• DocumentCode
    1353110
  • Title

    Effects of broken bars/end-ring connectors and airgap eccentricities on ohmic and core losses of induction motors in ASDs using a coupled finite element-state space method

  • Author

    Bangura, J.F. ; Demerdash, N.A.

  • Author_Institution
    Dept. of Electr. & Comput. Eng., Marquette Univ., Milwaukee, WI, USA
  • Volume
    15
  • Issue
    1
  • fYear
    2000
  • fDate
    3/1/2000 12:00:00 AM
  • Firstpage
    40
  • Lastpage
    47
  • Abstract
    In this paper, effects of rotor abnormalities such as broken squirrel-cage bars, broken cage connectors and airgap eccentricity on ohmic and core losses of induction motors are presented. In this investigation, a comprehensive time-stepping coupled finite element-state space (TSCFE-SS) model was fully utilized to compute the time-domain elemental flux density waveforms and various time-domain waveforms of motor winding currents useful for core loss and ohmic loss computations. Such investigation is feasible by use of the TSCFE-SS model due to its intrinsic nature and characteristics. The results obtained from the simulations of an example 1.2-hp induction motor clearly indicate that faults due to broken squirrel-cage bars/end-connectors can increase motor core losses in comparison to the healthy case. The results also give the effect of saturation on the core loss distributions within the cross-section of the motor, and indicate the potential for possible excessive loss concentrations and consequent hot spots near zones of bar and connector breakages in the rotor
  • Keywords
    electrical faults; finite element analysis; induction motor drives; losses; magnetic cores; rotors; squirrel cage motors; state-space methods; time-domain analysis; variable speed drives; 1.2 hp; adjustable speed drives; airgap eccentricities; broken bars; broken squirrel-cage bars; core losses; coupled finite element-state space method; end-ring connectors; hot spots; induction motors; motor winding currents; ohmic losses; rotor abnormalities; saturation effect; time-domain elemental flux density waveforms; time-domain waveforms; time-stepping coupled finite element-state space model; Bars; Connectors; Core loss; Couplings; Finite element methods; Hysteresis motors; Induction motors; Magnetic flux; Reluctance motors; Rotors;
  • fLanguage
    English
  • Journal_Title
    Energy Conversion, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0885-8969
  • Type

    jour

  • DOI
    10.1109/60.849114
  • Filename
    849114