Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements

Roumeliotis, Georgios; Desmet, Jan; Ameele, Sean; Knockaert, Jos

Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements

Georgios Roumeliotis (UGent) , Jan Desmet (UGent) , Sean Ameele and Jos Knockaert (UGent)

(2021) CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution. p.810-814

Author

Georgios Roumeliotis (UGent) , Jan Desmet (UGent) , Sean Ameele and Jos Knockaert (UGent)

Organization

Department of Electromechanical, Systems and Metal Engineering

Abstract

The first step in modelling a real grid in the frequency range 2–500 kHz is discussed in this paper. The distributed parameters of the equivalent transmission line (TL) model are determined combining the benefits of three techniques: Four-terminal (4T) sensing is used to evaluate resistances, time-domain reflectometry (TDR) to determine lengths of cables, and impedance (Z) measurements to estimate inductances and capacitances. Finally, a measurement of the network impedance is performed in order to have a more complete view of the behaviour of the network.

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Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-8722159

MLA: Roumeliotis, Georgios, et al. “Distributed Properties of Multi-Conductor Low Voltage Cables at 2-500 KHz : Network Analysis by Four-Terminal Sensing, Time-Domain Reflectometry and Impedance Measurements.” CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution, IET, 2021, pp. 810–14, doi:10.1049/icp.2021.2038.
APA: Roumeliotis, G., Desmet, J., Ameele, S., & Knockaert, J. (2021). Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements. CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution, 810–814. https://doi.org/10.1049/icp.2021.2038
Chicago author-date: Roumeliotis, Georgios, Jan Desmet, Sean Ameele, and Jos Knockaert. 2021. “Distributed Properties of Multi-Conductor Low Voltage Cables at 2-500 KHz : Network Analysis by Four-Terminal Sensing, Time-Domain Reflectometry and Impedance Measurements.” In CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution, 810–14. IET. https://doi.org/10.1049/icp.2021.2038.
Chicago author-date (all authors): Roumeliotis, Georgios, Jan Desmet, Sean Ameele, and Jos Knockaert. 2021. “Distributed Properties of Multi-Conductor Low Voltage Cables at 2-500 KHz : Network Analysis by Four-Terminal Sensing, Time-Domain Reflectometry and Impedance Measurements.” In CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution, 810–814. IET. doi:10.1049/icp.2021.2038.
Vancouver: 1.
Roumeliotis G, Desmet J, Ameele S, Knockaert J. Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements. In: CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution. IET; 2021. p. 810–4.
IEEE: [1]
G. Roumeliotis, J. Desmet, S. Ameele, and J. Knockaert, “Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements,” in CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution, Online, 2021, pp. 810–814.

@inproceedings{8722159,
  abstract     = {{The first step in modelling a real grid in the frequency range 2–500 kHz is discussed in this paper. The distributed parameters of the equivalent transmission line (TL) model are determined combining the benefits of three techniques: Four-terminal (4T) sensing is used to evaluate resistances, time-domain reflectometry (TDR) to determine lengths of cables, and impedance (Z) measurements to estimate inductances and capacitances. Finally, a measurement of the network impedance is performed in order to have a more complete view of the behaviour of the network.}},
  articleno    = {{0343}},
  author       = {{Roumeliotis, Georgios and Desmet, Jan and Ameele, Sean and Knockaert, Jos}},
  booktitle    = {{CIRED 2021 - The 26th International Conference and Exhibition on Electricity Distribution}},
  isbn         = {{9781839535918}},
  language     = {{eng}},
  location     = {{Online}},
  pages        = {{0343:810--0343:814}},
  publisher    = {{IET}},
  title        = {{Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements}},
  url          = {{http://doi.org/10.1049/icp.2021.2038}},
  year         = {{2021}},
}

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Distributed properties of multi-conductor low voltage cables at 2-500 kHz : network analysis by four-terminal sensing, time-domain reflectometry and impedance measurements

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