. , 5 , 533 - 539
    17. 17)
      • J. Cusidó , L. Romeral , J.A. Ortega , J.A. Rosero , A.G. Espinosa . Fault detection in induction machines using power spectral density in wavelet decomposition. IEEE Trans. Ind. Electron. , 2 , 633 - 643
    18. 18)
      • IEEE Std. 432-1992: ‘IEEE guide for insulation maintenance for rotating electric machinery (5 hp to less than 10 000 hp)’, 1992.
    19. 19)
      • G. Ridley . EL CID test evaluation, 1984-96. Power Eng. J. , 21 - 26
    20. 20)
      • J. Yun , J. Cho , S.B. Lee , J. Yoo . Online detection of high–resistance connections in the incoming electrical circuit for induction machines. IEEE Trans. Ind. Appl. , 2 , 694 - 702
    21. 21)
      • Sutton, J.: `Method and apparatus for testing laminated cores of electrical machines', US Patent, , June 2003.
    22. 22)
      • McKinnon, D., Seyoum, D., Grantham, C.: `Investigation of parameter characteristics for induction machine analysis and control', Second Int. Conf. on Power Electronics, Machines and Drives, (PEMD 2004), 31 March–2 April 2004, 1, p. 320–325.
    23. 23)
      • A.M. da Silva , R.J. Povinelli , N.A.O. Demerdash . Induction machine broken bar and stator short-circuit fault diagnostics based on three-phase stator current envelopes. IEEE Trans. Ind. Electron. , 3 , 1310 - 1318
    24. 24)
      • S.B. Lee , R.M. Tallam , T.G. Habetler . A robust, on-line turn-fault detection technique for induction machines based on monitoring the sequence component impedance matrix. IEEE Trans. Power Electron. , 3 , 865 - 872
    25. 25)
      • P.J. Tavner , A.F. Anderson . Core fault in large generators. IEE Proc., Electr. Power Appl. , 6 , 1427 - 1439
    26. 26)
      • García, G.O., Santisteban, J., Brignone, S.: `Iron losses influence on a field-oriented controller', 20thInt. Conf. on Industrial Electronics, Control and Instrumentation, IECON 94, September 1994, Bologna, Italy, p. 633–638.
    27. 27)
      • E. Levi . Impact of iron loss on behavior of vector controlled induction machines. IEEE Trans. Ind. Appl. , 6 , 1287 - 1296
    28. 28)
      • B. Ayhan , H.J. Trussell , M.-Y. Chow , M.-H. Song . On the use of a lower sampling rate for broken rotor bar detection with DTFT and AR-based spectrum methods. IEEE Trans. Ind. Electron. , 3 , 1421 - 1434
    29. 29)
      • E. Levi , M. Sokola , A. Boglietti , M. Pastorelli . Iron loss in rotor-flux-oriented induction machines: identification, assessment of detuning, and compensation. IEEE Trans. Power Electron. , 5 , 698 - 709
    30. 30)
      • de la Barrera, P.M., Curti, M.R., Bossio, G.R., Solsona, J.A., García, G.O.: `Experimental generation and quantification of stator core faults on induction motors', The Seventh IEEE Int. Symp. on Diagnostics for Electric Machines, Power Electronics and Drives (SDEMPED 2009), August–September 2009, Cargèse, France.
    31. 31)
      • S.B. Lee , G.B. Kliman , M.R. Shah . Experimental study of inter–laminar core fault detection techniques based on low flux core excitation. IEEE Trans. Energy Convers. , 1 , 85 - 94
    32. 32)
      • IEEE Std. 112-1996: ‘IEEE Standard test procedure for polyphase induction motors and generators’, 1996.
    33. 33)
      • H. Su , K.T. Chong . Induction machine condition monitoring using neural network modeling. IEEE Trans. Ind. Electron. , 1 , 241 - 249
    34. 34)
      • J. Sottile , J.L. Kohler . An on-line method to detect incipient failure of turn insulation in random-wound motors. IEEE Trans. Energy Convers. , 4 , 762 - 768
    35. 35)
      • P.M. de la Barrera , G.R. Bossio , J.A. Solsona , G.O. García . On-line iron loss resistance identification by a state observer for rotor-flux-oriented control of induction motor. Energy Convers. Manag. , 10 , 2742 - 2747
    36. 36)
      • Bossio, G.R., De Angelo, C.H., Donolo, P.D., Castellino, A.M., García, G.O.: `Effects of voltage unbalance on IM power, torque and vibrations', Seventh IEEE Int. Symp. on Diagnostics for Electric Machines, Power Electronics and Drives (SDEMPED 2009), August–September 2009, Cargèse, France.
    37. 37)
      • E. Watanabe , R. Stephan , M. Aredes . New concepts of instantaneous active and reactive powers in electrical systems with generic loads. IEEE Trans. Power Delivery , 2 , 697 - 703
    38. 38)
      • R.M. Tallam , S.B. Lee , G. Stone . A survey of methods for detection of stator-related faults in induction machines. IEEE Trans. Ind. Appl. , 4 , 920 - 933
    39. 39)
      • C. Yung , A.H. Bonnett . Repair or replace? A decision model for industrial electric motors. IEEE Ind. Appl. Mag. , 5 , 48 - 58
    40. 40)
      • Z. Posedel . Inspection of stator core in large machines with a low yoke induction method-measurement and analysis of interlamination short-circuits. IEEE Trans. Energy Convers. , 1 , 81 - 86
    41. 41)
      • T. Sato , Y. Sakaki . Physical meaning of equivalent loss resistance of magnetic cores. IEEE Trans. Magn. , 5 , 2894 - 2897
    42. 42)
      • S.B. Lee , G.B. Kliman , M.R. Shah , N.K. Nair , R.M. Lusted . An iron core probe based inter–laminar core fault detection techniques for generator stator cores. IEEE Trans. Energy Convers. , 2 , 344 - 351
    43. 43)
      • M. Enokizono , H. Shimoji , T. Horibe . Effect of stator construction of three-phase induction motors on core loss. IEEE Trans. Magn. , 3 , 1484 - 1487
    44. 44)
      • M. Blodt , D. Bonacci , J. Regnier , M. Chabert , J. Faucher . On-line monitoring of mechanical faults in variable-speed induction motor drives using the Wigner distribution. IEEE Trans. Ind. Electron. , 2 , 522 - 533
    45. 45)
      • G.B. Kliman , S.B. Lee , M.R. Shah , R.M. Lusted , N.K. Nair . A new method for synchronous generator core quality evaluation. IEEE Trans. Energy Convers. , 3 , 576 - 582
    46. 46)
      • M. Arkan , D.K. Perović , P. Unsworth . Online stator fault diagnosis in induction motors. IEE Proc.-Electr. Power Appl. , 6 , 537 - 547
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