https://scholars.lib.ntu.edu.tw/handle/123456789/438577
標題: | New Fourier filter algorithm for series compensated transmission lines | 作者: | Yu C.-S. CHIH-WEN LIU Yang J.-Z. JOE-AIR JIANG |
關鍵字: | decaying dc component; Discrete Fourier Transform; series compensated lines; sub-synchronous frequency component | 公開日期: | 2002 | 卷: | 4 | 起(迄)頁: | 2556 - 2560 | 來源出版物: | PowerCon 2002 - 2002 International Conference on Power System Technology, Proceedings | 會議論文: | International Conference on Power System Technology, PowerCon 2002 | 摘要: | In protection relaying schemes, the discrete Fourier transform (DFT) is the most widely used algorithm for computing the fundamental frequency components. When the measurements only contain fundamental frequency and integer harmonic frequency components, the conventional DFT only need "one-cycle post-fault data amounts" to compute the fundamental frequency component. However, in series compensated lines, the voltage and current signals both contain large sub-synchronous frequency and decaying DC components during the fault interval. These abnormal components involved in measurements will extremely postpone the convergent speed of the conventional DFT algorithm. Different from the ideal "one-cycle post-fault data amounts" of the ideal cases, the conventional DFT need "5-10 cycles post-fault data amounts" (for decay DC component) or "10-20 cycles post-fault data amounts" (for sub-synchronous frequency component) to compute the convergent fundamental frequency component. The vital slow convergency will extremely reduce the accuracy and response time of the following fault locator or other installations in the relaying schemes. In order to overcome the above problems, this paper presents a new Fourier filter algorithm for series compensated transmission lines. Via the proposed algorithm, the convergent fundamental frequency components can be computed in only "2-3.5 cycles post-fault data amounts", even the decaying DC or sub-synchronous frequency components involved in measurements. Meanwhile, the resolution of the A/D converters and the effects of the low-pass filter are also considered in the investigations. Since the proposed algorithm effectively suppresses the abnormal frequency components, not only the fundamental frequency components but also the following fault location computations all can be achieved very fast. EMTP generated data using a 300 km, 345 kV series compensated transmission line has tested the performance of the proposed algorithm. The tested cases include various fault types, fault locations, fault resistances, fault inception angles, etc. Simulation results indicate that the proposed algorithm can achieve up to 99.95% accuracy for most tested cases. © 2002 IEEE. |
URI: | https://www2.scopus.com/inward/record.uri?eid=2-s2.0-84975474886&doi=10.1109%2fICPST.2002.1047247&partnerID=40&md5=95664ce044565d31239451bd1b25bbf0 | ISBN: | 0780374592; 9780780374591 | DOI: | 10.1109/ICPST.2002.1047247 | SDG/關鍵字: | Analog to digital conversion; Discrete Fourier transforms; Electric fault location; Electric lines; Low pass filters; Natural frequencies; Relay control systems; Decaying DC components; Fault inception angles; Fundamental frequencies; Integer harmonic frequency; Protection relayings; Series compensated lines; Series compensated transmission lines; Sub-synchronous; Fourier series |
顯示於: | 生物機電工程學系 |
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