Active Power Factor Correction

AUTHOR(S)

Dr.S.N.Dhurvey, Sagar Sakhare, Shubham Wase, Nikhil Manawar

DOI: https://doi.org/10.46647/ijetms.2023.v07i03.72

ABSTRACT
Lower in Power Factor of electrical equipment's will draws high current from supply power. The effect of this is affected by impedance of electrical equipment. Power factor correction of boost converter is done by using predictive control strategy. In this project predictive control algorithm is presented based on this algorithm all of the duty cycles required to achieve unity power factor in one half line period are calculated in advance by proportional Integral (PI) controller, the simulation results show that the proposed predictive strategy for PFC achieves near unity power factor. The power factor and input current distortion are analyzed using with control and without control techniques. Simulation results are shows that the power factor is higher than 0.99, and current total harmonics distortion (THD) is smaller than 20% under full load condition. In this project is how impedance of electrical equipment affects the power factor of electrical loads, and then distributed power as the whole. This project is important to verify the right action to increase low power factor effectively for electrical energy efficiency concern.

Page No: 510 - 515

References:

[1] Wanfeng Zhang, Guang Feng, and Yan-Fei Liu November 2004. A Digital Power Factor Correction (PFC) Control Strategy Optimized for DSP” IEEE Transactions on Power Electronics, vol. 19, no.6.
[2] S.Bibian and H.Jin, 2001.Digital control with improved performance for Boost power factor correction circuits,” in Proc. 16th Annu. IEEE Applied Power Electronics Conf. Expo,pp. 137–143.
[3] J.Chen,A.Prodic, R. W. Erickson, and D. Maksimovic Jan. 2003. “Predictive digital current programmed control,” IEEE Trans. Power Electron., vol. 18, pp. 411–419.
[4] A.H.Mitwalli, S.B.Leeb, G. C. Verghese, and V.J.Thottuvelil Mar. 1996 An adaptive digital controller for a unity power factor converter,” IEEE Trans. Power Electron., vol. 11, pp. 374–382.
[5] P.Zumel, A. de Castro, O.Gaecia, T. Riesgo, and J.Uceda, 2002. Concurrent and simple digital controller of an ac/dc converter with power factor correction in Proc. IEEE Applied Power Electronics Conf. Expo, , pp. 469–475.
[6] A. de Castro, P.Zumel, O.Gaecia, T.Riesgo, and J.Uceda Jan. 2003 Concurrent and simple digital controller of an ac/dc converter with power factor correction based on FPGA,” IEEE Trans. Power Electron., vol. 18, pp. 334–343.
[7] I.W.Merfert 1999 Stored-duty-ratio control for power factor correction,” in Proc. IEEE Applied Power Electronics Conf. Expo, vol. 2, , pp. 1123–1129.
[8] “Analysis and application of a new control method for continuous mode Boost converters in power factor correction circuits,” in Proc. IEEE Power Electronics Specialists Conf., vol. 1, 1997, pp. 96–102.
[9] Bhim Singh, Brig N.Singh, Ambrish Chandra June 2004. A Review of Three-Phase Improved Power Quality AC to DC Converters‟. IEEE Transactions on Industrial Electronics, vol. 51, no.3, pp,641_659.
[10] A.Pandey, Prof B.Singh November 30 Comparative Evaluation of Single phase Unity Power Factor ac-dc Boost Converter Topologies.IEEE proc. , 2004.pp,102_109.
[11]Y.Nishida, M.Nakaoka,July 1996. Simplified predictive instantaneous current control for single phase and three phase voltage fed PFC converters ”IEEE Proc- Electric .power Appl,vol.144,No 1.pp,46_52
[12]S.N.Dhurvey, V.K.Chandrakar , 2008. Performance Comparison of
UPFC In Coordination with Optimized POD and PSS On Damping of
Power System Oscillations, International Journal of WSEAS Transaction
on Power System, Vol.3 (5), pp.287-299.
[13] S.N.Dhurvey, V.K.Chandrakar, 2’nd -4’th April 2007. Damping of
Power System Oscillations With Coordinated Tuning of UPFC & POD, Asian Power & energy System, IASTED, Thailand, pp.270-275.
[14] S.N.Dhurvey, V.K.Chandrakar, 1st -4th Sept.2008. Optimized POD
in coordination with UPFC for Damping of Power System Oscillations”, International Conference UPEC 2008, Padova, Italy.
[15] S.N.Dhurvey, V.K.Chandrakar, 2016.Performance Evaluation of Optimized PI Based IPFC with POD, International Journal of Power Systems, Volume 1,pp.69-77.
[16] S.N.Dhurvey, V.K.Chandrakar,2016.Improvement of Power System Performance Using Fuzzy Logic Based Interline Power Flow Controller [IPFC]”, Journal of Power and Energy Engineering, 4,pp.67-77.
[17] S.N.Dhurvey, V.K.Chandrakar,2016.Performance Comparison of PI and Fuzzy Logic Based IPFC on Damping of Power System Oscillations. Journal of Power and Energy Engineering, 4, pp.78-90.
[18] S.N.Dhurvey, V.K.Chandrakar,2016. Performance of power system improvement by using FACTS device :Interline power flow controller”, International Journal of Power Systems, Volume 1,pp.41-45.
[19] S.N.Dhurvey, V.K.Chandrakar,2016.Performance Comparison of PI and MFFN Based IPFC on Damping of Power System Oscillations”, International Journal of Power Systems, Volume 1,pp.17-26.
[20]S.N.Dhurvey, V.K.Chandrakar, JULY 2019.MFFN based IPFC for Enhancement of Power System Security”, ICTACT JOURNAL ON SOFT COMPUTING, VOLUME: 09, ISSUE: 04, pp.1988-1992.
[21] S.N.Dhurvey, V.K.Chandrakar,July 2019. RBFN Based IPFC for Enhancement of Power System Security,International Journal of Recent Technology and Engineering (IJRTE), Volume-8 Issue-2, pp.1928-1932.
[22] Dhurvey S.N., Chandrakar VK.,2018.Performance Comparison of Fuzzy and MFFN based IPFC” International Conference on Smart Electric Drives and Power System (ICSEDPS), pp.245-250.
[23] Dhurvey S.N., Chandrakar VK.,2019.Upgradation of Small Signal Stability by Using RBFN Based IPFC, IEEE Innovations in Power and Advanced Computing Technologies (i-PACT) Conference, VIT Vellore, pp. 1-5.

How to Cite This Article:
Dr.S.N.Dhurvey, Sagar Sakhare, Shubham Wase, Nikhil Manawar .Active Power Factor Correction . ijetms;7(3):510-515. DOI: 10.46647/ijetms.2023.v07i03.72