Abstract
In case of an internal ideal cable fault, the voltage will instantaneously drop in the faulted phase at the fault location. This is equivalent to applying a voltage impulse equal, but with opposite sign to that existing on the faulted phase at the time of fault. The study of how high frequency impulses propagate on a crossbonded system is therefore interesting for fault location purposes and is studied in this chapter.
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References
C.K. Jung., J.B. Lee, Fault location algorithm on underground power cable systems using noise cancellation technique. in Transmission and Distribution Conference and Exposition, 2008, pp 1–7. IEEE/PES, April 2008
L.M. Wedepohl, D.J. Wilcox, Transient analysis of underground power-transmission systems: system-model and wave-propagation characteristics. Proc. Inst. Electr. Eng. 120(2), 253–260 (1973)
L.M. Wedepohl, Application of matrix methods to the solution of travelling-wave phenomena in polyphase systems. Proc. Inst. Electr. Eng. 110(12), 2200–2212 (1963)
L.M. Wedepohl, Electrical characteristics of polyphase transmission systems with special reference to boundary-value calculations at power-line carrier frequencies. Proc. Inst. Electr. Eng. 112(11), 2103–2112 (1965)
A. Ametani, Wave propagation characteristics of cables. IEEE Trans. Power Apparatus Syst. PAS 99(2), 499–505 (1980)
H.W. Dommel, Digital computer solution of electromagnetic transients in single-and multiphase networks. IEEE Trans. Power Apparatus Syst. PAS 88(4), 388–399 (1969)
A. Ametani, A general formulation of impedance and admittance of cables. IEEE Trans. Power Apparatus Syst. PAS 99(3), 902–910 (1980)
H.M.J.S.P. De Silva, Accuracy and Stability Improvments in Electromagnetic Simulations of Power Transmission Lines and Cables. (University of Manitoba, Canada, 2008)
L.M. Wedepohl, H.V. Nguyen, D.A. Irwin, Frequency-dependent transformation matrices for untransposed transmission lines using newton-raphson method. IEEE Trans. Power Syst. 11(3), 1538–1546 (1996)
N. Nagaoka, A. Ametani, Transient calculations on crossbonded cables. IEEE Trans. Power Apparatus Syst. PAS 102(4), 779–787 (1983)
Y. Itoh, N. Nagaoka, A. Ametani, Transient analysis of a crossbonded cable system underneath a bridge. IEEE Trans. Power Delivery 5(2), 527–532 (1990)
U.S. Gudmundsdottir, B. Gustavsen, C.L. Bak, W. Wiechowski, Field test and simulation of a 400-kv cross-bonded cable system. IEEE Trans. Power Delivery 26(3), 1403–1410 (2011)
L. Marti, Simulation of transients in underground cables with frequency-dependent modal transformation matrices. IEEE Trans. Power Delivery 3(3), 1099–1110 (1988)
U.S. Gudmundsdottir, Modeling of Long High Voltage AC Cables in Transmission Systems, 2nd edn. (Energinet.dk, Denmark, 2010). ISBN 978-87-90707-73-6
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Jensen, C.F. (2014). Wave Propagation on Three Single-Core Solid-Bonded and Crossbonded Cable Systems. In: Online Location of Faults on AC Cables in Underground Transmission Systems. Springer Theses. Springer, Cham. https://doi.org/10.1007/978-3-319-05398-1_6
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DOI: https://doi.org/10.1007/978-3-319-05398-1_6
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