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Metody stosowane w analizie awaryjnych wyłączeń w sieci elektroenergetycznej

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Warianty tytułu
EN
The Methods Used in Contingency Analysis of an Electrical Network
Języki publikacji
PL
Abstrakty
PL
W artykule zostanie przedstawiona metoda wyznaczania mocy gałęziowej po wyłączeniu jednego, dwóch lub trzech dowolnych elementów sieci elektroenergetycznej. W metodzie tej moc gałęziowa jest obliczana bez konieczności ponownego wyznaczania macierzy admitancyjnej i jej odwracania po każdym wyłączeniu. Następnie zostanie zaprezentowana metoda sprawdzania spójności grafu rozważanej sieci po analizowanych wyłączeniach.
EN
The paper will present a branch power calculation method after switching off one, two or three chosen electrical network elements. In this method the branch power is calculated without having to reassess the admittance matrix and inverse it every time after switching off. Next, a method assessing the graph connectivity of an analysed network after switching off will be presented.
Rocznik
Strony
94--97
Opis fizyczny
Bibliogr. 36 poz.
Twórcy
autor
  • Politechnika Łódzka, Instytut Elektroenergetyki, ul. Stefanowskiego 18/22, 90924 Łódź
Bibliografia
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  • [2] Chakrabarti A., Halder S, Power System Analysis: Operation and Control, PHI Learning Pvt. Ltd., (2010), 1270
  • [3] PSS™E 31.0 User’s Manual, Siemens Power Transmission & Distribution, Inc., Power Technologies International, (2007)
  • [4] Wai Y. Ng, Generalized Generation Distribution Factors for Power System Security Evaluations, IEEE Trans. on Power App. and Systems, Vol. PAS-100, (1981), 1001-1005
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  • [6] Davis C. M., Overbye J., Multiple Element Contingency Screening, IEEE Trans. on Power Systems, Vol. 26, (2011), 1294-1301
  • [7] Ricardo R. Austria, XiaokangXu, Michael Power, Voltage Stability Assessment of The National Grid System Using Modern Analytical Tools,Transmission and Distribution Conference and Exposition IEEE/PES, (2001), 229-234
  • [8] CapitanescuF., Van CutsemT., Preventive Control of Voltage Security Margins: A Multicontingency Sensitivity-Based Approach, IEEE Trans. on Power Systems, Vol. 17, (2002), 358-364
  • [9] Ozdemir A., Jae Yun Lim, Chanan Singh, Branch Outage Simulation for MVAR Flows: Bounded Network Solution, IEEE Trans. on Power Systems, Vol. 18, (2003), 1523-1528
  • [10] Yorino N., Li H. Q., Harada S., Ohta A., Sasaki H., A Method of Voltage Stability Evaluation for Branch and Generator Outage Contingencies, IEEE Trans. on Power Systems, Vol. 19, (2004), 252-259
  • [11] EchavarrenF.M., Lobato E., Rouco L., Contingency analysis: feasibility identification and calculation algorithm, IEE Proc.-Gener. Transm. Distrib., Vol. 152, (2005), 645-652
  • [12] RuizP.A. , SauerP.W., Voltage and Reactive Power Estimation for Contingency Analysis Using Sensitivities, IEEE Trans. on Power Systems, Vol. 22, (2007), No. 2,
  • [13] Flueck A. J., Gonella R., Jayabharath R. D., A New Power Sensitivity Method of Ranking Branch Outage Contingencies for Voltage Collapse, IEEE Trans. on Power Systems, Vol. 17, (2002), 265-270
  • [14] BhavikSuthar, Balasubramanian R., A New Approach to Real Time Line Outage Contingency Analysis for Voltage Secure Operation of Power Systems, Power System Technology and IEEE Power India Conference, (2008)
  • [15] MeliopoulosA. P., Power System Modeling, Analysis and Control, Marcel Dekker Inc., (2004), 652
  • [16] MoranteQ., RanaldoN., VaccaroA., ZimeoE., Pervasive Grid for Large-Scale Power Systems Contingency Analysis, IEEE Trans. on Power App. and Industrial Informatics, Vol. 2, (2006), 165-175
  • [17] Yousu Chen, Zhenyu Huang, Chavarría-MirandaD., Performance Evaluation of Counter-Based Dynamic Load Balancing Schemes for Massive Contingency Analysis with Different Computing Environments, IEEE Power and Energy Society General Meeting,(2010), 1-6
  • [18] Binh Dam Q., Meliopoulos A. P., HeydtG.T., Bose A., A Breaker-Oriented, Three-Phase IEEE 24-Substation Test System, IEEE Trans. on Power Systems, Vol. 25, (2010), 59-67
  • [19] LourençoE. M., CostaA.S., RibeiroR.P., Steady-State Solution for Power Networks Modeled at Bus Section Level, IEEE Trans. on Power Systems, Vol. 25, (2010), 10-20
  • [20] EjebeG.C., Wollenberg B.F., Automatic Contingency Selection, IEEE Trans. on Power App. and Systems, Vol. PAS- 98, (1979), 97-109
  • [21] ZaborskyJ., WhangK.W., Prasad K., Fast Contingency Evaluation Using Concentric Relaxation, IEEE Trans. on Power App. and Systems, Vol. PAS-99, (1980), 28-36
  • [22] LaubyM.G., MikolinnasT.A., Reppen N.D., Contingency Selection of Branch Outages Causing Voltage Problems, IEEE Trans. on Power App. and Systems, Vol. PAS- 102, (1983), 3899-3904
  • [23] GalianaF.D., Bound Estimates of Severity of Line Outages in Power System Analysis and Ranking, IEEE Trans. on Power App. and Systems, Vol. PAS-103, (1984), 2612-2624
  • [24] Brandwajn V., Efficient Bounding Method for Linear Contingency Analysis, IEEE Trans. on Power Systems, Vol. PWRS-3, (1988), 38-43
  • [25] EjebeG.C., Van MeeterenH.P., Wollenberg B.F., Fast Contingency Screening and Evaluation for Voltage Security Analysis, IEEE Trans. on Power Systems, Vol. PWRS-3, (1988), 1582-1590
  • [26] LaubyM.G., Evaluation of a Local DC Load Flow Screening Method for Branch Contingency Selection of Overloads, IEEE Trans. on Power Systems, Vol. PWRS-3, (1988), 923-928
  • [27] Brandwajn V., LaubyM.G., Critical Review of Branch Contingency Selection Methods, IFAC Symposium on Power Systems and Power Plant Control, (1989), 22-24
  • [28] Brandwajn V., LaubyM.G., Complete Bounding Method for AC Contingency Screening, IEEE Trans. on Power Systems, Vol. PWRS-4, (1989), 724-729.
  • [29] Bacher R.,Tinney W., Faster Local Power Flow Solutions: The Zero Mismatch Approach, IEEE Trans. on Power Systems, Vol. PWRS-4, (1989), 1345-1362
  • [30] Chen Y., Bose A., Direct Ranking for Voltage Contingency Selection, IEEE Trans. on Power Systems, Vol. PWRS-4, (1989), 1335-1344
  • [31] Chen Y., Bose A., An Adaptive Pre-Filter fot the Voltage Contingency Selection Function, IEEE Trans. on Power Systems, Vol. 5, (1990), 1478-1486
  • [32] ZhihongJia, Jeyasurya B., Contingency Ranking for On-Line Voltage Stability Assessment, IEEE Trans. on Power Systems, Vol. 15, (2000), 1093-1097
  • [33] HedmanK.W., O’Neill R.P., Fisher E.B., Oren S..S., Optimal Transmission Switching With Contingency Analysis, IEEE Trans. on Power Systems, Vol. 24, (2009), 1577-1586
  • [34] Jin Tao Ma, Xiaodong Liu, HemantaSinha, Janet Luciano, VasiliosTsolias, User Experiences with Contingency Analysis at NSTAR, IEEE Power and Energy Society General Meeting, (2012), 1-8
  • [35] Gorton I., Zhenyu Huang, Yousu Chen, Benson Kalahar, Shuangshuang Jin, Daniel Chavarría-Miranda, Baxter D., Feo J., A High-Performance Hybrid Computing Approach to Massive Contingency Analysis in the Power Grid, Fifth IEEE International Conference on e-Science, (2009), 277-283
  • [36] Lachs W. R., Controlling Grid Integrity After Power System Emergencies, IEEE Trans. on Power Systems, Vol. 17, (2002), 445-450
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f405173b-caf1-44de-9d37-d3aa6781f977
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