استراتژی نوین برای کنترل فیلترهای اکتیو CSI و VSI و مقایسهی این دو نوع فیلتر
محورهای موضوعی : فیلتر اکتیوغلامرضا عرب مارکده 1 , سمیه یاراحمدی 2 , جعفر سلطانی 3
1 - دانشیار - دانشکده فنی و مهندسی، عضو قطب علمی آنالیز غیرخطی، بهینهسازی و کنترل، دانشگاه شهرکرد
2 - کارشناس ارشد – دانشکده مهندسی برق، دانشگاه شهرکرد
3 - استاد – دانشکده برق، دانشگاه صنعتی اصفهان
کلید واژه: اینورتر منبع جریان, فیلتر اکتیو, اینوتر منبع ولتاژ, بار غیرخطی, کنترل حالت لغزشی,
چکیده مقاله :
اخیراً برای حذف هارمونیکها و ارتقاء ضریب توان در شبکههای قدرت، فیلترهای اکتیو مورد توجه فراوان قرار گرفتهاند. از مزایای این گونه فیلترها، حجم کمتر و مشخصات جبران کنندگی بهتر آنها نسبت به فیلترهای پسیو است. در این مقاله استراتژی کنترلی نوین برای دو نوع فیلتر اکتیو VSI و CSI پیشنهاد شده است و سپس این دو نوع فیلتر از نظر میزان کاهش THD جریان بارغیرخطی مورد مقایسه گرفتهاند. استراتژی کنترلی پیشنهادی برای فیلتر اکتیو VSI مبتنی بر علامتهای لغزش و منبع جریان و استراتژی کنترلی پیشنهادی فیلتر اکتیو CSI فقط مبتنی بر علامت لغزش است. کلیهی شبیهسازیها در محیط MATLAB/Simulink انجام گرفته است. نتایج شبیهسازی نشان میدهد که روشهای کنترلی پیشنهادی برای هر دو نوع فیلتر بهتر از روشهای کنترلی قبلی میباشد و فیلتر اکتیو CSI عملکرد بهتری نسبت به فیلتر اکتیو VSI با در نظر گرفتن ناحیهی مرده (برای جلوگیری از اتصال کوتاه شدن منبع) دارد
Recently to eliminate the harmonics and improve the power factor of the power networks, much attention has been attracted to active filters. The advantages of these filters are lower volume and their better compensating characteristics than the passive filters. In conventional sliding mode controllers, the source current waveform is fluctuated in near to zero values. In this paper, using a new sliding technique, lower Total Harmonic Distortion (THD) in source current is obtained and the current waveform is improved. As well as, two novel control strategies for two types of active filters, VSI and CSI is proposed and then these two types of filters are compared to reduce THD value of source current.The proposed controlled strategies are simulated by MATLAB/Simulink. The Simulation results confirm that the proposed strategies reduce the THD of source current more than other strategies, and active filter based on CSI has a better performance than active filter based on VSI with a dead time area (for avoiding short circuit of the source) in high powers.
[1] V. Pires, J. Silva, "A current source active power filter controlled by a sliding mode approach", Proceeding of the IEEE/EPEPEMC, Vol. 1, pp, 1654-1659, Portoroz, Aug. 2006.
[2] K. Firouzjah, A. Sheikholeslami, M.R. Karami-Mollaei, F. Heydari, "A predictive current control method for shunt active filter with windowing based wavelet transform in harmonic detection", Simulation Modelling Practice and Theory, Vol. 17, No. 5, pp. 883-896, 2009.
[3] N. Mendalek, K. Al-Haddad, H.Y. Kanaan, G.Hassoun, "Sliding mode control of three-phase four-leg shunt active power filter", Proceeding of the IEEE/PESC, Vol. 1, pp. 4362-4367, June. 2008.
[4] W.R. Nogueira Santos, E.R. Cabral da Silva, C. Brandao Jacobina, E. de Moura Fernandes, A. Cunha Oliveira, R. Rocha Matias, D. Franca Guedes Filho, O.M. Almeida, P. Marinho Santos,"The transformerless single-phase universal active power filter for harmonic and reactive power compensation", IEEE Trans. on Power Electronics, Vol. 29, No. 7, pp. 3563-3572, July 2014.
[5] M. Ch. Jiang, Ch. M. Wang, Sh. Sh. Perng, H.K. Fu, M.L. Tsai, K.Y. Lu, “A novel single-phase soft-switching unipolar PWM shunt active power filter”, Proceeding of the IEEE/ICIEA, pp. 2081-2086, Singapore, July. 2012.
[6] J.J.E. Slotine, W. Li, Applied nonlinear control, Prentice-Hall Englewood Cliffs, NJ, 1991.
[7] B. Singh, K. Al-Haddad, A. Chandra, "A review of active filters for power quality improvement", IEEE Trans. on Industrial Electronics, Vol. 46, No. 5, pp. 960-971, Oct. 1999.
[8] A. Massoud, S.J. Finney, B.W. Williams, "Review of harmonic current extraction techniques for an active power filter", Proceeding of the IEEE/ICHQP, pp. 154-159, Sep. 2004.
[9] F.R. Jimenez Lopez, C.A., E. Forero, "Current and voltage harmonics acquisition and obtaining reference currents for an single phase shunt active power filter", Proceeding of the IEEE/PEPQA, pp. 1-8, Bogota, July. 2013.
[10] Z. Wei-ping, Z. Wei-ping, L. Da-ming, W. Zheng-guo, X. Li, Y. Xuan-fang, "The optimization-sliding mode control for three-phase three-wire DSP-based active power filter", Proceeding of the IEEE/IPEMC, Vol. 3, pp. 1-5, Shanghai, Aug. 2006.
[11] M. El-Habrouk, M.K. Darwish, P. Mehta, "Active power filters: A review", Proceeding of the IEE/EPA, Vol. 147, No. 5, pp. 403-413, 2000.
[12] N. Mohan, T.M. Undeland, W.P. Robbins, "Power electronics: Convertors, applications and design", New York Chichester Brisbane Toronto Singapore, 2002.
[13] F.P. Souza, I. Barbi, "Power factor correction of linear and non-linear loads employing a single phase active power filter based on a full-bridge current source inverter controlled through the sensor of the AC mains current", Proceeding of the IEEE/PESC, Vol. 99, pp. 387-392, Charleston, SC, Aug. 1999.
[14] O.S. Yu, N.J. Park, D.S. Hyun, "A novel fault detection scheme for voltage fed PWM inverter", Proceeding of the IEEE/IECON, pp. 2654-2659, Paris, Nov. 2006.
[15] R. Ribeiro, F. Profumo, C.B. Jacobina, G. Griva, E. Da Silva, A. Lima, G. Penneta, "Two fault tolerant control strategies for shunt active power filter systems", IEEE/IECON, Vol. 1, pp. 792-797, Nov. 2002.
[16] B.R. Lin, D.J. Chen, "Single-phase neutral point clamped AC/DC Converter with the function of power factor corrector and active filter", Proceeding of the IEE/EPA,Vol. 149, No. 1, pp. 19-30, Jan. 2002.
[17] R. Costa-Castelló, R. Grinó, E. Fossas, "Odd-harmonic digital repetitive control of a single-phase current active filter", Power Electronics, IEEE Trans., Vol. 19, No. 4, pp. 1060-1068, July. 2004.
[18] A. Bhat, P. Agarwal, "A fuzzy logic controlled three-phase neutral-point clamped bidirectional PFC rectifier", IEEE, Conf., pp. 238-244, Dec. 2007.
[19] S. Saad, L. Zellouma, "Fuzzy logic controller for three-level shunt active filter compensating harmonics andreactive power", Electric Power Systems Research, Vol. 79, pp. 1337-1341, 2009.
[20] H. Usman, H. Hizam, M.A.M. Radzi, "Simulation of single-phase shunt active power filter with fuzzy logic controller for power quality improvement", Proceeding of the IEEE/CEAT, pp. 353 – 357, Lankgkawi, Nov. 2013.
[21] L. Zellouma, S. Saad, "Fuzzy logic controller for three-phase shunt active filter compensating harmonics and reactive power simultaneously", Proceedings of the ICCIM, Setif, Algeria, pp. 03-04, 2007.
[22] J. Matas, L.G. de Vicuña, J. Miret, J.M. Guerrero, M. Castilla, "Feedback linearization of a single-phase active power filter via sliding mode control", IEEE. Trans. on Power Electronics, Vol. 23, pp. 116-125, Jan, 2008.
[23] M.H. Antchev, M.P. Petkova, V.T. Gurgulicov, "Sliding mode control of a single-phase series active power filter", Proceeding of the IEEE/EURCON, pp. 1344-1349, Warsaw, Sep. 2007.
[24] S. Sladic, M. Odavic and Z. Jakopovic, "Single phase active power filter", Proceeding of the IEEE/MELECON, Vol. 3, pp. 1133-1136, May 2004.
[25] M. Nayeripour, A. Yazdian, M. Mohamadian, "Optimization of an improved sliding mode controller for shunt active power filter", Proceeding of the IEEE/POWERENG, pp. 42-47, April. 2007.
[26] D. Stanciu, M. Teodorescu, A. Florescu, D.A. Stoichescu, "Single- phase active power filter with improved sliding mode control", Proceeding of the IEEE/AQTR, Vol. 1, pp. 1-5, Cluj-Napoca, May 2010.
[27] V.I. Utkin, Sliding modes in control and optimization, Springer-Verlag Berlin, 1992.
[28] S. George, V. Agarwal, "A DSP based optimal algorithm for shunt active filter under nonsinusoidal supply and unbalanced load conditions", IEEE Trans on Power Electronics, Vol. 22, No. 2, pp. 593-601, March. 2007.
[29] H. Komurcugil, O. Kukrer, "A robust current control strategy for single-phase shunt active power filters", Proceeding of the IEEE/IECON, Vol. 3, pp. 2277-2281, Nov. 2003.
_||_