A voltage-behind-reactance induction machine model for the EMTP-Type solution. Wang, L. & Jatskevich, J. In 2009 IEEE Power & Energy Society General Meeting, pages 1-1, July, 2009.
doi  abstract   bibtex   
Recently, there has been renewed interest in modeling of electrical machines for the EMTP-type programs, with the goal of improving the machine-network interface. In this paper, we present a new voltage-behind-reactance induction machine model for the EMTP-type solution and power system transients. In the proposed model, the stator circuit is represented in phase coordinates and the rotor subsystem is expressed in arbitrary reference frame. Similar to the recently proposed synchronous-machine voltage-behind-reactance model and the established phase-domain model, simultaneous solution of the machine-network electrical variables is achieved. Efficient numerical implementation of the proposed model is presented, in which one time-step requires as little as 108 flops, taking 1.6 mirco-second of CPU time. Case studies of induction machine start-up transients demonstrate that the proposed model is more accurate and efficient than several existing EMTP machine models.
@INPROCEEDINGS{5275842,
  author={Wang, Liwei and Jatskevich, Juri},
  booktitle={2009 IEEE Power & Energy Society General Meeting}, 
  title={A voltage-behind-reactance induction machine model for the EMTP-Type solution}, 
  year={2009},
  volume={},
  number={},
  pages={1-1},
  abstract={Recently, there has been renewed interest in modeling of electrical machines for the EMTP-type programs, with the goal of improving the machine-network interface. In this paper, we present a new voltage-behind-reactance induction machine model for the EMTP-type solution and power system transients. In the proposed model, the stator circuit is represented in phase coordinates and the rotor subsystem is expressed in arbitrary reference frame. Similar to the recently proposed synchronous-machine voltage-behind-reactance model and the established phase-domain model, simultaneous solution of the machine-network electrical variables is achieved. Efficient numerical implementation of the proposed model is presented, in which one time-step requires as little as 108 flops, taking 1.6 mirco-second of CPU time. Case studies of induction machine start-up transients demonstrate that the proposed model is more accurate and efficient than several existing EMTP machine models.},
  keywords={Voltage;Induction machines;Power system modeling;Power system transients;Stators;Circuits;EMTP},
  doi={10.1109/PES.2009.5275842},
  ISSN={1932-5517},
  month={July},}
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