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Warianty tytułu
Języki publikacji
Abstrakty
This paper presents a load equivalent conductance based control method for a shunt active power filter. The principle of energy balance in the circuit, which means between supplying source - active filter - load, is used to obtain the control formula. The natural inertia of the active filter action is exploited, so no PI regulators are needed. The active filter can compensate for non-active current and, additionally, can stabilise the supplying source active power. In a case of generating loads energy harvesting is possible. The presented method is useful as well for voltage-source as current-source inverter based active filters, and for DC system as well as for AC single- or three-phase one.
Czasopismo
Rocznik
Tom
Strony
259--275
Opis fizyczny
Bibliogr. 17 poz., wykr., wz.
Twórcy
autor
- Faculty of Circuit Theory and Electronics Cracow University of Technology
Bibliografia
- [1] Aredes M., Monteiro L., A control strategy for shunt active power filter. 10th International Conference on Harmonics and Quality of Power 2: 472-7 (2002).
- [2] Asimionaei L., Blaabjerg F., Hansen S., Detection is key. Harmonic detection methods for active power filter applications. IEEE Ind. Appl. Magazine 13(4): 22-33 (2007).
- [3] Chauhan S.K., Shah M.C., Tiwari R.R., Tekwani P.N., Analysis, design and implementation of a shunt active power filter with different schemes of reference current generation. IET Power Electron. 7(3): 627-39 (2014).
- [4] Depenbrock M., Staudt V., The FBD-method as tool for compensating non-active currents. International Conference on Harmonics and Quality of Power ICHQP’98, pp. 320-324 (1998).
- [5] Dirik H., _zdemir M., New extraction method for active, reactive and individual harmonic components from distorted current signal. IET Gener. Transm. Distrib 8(11): 1767-77 (2014).
- [6] Grabowski D., Maciążek M., Pasko M., Sizing of active power filters using some optimization strategies. COMPEL 32(4): 1326-36 (2013).
- [7] Herrera R., Salmeron P., Kim H., Instantaneous reactive power theory applied to active power filter compensation: different approaches, assessment, and experimental results. IEEE Trans. on Ind. Electron. 55(1): 184-96 (2008).
- [8] Jorge S.G., Busada C.A., Solsona J., Reduced order generalised integrator-based current controller applied to shunt active power filters. IET Power Electron. 7(5): 1083-91 (2014).
- [9] Orts-Grau S., Gimeno-Sales F.J., Segui-Chilet S. et al., Selective compensation in four-wire electric systems based on a new equivalent conductance approach. IEEE Trans. on Ind. Electron. 56(8): 2862-74 (2009).
- [10] Piróg S., PWM rectifier and active filter with sliding-mode control. European Conf. on Power Electronics and Applications, pp. 4.831-6, Trondheim, Norway (1997).
- [11] Savoye F., Venet P., Millet M., Groot J., Impact of periodic current pulse on Li-Ion battery performance, IEEE Trans. on Ind. Electr. 59(9): 3481-88 (2012).
- [12] Strzelecki R., Benysek G., Jarnut M., Power quality conditioners with minimum number of current sensor requirement, Przegląd Elektrotechniczny (Electrotechnical Review) 84(11): 295-8 (2008).
- [13] Szromba A., A shunt active power filter: development of properties, COMPEL 23(4): 1146-62 (2004).
- [14] Szromba A., Energy controlled shunt active power filters, COMPEL 26(4): 1142-60 (2007).
- [15] Szromba A., Shunt power electronic buffer as active filter and energy flow controller. Arch. of Electr. Eng. 62(1): 55-75 (2013).
- [16] Trinh Q.-N., Lee H.-H., An Advanced Current Control Strategy for Three-Phase Shunt Active Power Filters. IEEE Trans. on Ind. Electron. 60(12): 5400-10 (2012).
- [17] Yi H., Zhuo F., Zhang Y., Li Y., Zhan W., Chen W., Liu J., A Source-Current-Detected Shunt Active Power Filter Control Scheme Based on Vector Resonant Controller. IEEE Trans. on Ind. Appl. 50(3): 1953-65 (2014).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-179f4d52-469d-43b5-81b0-03bb9d5645f9