A Novel Application of Network Equivalencing Method in Time Domain to Precise Calculation of Dead Time in Power Transmission Title
Authors: J. Moshtagh, L. Eslami
Abstract:
Various studies have showed that about 90% of single line to ground faults occurred on High voltage transmission lines have transient nature. This type of faults is cleared by temporary outage (by the single phase auto-reclosure). The interval between opening and reclosing of the faulted phase circuit breakers is named “Dead Time” that is varying about several hundred milliseconds. For adjustment of traditional single phase auto-reclosures that usually are not intelligent, it is necessary to calculate the dead time in the off-line condition precisely. If the dead time used in adjustment of single phase auto-reclosure is less than the real dead time, the reclosing of circuit breakers threats the power systems seriously. So in this paper a novel approach for precise calculation of dead time in power transmission lines based on the network equivalencing in time domain is presented. This approach has extremely higher precision in comparison with the traditional method based on Thevenin equivalent circuit. For comparison between the proposed approach in this paper and the traditional method, a comprehensive simulation by EMTP-ATP is performed on an extensive power network.
Keywords: Dead Time, Network Equivalencing, High Voltage Transmission Lines, Single Phase Auto-Reclosure.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1336082
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[1] Bowler, C. E. J.; Brown, P. G.; walker, D. N.; "Evaluation of The Effect of Power Circuit Break Reclosing Practices on Turbine-Generator Shaft,” IEEE Trans. Power App. Syst., vol. PAS-99, p.p. 1764-1779, 1980.
[2] Vahidi, B.; Jannati, M.; Hosseinian, S. H.; "A Novel Approach to Adaptive Single Phase Autoreclosure Scheme for EHV Power Transmission Lines Based on Learning Error Function of ADALINE” SIMULATION. vol. 84, p.p. 601-610, 2008.
[3] Jannati, M.; Vahidi, B.; Hosseinian, S. H.; Baghaee, H. R.; "A New Adaptive Single Phase Auto-Reclosure Scheme for EHV Transmission Lines” Power System Conference, MEPCON. 12th International Middle-East (IEEE), p.p. 203 – 207, 2008.
[4] Irisarri, G.; Sasson, A. M.; Dopazo, J. F.; "Real-Time External System Equivalent for on-Line Contingency Analysis”, IEEE Transactions on Power Apparatus and Systems, vol. PAS-98, p.p. 2153-2171, 1979.
[5] Abur, A.; Singh, H.; "Time domain modeling of external systems for electromagnetic transients programs”, Power Systems, IEEE Transactions on, vol. 8, p.p. 671 – 679, 1993.
[6] Semlyen, A.; Iravani, M. R.; "Frequency domain modeling of external systems in an Electro-Magnetic Transients Program”, Power Systems, IEEE Transactions on, vol. 8, p.p. 527-533, 1993.
[7] Debs, A. S.; "Estimation of external network equivalents from internal system data”, IEEE Transactions on Power Apparatus and Systems, vol. 94, p.p. 273-279, 1975.
[8] Xin Nie.; Yuan Chen.; Dinavahi, V.; "Real-time transient simulation based on a robust two layer network equivalent”, Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century, IEEE, 2008.
[9] Miu, K. N.; Yiming Mao.; "Network equivalent models for short circuit analysis”, Power Engineering Society Winter Meeting, IEEE, vol. 2, p.p. 862-865, 2002.
[10] Ibrahim, A. I.; Salama, M. M. A.; "Frequency dependent network equivalent for AC power systems using the QZ algorithm” Conference on Electrical and Computer Engineering, Canadian, vol. 1, p.p. 56-59, 1995.
[11] Noda, T.; "Identification of a multiphase network equivalent for electromagnetic transient calculations using partitioned frequency response” Power Engineering Society General Meeting, IEEE, vol. 2, 2005.
[12] Boaventura, W. C.; Semlyen, A.; Iravani, M. R.; Lopes, A.; "Sparse Network Equivalent Based on Time-Domain Fitting” Power Engineering Review, IEEE, vol. 21, 2001.
[13] Jun-Hee Hong.; Jong-Keun Park.; "A time-domain approach to transmission network equivalents via Prony analysis for electromagnetic transients analysis”, IEEE Transactions on Power Systems, vol. 10, p.p. 1789 – 1797, 1995.
[14] Noda, T.; "A Binary Frequency-Region Partitioning Algorithm for the Identification of a Multiphase Network Equivalent for EMT Studies” IEEE Transactions on Power Delivery, vol. 22, p.p. 1257-1258, 2007.
[15] Ibrahim, A. I.; Salama, M. M. A.; "Frequency dependent network equivalent algorithm for AC power systems”, Conference on Electrical and Computer Engineering, Canadian, vol. 2, p.p. 639 – 642, 1996.
[16] Sang-Pil Ahn.; Chul-Hwan Kim.; Aggarwal, R. K.; Johns, A. T.; "An alternative approach to adaptive single pole auto-reclosing in high voltage transmission systems based on variable dead time control” IEEE Transactions on Power Delivery, vol. 16, p.p. 676-686, 2001.
[17] Ahn, S. P.; Aggarwal, R. K.; Johns, A. T.; "An Alternative Approach to Adaptive Single-Pole Auto Reclosing in High-Voltage Transmission Systems Based on Variable Dead Time Control”, Power Engineering Review, IEEE, vol. 21, p.p. 70-70, 2001.
[18] Jannati, M.; Vahidi, B.; Hosseinian, S. H.; Baghaee, H. R.; "A novel approach for optimizing dead time of extra high voltage transmission lines”, Conference on Optimization of Electrical and Electronic Equipment, OPTIM. 11th International, p.p. 215-220, 2008.
[19] Sanaye-Pasand, M.; kadivar, A.; "Design of An Online Adaptive Auto-Reclose Algorithm for HV Power transmission lines,” IEEE Power India Conferen