Remote means for fault location determination are intended for finding the most likely fault point and reducing the bypass zone of the line. Methods of improving the accuracy of the calculation of the distance to the fault location (and reducing the inspection zone of the OHL) owing to the use of special digital processing of fault regime oscillogram signals are examined.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
T. Takagi, Y. Yamakoshi, J. Baba, K. Uemura, and T. Sakaguchi, “A new algorithm of an accurate fault location for EHV/UHV transmission lines: part 1. Fourier transformation method,” IEEE Trans. Power App. Syst., PAS-100(3), 1316 – 1323 (1981).
T. Takagi, Y. Yamakoshi, J. Baba, K. Uemura, and T. Sakaguchi, “A new algorithm of an accurate fault location for EHV/UHV transmission lines: part II. Laplace transform method,” IEEE Trans. Power App. Syst., PAS-101(3), 564 – 573 (1982).
A. Girgis, D. Hart, and W. Peterson, “A new fault location technique for two- and three-terminal lines,” IEEE Trans. Power Delivery, 7(Jan), 98 – 107 (1992).
D. Novosel, D. G. Hart, E. Udren, and A. Phadke, “Accurate fault location using digital relays,” in: ICPST Conf., pp. 1120 – 1124 (1994).
E. A. Arzhannikov, Distance Principle in Relay Protection and Automatics of Power Transmission Lines in the Presence of Faults to Ground [in Russian], Énergoatomizdat, Moscow (1985).
Yu. Ya. Lyamets, V. A. Il’in, and N. V. Podshivalin, “Software for analyzing emergency processes and determining the location of a fault an electric power transmission line,” Élektrichestvo, No. 12, 2 – 7 (1996).
A. N. Visyashchev (ed.), Diagnostics of 10 – 110 kV Electric Power Air Lines in Normal and Fault Regimes [in Russian], Izd. IrGTU, Irkutsk (2012).
M. Abe, T. Emura, N. Otsuzuki, and M. Takeuchi, “Development of a new fault location system for multi-terminal single transmission lines,” IEEE Trans. Power Delivery, 10(Jan.), 159 – 168 (1995).
J.-A. Jiang, J.-Z. Yang, Y.-H. Lin, C.-W. Liu, and J.-C. Ma, “An adaptive PMU based fault detection/location technique for transmission lines part I: Theory and algorithms,” IEEE Trans. Power Delivery, 15(Apr.), 486 – 493 (2000).
Technical manual ABB 1MRK 505 344-UEN. Line differential protection RED670 2.1 IEC (2015), ABB Inc., Sweden; on-line http://new.abb.com.
A. L. Kulikov and M. D. Obalin, “Use of adaptive procedures in algorithms determining fault locations in OHL,” Promyshl. Énerget., No. 12, 35 – 39 (2013).
A. L. Kulikov, M. D. Obalin, and P. A. Kolobanov,” Izv. Vuzov. Élektromekhanika, No. 5, 57 – 62 (2013).
A. L. Kulikov, P. A. Kolobanov, and V. A. Fal’shina, “Simplified digital measuring organs of distance protection,” Promyshl. Énerget., No. 12, 30 – 35 (2013).
G. Benmouyal, “An Adaptive Sampling Interval Generator for Digital Relaying,” IEEE Trans. Power Delivery, 4(3), 1602 – 1609 (1989).
A. L. Kulikov, V. A. Fal’shina, and P. A. Kolobanov, “Algorithms for suppressing aperiodic component in the fault currents,” Élektrichestvo, No. 11, 26 – 35 (2014).
Operation Manual, Certificate. Indicator of Microprocessor Fixing IMF-3R Radius Avtomatika [in Russian], Izd. ZAO “Radius Avtomatika,” Moscow (2009).
User Manual BRS-0030.01-D001 PPO: Software System WinBres Version 3, Izd. NPP Bresler , Cheboksary (2011); on-line http://xn--btbma3aioaldi.xn-p1ai/en.
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Élektricheskie Stantsii, No. 4, March, 2016, pp. 39 – 44.
Rights and permissions
About this article
Cite this article
Kulikov, A.L., Obalin, M.D. & Petrova, V.A. Application of Digital Signal Processing to Improve the Accuracy of Fault Location Determination in Power Transmission Lines on the Basis of Fault Regime Parameters. Power Technol Eng 50, 332–336 (2016). https://doi.org/10.1007/s10749-016-0707-6
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10749-016-0707-6