A Robust Deadbeat Control Scheme for Active Power Filter with LCL Input Filter

• Autorzy: Han Y. , Xu L. , Yao G. , Zhou L. , Khan M. , Chen C.

Warianty tytułu

PL

Odporny system sterowania dla aktywnych filtrów energetycznych z wejściowym filtrem LCL

• Języki publikacji: EN

Abstrakty

EN

This paper proposes a novel robust deadbeat control scheme for the active power filter with LCL input filter. The selection of the current loop gain is discussed by using root locus diagram representation to ensure stability of the closed-loop control algorithm. A feed-forward plus feedback control structure is adopted to achieve accurate steady-state performance and fast dynamic response by using the adaptive linear neural network (ANN) harmonic detection scheme. The validity of the control scheme is verified by the extensive simulation and experimental results.

PL

Artykuł przedstawia nowy odporny system sterowania dla aktywnych filtrów energetycznych z wejściowym filtrem LCL. Dobór wzmocnienia pętli prądowej jest analizowany dla zapewnienia stabilności sterowania przy zamkniętej pętli. Zaadaptowano sprzężenie do przodu i sprzężenie zwrotne dla dokładnego osiągnięcia stanu ustalonego i szybkiej odpowiedzi dynamicznej przy wykorzystaniu adaptacyjnej liniowej sieci neuronowej. Jakość sterowania potwierdzono badaniami symulacyjnymi i eksperymentalnymi.

Słowa kluczowe

EN

active power filter; harmonic contamination; robust deadbeat control; digital signal processor

PL

filtry aktywne; zakłócenia; harmoniczne

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2010
• Tom: R. 86, nr 2
• Strony: 14--19
• Opis fizyczny: Bibliogr. 31 poz., rys., wykr.

Twórcy

autor

Han Y.

autor

Xu L.

autor

Yao G.

autor

Zhou L.

autor

Khan M.

autor

Chen C.

• Shanghai Jiao Tong University,

Bibliografia

• [1] Han Y., Xu L, Yao G., Zhou LD., Khan MM., Chen C, A novel modulation scheme for dc-voltage balancing control of cascaded H-bridge multilevel APF, Przegląd Elektrot., 85(2009), n. 5, 81-85
• [2] Han Y., Khan MM, Yao G., Zhou L., Chen C, A novel harmonicfree power factor corrector based on T-type APF with adaptive linear neural network (ADALINE) control, Simul. Model. Pract. Theory, 16(2008), n.9, 1215-1238
• [3] Han Y., Xu L, Khan MM, Yao G., Zhou L, Chen C, A novel synchronization scheme for grid-connected converters by using adaptive linear optimal filter based PLL (ALOF-PLL), Simul. Model. Pract. Theory, 17(2009), n.8, 1299-1345
• [4] Recommended Practices and Requirements for Harmonics Control in Electrical Power Systems, IEEE 519, 1993.
• [5] Limits for Harmonic Current Emissions (Equipment Input Current < 16A Per Phase), IEC 1000-3-2 International Standard, 1995.
• [6] Limits for Harmonic Current Emissions (Equipment Input Current up to and Including 16A Per Phase), IEC 61000-3-2 International Standard, 2000.
• [7] Bierhoff M. H., Fuchs F. W., Active damping for three-phase PWM reetifiers with high-order line-side filters, IEEE Trans. Ind. Electron., 56(2009), n.2, 371-379
• [8] Jalili K., Bernet S., Design of LCL filters of active-front-end two-level voltage-source converters, IEEE Trans. Ind. Electron., 56(2009), n.5, 1674-1689
• [9] Shen G. Q., Xu D. H., Cao L. P., Zhu X. C, An improved control strategy for grid-connected voltage source inverters with an LCL filter, IEEE Trans. Power Electron., 23(2008), n.4, 1899-1906
• [10] Mariethoz S., Morari M., Explicit model-predictive control of a PWM inverter with an LCL filter, IEEE Trans. Ind. Electron., 56(2009), n.2, 389-399
• [11] Twining E., Holmes D. G., Grid current regulation of a three-phase voltage source inverter with an LCL input filter, IEEE Trans. Power Electron., 18(2003), n.3, 888-895
• [12] Liserre M., Blaabjerg F, Hansen S., Design and control of an LCL-filter-based three-phase active reetifier, IEEE Trans. Ind. Applicat.41(2005), n.5, 1281-1291
• [13] Kim D. E., Lee D. C, Feedback linearization control of grid-interactive PWM converters with LCL filters, Journal of Power Electron., 9(2009), n.2, 288-299
• [14] Liserre M., Dell'Aquila A., Blaabjerg F., Genetic algorithm-based design of the active damping for an LCL-filter three-phase active reetifier, IEEE Trans. Power Electron., 19(2004), n. 1,76-86
• [15] Bula D., Maciazek M., Pasko M., Hybrid active power filter with the reduced passive filter, Przegląd Elektrot., 85(2009), n. 6, 1-4
• [16] Han Y., Xu L, Yun WJ., Yao G., Zhou LD„ Khan MM., Chen C, Power quality enhancement for automobile factory electrical distribution system-strategies and field practice, Przegląd Elektrot, 85(2009), n. 6, 159-163
• [17] Pasko M., Maciazek M., Bula D., Performance and aceuracy comparison of fixed and floating point realizations of the active power filter control algorithm, Przegląd Elektrot., 85(2009), n. 1, 162-165
• [18] Gwozdz M., Power electronies active filter with controlled dynamies, Przegląd Elektrot, 85(2009), n. 1, 190-192
• [19] Sozanski KP., lmproved shunt active power filters, Przegląd Elektrot, 84(2008), n. 11, 290-294
• [20] Wojciechowski D., Strzelecki R., New control system of the shunt active power filter, Przegląd Elektrot., 84(2008), n. 11, 303-307
• [21] Płatek T., Aspects of voltage regulation in dc circuit of the three-wire, three-phase active filter, Przegląd Elektrot., 84(2008), n. 4, 69-73.
• [22] Kosiorowski S., Stobiecki A., Transient states in circuits with active power filters, Przegląd Elektrot, 84(2008), n. 6, 131-134.
• [23] Tarkiainen A., Pollanen R., Niemela M., Pyrhonen J., Mitigating grid voltage harmonics using a line converter with active filtering feature, Electr. Eng., 88(2006), n.2, 97-107
• [24] Bina M. T., Pashajavid E., An efficient procedure to design passive LCL-filters for active power filters, Electric Power Syst. Res., 79(2009), n.4, 606-614
• [25] Liserre M., Teodorescu R., Blaabjerg F., Stability of photovoltaic and wind turbine grid-connected inverters for a large set of grid impedance values, IEEE Trans. Power Electron., 21(2006), n.1, 263-272
• [26] Figueres E., Garcera G., Sandia J., Gonzalez-Espin F., Rubio JC, Sensitivity study of the dynamies of three-phase photovoltaic inverters with an LCL grid filter, IEEE Trans. Ind. Electron., 56(2009), n.3., 706-717
• [27] Bueno E. J., Cobreces S., Rodriguez F. J., Hernandez A., Espinosa F., Design of a back-to-back NPC converter interface for wind turbines with squirrel-cage induction generator, IEEE Trans. Energy Conversion, 23(2008), n.3, 932-945.
• [28] Park S. Y., Chen C. L, Lai J. S., Moon S. R., Admittance compensation in current loop control for a grid-tie LCL fuel cell inverter, IEEE Trans. Power Electron., 23(2008), n.4, 1716-1723
• [29] Kim H., Yu T., Choi S., Indirect current control algorithm for utility interactive inverters in distributed generation systems, IEEE Trans. Power Electron., 23(2008), n.3, 1342-1347
• [30] Han Y., Xu L, Yao G., Zhou L, Khan MM, Chen C, Flicker mitigation of arc furnace load using modified p-q-r method, Przegląd Elektrot, 85(2009), n.1, 225-229
• [31] Han Y., Khan MM, Xu L., Zhou L., Yao G., Chen C, A novel control strategy for active power filter using synchronous reference frame (SRF) ADALINEs, International Review of Electrical Engineering-IREE, 3(2008), n.4, 629-645.