D-STATCOM Pulse Selection and Transformer Configuration for Harmonic Elimination

• Autorzy: Hannan M.A.

Warianty tytułu

PL

Dobór liczby pulsów i konfiguracji transformatora kompensatora D-STATCOM - eliminacja wyższych harmonicznych

• Języki publikacji: EN

Abstrakty

EN

The sensitive industrial loads and critical commercial operations suffer from harmonics problems which can cost significant loss per incident based on process down-time, loss production, idle work forces and other factors. To overcome such problems, utility companies have made efforts to improve the quality and reliability of their electric power by introducing distribution static compensator (D-STATCOM). However, up to now, many research are going on D-STATCOM control scheme, suitable pulse and transformer design, dc capacitance effect and involvement with many power quality problems. This paper deals with the modelling and simulations of D-STATCOM model focus with the pulse selection, transformer design configuration and test distribution system. The issue of harmonics in the D-STATCOM is addressed by considering a 24-pulse so as to eliminate the generated harmonics. The harmonics eliminating performance of the D-STATCOM in 12-pulse, 24-pulse and 48-pulse are also investigated.

PL

W artykule opisano budowę modelu i symulacje kompensatora statycznego D-STATCOM. Przedstawiono zagadnienie liczby pulsów, konfiguracji transformatora oraz przeprowadzono testy systemu energetycznego. Analizie poddano zagadnienie eliminacji wyższych harmonicznych w układach 12-, 24- oraz 48-pulsowym.

Słowa kluczowe

EN

D-STATCOM; Pulse selection; harmonics; inverter; transformer; power quality

PL

DSTATCOM; wybór liczby pulsów; harmoniczne; transformator falownikowy; jakość energii

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2012
• Tom: R. 88, nr 11a
• Strony: 210--213
• Opis fizyczny: Bibliogr. 20 poz., tab., rys.

Twórcy

autor

Hannan M.A.

• Universiti Kebangsaan Malaysia,

Bibliografia

• [1] Hannan M. A., Mohamed A., PSCAD/EMTDC Simulation of Unified Series-Shunt Compensator for Power Quality Improvement, IEEE Transaction on Power Delivery, 20(2005), 1650-1656.
• [2] Hannan M. A., Mohamed A., Hussain A., Dabbay M., Development of the USSC Model for Power Quality Mitigation, American Journal of Applied Sciences, 6(2009), 978-986.
• [3] Hannan M. A., Mohamed A., Hussain A., Dabbay M., Power Quality Analysis of STATCOM using Dynamic Phasor Modeling, International Journal of Electric Power System Research, 79(2009), 993-999.
• [4] Dong S., Wang Z., Chen, J. Y., Song Y. H., Harmonic Resonance Phenomena in STATCOM and Relationship to Parameters Selection of Passive Components. IEEE Trans. On Power Delivery 16 (2001), 46-52.
• [5] Hannan M. A., Chan K. W., Modern Power Systems Transients Studies Using Dynamic Phasor Models, The proceeding of the International Conference on Power System Technology, Singapore, 21-24 November 2004, pp 1-5.
• [6] Floricau D., Floricau E., Kisch D., Spataru L., The active-SNPC multilevel converter and its total loss balancing, Electrical Review, 9(2010), 284-288.
• [7] Mohaddes M., Gole A. M., Sladjana M., Steady State Frequency Response of STATCOM. IEEE Transactions on Power Delivery, 16 (2001), 18-23.
• [8] Sutanto D., Snider L. A., Mok K. L., EMTP simulation of a STATCOM using Hysteresis Current Control, IEEE International Conference on Power Electronics and Drive Systems (PEDS), July, Hong Kong, 1999.
• [9] Carlos A. C., Watanabe E. H., Aredes, M., Multi-pulse STATCOM operation under unbalanced voltages, IEEE Power Engineering Society Winter Meeting 1 (2002), 567 –572.
• [10] Peter W. L., A Benchmark System for Simulation of the DSTATCOM, IEEE Transactions on Power Delivery, 12(2002), 496-498.
• [11] Wanki M., Joonki M., Jaeho C., Control of STATCOM Using Cascade Multilevel Inverter for High Power Application, IEEE International Conference on Power Electronics and Drive Sustems (PEDS), July, Hong Kong, 1999, 871-876.
• [12] Moon G. W., Predictive Current Control of Distribution Static Compensator for Reactive Power Compensation. IEE Proceeding of Generation, Transmission and Distribution, 146 (1999): 515-520.
• [13] Garcia-Gonzalez P., Garcia-Cerrada A., Control System for a PWM Based STATCOM, IEEE Transactions on Power Delivery, 15 (2002): 1252-1257.
• [14] Subiyanto, Mohamed A., Hannan M. A., Photovoltaic Maximum Power Point Tracking Controller Using a New High Performance Boost Converter, International Review of Electrical Engineering, 5(2011), 2535-2545.
• [15] Yang H., Lin X., Muhammad K., Chen C., Power balancing control strategies for the cascaded H-bridge multilevel DSTATCOM, Electrical Review, 02(2011), 212-219.
• [16]Yang H., Lin X., A survey of the Smart Grid Technologies: background, motivation and practical applications, Electrical Review, 6(2011), 47-57.
• [17] Singh B., Saha R., Chandra A., Al-Haddad A. K., Static synchronous compensators (STATCOM): a review, IET Power Electronics, 2(2009), 297–324.
• [18] Holmes D. G., cGrath, B. P., Opportunities for Harmonic Cancellation with Carrier-Based PWM for a Two-Level and Multilevel Cascaded Inverters, IEEE Transactions on Industry Applications, 37 (2001), 574 –582.
• [19] Rashid M. H., Spice for Power Electronics and Electric Power, Prentice Hall, Englewood Cliffs, New Jersey 07632, 1993.
• [20] McGranaghan M., Power Quality Standards. Electrotek Concepts Inc., Electrical Contractor Magazine, Power Quality for the Electrical Contractor Course, 1998.