Currents’ Physical Components (CPC) concept: a fundamental of Power Theory

• Autorzy: Czarnecki L.

Warianty tytułu

EN

Koncepcja Składowych Fizycznych Prądu – fundamentalna teoria mocy

• Języki publikacji: PL

Abstrakty

PL

Artykuł jest wprowadzeniem do najbardziej obecnie zaawansowanej teorii mocy systemów elektrycznych z niesinusoidal-nymi przebiegami prądu i napięcia, wraz z podstawami ich kompensacji, opartej na koncepcji Składowych Fizycznych Prądu (Currents’ Physical Components – CPC). Obejmuje on układy jednofazowe oraz niezrównoważone układy trójfazowe, zasilane trójprzewodowo, z liniowymi odbiornikami stacjonarnymi (LTI) oraz z odbiornikami generującymi harmoniczne prądu (HGL).

EN

The paper introduces Readers to currently the most advanced power theory of electric systems with nonsinusoidal voltages and currents, along with fundamentals of their compensation, based on the concept of Currents’ Physical Components (CPC). It includes single-phase systems and unbalanced three-phase systems with linear, time-invariant (LTI) and harmonic generating loads (HGLs).

Słowa kluczowe

PL

definicje mocy; moc bierna; moc rozrzutu; moc generowana harmonicznych; moc niezrównoważenia

EN

power definition; scattered power; harmonic generating power

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2008
• Tom: R. 84, nr 6
• Strony: 28--37
• Opis fizyczny: Bibliogr. 38 poz., rys., wykr.

Twórcy

autor

Czarnecki L.

• Departament of Electrical and Computer Engineering Louisianan State University, Baton Rouge, USA,

Bibliografia

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• [22] Czarnecki L.S., Power Theory of Electrical Circuits with Quasi-Periodic Waveforms of Voltages and Currents, Europ. Trans. on Electrical Power, ETEP, 6 (1996), No.5, 321-328.
• [23] Czarnecki L.S., Hsu S.M., Chen G., Adaptive Balancing Com-pensator, IEEE Trans. Pov. Del., 10 (1996), No.3, 1663-1669.
• [24] Czarnecki L.S., Chen G., Staroszczyk Z., Application of Runn-ing Quantities for Control of an Adaptive Hybrid Compensator, Europ. Trans., Elect. Power, ETEP, 6 (1996), No.5, 337-344.
• [25] Czarnecki L.S., Budeanu and Fryze: Two Frameworks for In-tepreting Power Properties of Circuits with Nonsinusoidal Vol-tages and Currents, Archiv fur Elektrot., 81 (1997), No.2, 5-15.
• [26] The New IEEE Standard Dictionary of Electrical and Electro-nics Terms, (1997), IEEE Inc., New York.
• [27] Czarnecki L.S., Energy flow and power phenomena in elec-trical circuits: illusions and reality, Archiv fur Elektrotechnik, 82 (1999), No.4, 10-15.
• [28] Czarnecki L.S., Circuits with Semi-Periodic Currents: Main Features and Power Properties, Europ. Trans. on Electr. Power, ETEP, 12 (2002), No.1, 41-46.
• [29] Depenbrock M., Staudt V., Wrede H., Theoretical Investigation of Original and Modified Instantaneous Power Theory Applied to Four-Wire Systems, IEEE Trans. on Ind. Appl., 39 (2003), No.4, 1160-1167.
• [30] Tenti P., Mattavelli P., A Time-domain Approach to Power Terms Definitions under Non-sinusoidal Conditions, 6th Int. Workshop on Power Definitions and Measurement under Non-Sinusoidal Conditions, (2003), Milan, Italy.
• [31] Czarnecki L.S., On some misinterpretations of the Instantane-ous Reactive Power p-q Theory, IEEE Trans. on Power Elec-tronics, 19 (2004), No.3, 828-836.
• [32] Czarnecki L.S., Could Power Properties of Three-Phase Sys-tems be Described in Terms of the Poynting Vector? IEEE Trans. on Power Delivery, 21 (2006), No.1, 339-344.
• [33] Firlit A., Current’s Physical Components Theory and p-q Power Theory in the Control of the Three-Phase Shunt Active Power Filter, 7th Int. Workshop on Power Definitions and Meas. under Non-Sinusoidal Conditions, (2006), Cagliari, Italy.
• [34] Ginn III H.L., A Hybrid Reference Signal Generator for Active Compensators, Int. Workshop on Power Definitions and Meas. under Non-Sinusoidal Conditions, (2006) Cagliari, Italy.
• [35] Czarnecki L.S., Physical Interpretation of the Reactive Power in Terms of the CPC Power Theory, Electrical Power Quality and Utilization Journal, XIII (2007), No.1, 89-95.
• [36] Czarnecki L.S., Quasi-instantaneous Generation of Reference Signals for Hybrid Compensator Control, Electrical Power Quality and Utilization Journal, XIII (2007), No.2, 33-38.
• [37] Czarnecki L.S., Pearce S. E., Compensation Objectives and CPC–based Generation of Rreference Signals for Shunt Swit-ching Compensator Control, is to be printed in IET Power Electronics, 1 (2008), No.1.
• [38] Czarnecki L.S., Effect of Supply Voltage Harmonics on IRP - based Switching Compensator Control, is to be printed in IEEE Trans. on Power Electronics, (2008).