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PIER PIER B PIER C PIER M PIER Letters
2012-11-30
Simulation of the Bearing Voltage in an Inverter-Fed Induction Motor by a Full Three Phase Multi Conductor Transmission Line Model
By
Biagio De Vivo,

    Dr. Biagio De Vivo

    University of Salerno

    Italy

    Homepage

Patrizia Lamberti,

    Prof. Patrizia Lamberti

    University of Salerno

    Italy

    Homepage

Vincenzo Tucci,

    Prof. Vincenzo Tucci

    Electrical and Information Engineering

    University of Salerno

    Italy

    Homepage

Carlo Petrarca

    Dr. Carlo Petrarca

    University of Naples

    Italy

    Homepage

Progress In Electromagnetics Research B, Vol. 46, 233-250, 2013
doi:10.2528/PIERB12090605 | Google Scholar

Abstract
An accurate numerical model, based on multiconductor transmission lines (MTL) able to evaluate the voltage dynamics across the motor bearings and associated currents of an inverter-fed motor is presented. A full three phase stator winding of the wound type of a high power traction motor is considered in the proposed analysis. The different regions of the motor are modeled as suitable connections of lossy MTL which are then studied in the time domain. The per unit length characteristic matrices describing the MTL are accurately calculated by a FEM based software. The effects of the rise time of the input voltage and the length of the feeder cables are discussed. The reliability of the numerical results achieved by means of the MTL model is checked by performing a comparison with those obtained by considering a lumped parameter equivalent circuit.
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Citation
Biagio De Vivo, Patrizia Lamberti, Vincenzo Tucci, and Carlo Petrarca, "Simulation of the Bearing Voltage in an Inverter-Fed Induction Motor by a Full Three Phase Multi Conductor Transmission Line Model," Progress In Electromagnetics Research B, Vol. 46, 233-250, 2013.
doi:10.2528/PIERB12090605
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