Power Flow Control in the Converters Interconnecting AC-DC Meshed Systems

• Autorzy: Jardini J. A , Sousa T , Romero R. A , Rider M. J , Horita M. A. B , Bassini M , Cavalheiro M. R

Warianty tytułu

PL

Sterowanie przepływem mocy w przekształtniku łączącym sieci DC-AC

• Języki publikacji: EN

Abstrakty

EN

DC grids are being strongly considered as a technology to be used for future expansions of the transmission system. Voltage sourced converters (VSC) are the key equipment considered for AC/DC interconnections. However the flow from DC to AC system has to be properly set as many alternatives exists. In this article, an Optimal Power Flow (OPF) to control the flow of power in the converters interconnecting AC-DC systems is presented. The proposed OPF solution technique was tested using the CIGRE B4 DC Grid Test System.

PL

W artykule opisano sterowanie przepływem mocy w przekształtniku łączącym sieci DC-AC. Optymalny przepływ mocy OPF był testowany w systemie sieciowym CIGRE B4 DC.

Słowa kluczowe

EN

AC-DC grid; power flow control; optimal power flow; VSC converter

PL

sieć AC-DC; sterowanie przepływem mocy; przekształtnik

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2015
• Tom: R. 91, nr 1
• Strony: 46--49
• Opis fizyczny: Bibliogr. 14 poz., rys., tab.

Twórcy

autor

Jardini J. A

• Foundation for the Technological Development of the Engineering Sciences (FDTE)

autor

Sousa T

• Federal University of ABC

autor

Romero R. A

• State University of Sao Paulo

autor

Rider M. J

• State University of Sao Paulo

autor

Horita M. A. B

• Foundation for the Technological Development of the Engineering Sciences (FDTE)

autor

Bassini M

• Foundation for the Technological Development of the Engineering Sciences (FDTE)

autor

Cavalheiro M. R

• Sao Paulo State Power Transmission Company

Bibliografia

• [1] Avaiable in: http://www.friendsofthesupergrid.eu/. Access date: July 12, (2013).
• [2] CIGRE Working Group B4-38, “Modeling and Simulation Studies to be performed during the lifecycle of HVDC Systems”, (2013).
• [3] CIGRE Working Group B4-52, “HVDC Grid Feasibility Study”, Electra, (2013).
• [4] CIGRE Working Group B4-37, “VSC Transmission”, (2005).
• [5] J. Beerten, S. Cole and R. Belmans, "Generalized Steady-State VSC MTDC Model for Sequential AC/DC Power Flow Algorithms", IEEE Transactions on Power Systems, (2012), vol. 27, pp. 821-829.
• [6] Z. Xiao-Ping, "Multiterminal voltage-sourced converter-based HVDC models for power flow analysis", IEEE Transactions on Power Delivery, (2004), vol. 19, pp. 1877-1884.
• [7] M. A. B. Horita, J. A. Jardini, M. T. Bassini, G. Y. Saiki, M. R. Cavalheiro “Load Flow Calculation in a Hybrid AC and DC Grid”, Colloquium HVDC and Power Electronics to Boost Network Performance, October 2-3, (2013), Brasilia - Brazil
• [8] T. K. Vrana, Y. Yang, D. Jovcic, S. Dennetière, J. A. Jardini, H. Saad “The CIGRE B4 DC Grid Test System”, Electra, N. 270, October, (2013).
• [9] G.W. Stagg, A.H. El-Abiad, “Computer Methods in Power System Analysis”, McGraw Hill, (1968).
• [10] Jacobson, B., Westman, B., Bahrman, M. P. “500 kV VSC Transmission System for Lines and Cables”, 2012 San Francisco Colloquium. Advances in Voltage Source Converter Technologies, (2012).
• [11] Knight, M. “Offshore Grid Technology: Technology Options and Practical Issues for Offshore Networks”, Cigré Workshop on Offshore Networks, (2011).
• [12] Fourer, R., Gay, D. M. e Kernighan, B. W. “AMPL: A modeling language for mathematical programming”, CA: Brooks/Cole- Thomson Learning, Pacific Grove, (2003).
• [13] ILOG. “CPLEX Optimization subroutine library guide and reference”, version 11.0, Incline Village, NV, USA, (2008).
• [14] R. H. Byrd, J. Nocedal, and R. A. Waltz, "KNITRO: An Integrated Package for Nonlinear Optimization" in Large-Scale Nonlinear Optimization, G. di Pillo and M. Roma, eds, pp. 35-59 (2006).