Modelling of Wave Processes on Power Transmission Lines to Improve the Accuracy of Fault Location1

S. Lin S, Z. Y. He, X. P. Li, and Q. Q. Qian, “Travelling wave time-frequency characteristic-based fault location method for transmission lines,” IET Gener. Transm. Distrib., No. 6 (2012).

Zhang Yi-ning, Liu Yong-hao, Xu Min, and Cai Ze-xiang, “A novel algorithm for HVDC line fault location based on variant travelling wave speed,” in: 4th Int. Conf. “Electric Utility Deregulation and Restructuring and Power Technologies” (2011).

A. L. Kulikov and V. V. Anan’ev, “Adaptive wave determination of fault locations in electric power transmission lines,” Vestnik Ivanovsk. Gos. Énerget. Univ., No. 4 (2014).

A. L. Kulikov and V. V. Anan’ev, “Use of simulation modelling for increasing the accuracy of wave determinations of fault location in electric transmission lines,” Releishchik, No. 2 (2014).

D. M. Obalin and A. L. Kulikov, “Use of adaptive procedures in algorithms for determination of fault location electric transmission lines,” Promyshl. Énerget., No. 12 (2013).

X. Cai, G. Song, S. Gao, J. Suonan, and G. Li, “A fault-location method for VSC-HVDC transmission lines based on natural frequency of current,” Proc. Chinese Soc. Electr. Eng., 31(28) (2011).

O. M. K. K. Nanayakkara, A. D. Rajapakse, and R. Wacha, “Travelling-wave-based line fault location in star-connected multiterminal HVDC systems,” IEEE Trans. Power Deliv., 27(4) (2012).

X. Kong, Z. Zhang, X. Yin, and X. Deng, “Application of Hilbert– Huang transformation for identifying the fault location on series compensated lines,” Przeglad Elektrotechn., 89(6) (2013).

X. Fan and Y. Zhu, “A novel fault location scheme for multi-terminal transmission lines based on principle of double-ended traveling wave,” Power Syst. Technol., 37(1) (2013).

F. V. Lopes, D. Fernandes, and W. L. A. Neves, “A Travelling-Wave Detection Method Based on Park’s Transformation for Fault Locators,” IEEE Trans. Power Deliv., 28 (3) (2013).

E. E. Ngu and K. Ramar, “A combined impedance and travelling wave based fault location method for a multi-terminal transmission lines,” Int. J. Electr. Power Energy Syst., 33(10) (2011).

BRS-07.090T-D001 RÉ. Bresler-0107.090 microprocessor device for determining fault location. Operating instructions [in Russian], Izd. NPP “Bresler,” Cheboksary (2013).

Zeng Xiangjun, K. K. Li, Liu Zhengyi, and Yin Xianggen, “Fault location using traveling wave for power networks,” in: 39th IAS Annual Meeting, IEEE Conference Record “Industry Applications Conference,” Vol. 4 (2004).

F. Deng, X. Zeng, Z. Bo, S. Ma, S. Zhou, “An improved network-based traveling wave fault location method,” in: Power and Energy Engineering Conf., Asia-Pacific (2011).

Zeng Xiangjun, Xia Yunfeng, Ma Hongjiang, and Wang Yuanyuan, “Grounding Faulted Feeder Detection Methods Applied in Chinese Ineffectively Earthed Distribution System,” in: Conf. Rec. of the IEEE Industry Appl. Conf. (2007).

Traveling wave fault location in power transmission systems: a white paper, 5900 Southwest Parkway, Suite 210 Austin, Texas 78735.

B. Wang, B. Wang, X. Dong, T. Cui, K. Lui, R. Cao, T. Huang, and Z. Bo, “HPR7000 traveling wave based fault recording and location system in EHV lines,” in: Int. Conference on Electrical Engineering (2009).

TWS FL-8, Apparatus for determining fault location by a “traveling wave” method, Qualitrol Corporation, document No. 40-08591-01 (2011).

A. L. Kulikov, Remote Fault Detection in Power Transmission Lines by Active Probing Methods [in Russian], Énergoatomizdat, Moscow (2006).