PENURAS KUASA AKTIF PIRAU SATU FASA MENGGUNAKAN STRATEGI KAWALAN RINGKAS
DOI:
https://doi.org/10.11113/jt.v79.10003Keywords:
Active power filter, equivalent resistance, harmonics, nonlinear load, power factorAbstract
This paper describes a single phase shunt active power filter system used in compensating current harmonics and improving electrical line’s power factor via simplified control strategy based on estimation of nonlinear load’s equivalent resistance. By employing MATLAB Simulink simulation tool, the proposed control strategy successfully compensated source current harmonics and corrected line power factor to near unity. Moreover, analysis on the system performance indicated that the system’s achieved fast time response, stabilized system and near zero steady state error. To verify the proposed system, experimental results also presented.
References
Zainal, S., Tan, P. C. and Awang, J. 2006. Harmonics Mitigation Using Active Power Filter: A Technological Review. Elektrika. 8(2): 17-26.
Yusof, Y. and Rahim, N. A. 2009. Simulation of Series Active and Passive Power Filter Combination System to Mitigate Current Source Harmonics. Proceedings of Power Control and Optimization, 2009 American Institute of Physics. 86-91.
Hua, C. C., Li, C. S. and Lee, C. H. 2009. Control Analysis of an Active Power Filter Using Lyapunov Candidate. IET Power Electronics. 2(4): 325-334.
Adel, M., Zaid, S. and Mahgoub, O. 2011. Improved Active Power Filter Performance Based on an Indirect Current Control Technique. Journal of Power Electronics. 11(6): 931-937.
Hamadi, A., Rahmani, S. and Al-Haddad, K. 2013. Digital Control of a Shunt Hybrid Power Filter Adopting a Nonlinear Control Approach. IEEE Transactions on Industrial Informatics. 9(4): 2092-2104.
Monfared, M., Golestan S. and Guerrero, J. M. 2013. A New Synchronous Reference Frame-Based Method for Single-Phase Shunt Active Power Filters. Journal of Power Electronics. 13(4): 692-700.
Lim, P. Y. and Naziha, A. A. 2007. Comparison of Inverter’s Performance as Active Power Filters with Unified Power-Frequency Integration Control. Jurnal Teknologi. 46(D): 121-134.
Rashid, M. H. 2004. Power Electronics: Circuits, Devices, and Applications. 3rd Edition. Pearson Education.
Akagi, H. 2005. Active Harmonic Filters. Proc. the IEEE. 93(12): 2128-2141.
Radzi, M. A. M. and Rahim, N. A. 2009. Neural Network and Bandless Hysteresis Approachto Control Switched Capacitor Active Power Filter for Reduction of Harmonics. IEEE Trans. Ind. Electron. 56(5): 1477-1484.
Zainuri, M. A. A. M., Radzi M. A. M., Soh, A. C., Mariun, N. and Rahim, N. A. 2016. DC-link Capacitor Voltage Control for Single-Phase Shunt Active Power Filter with Step Size Error Cancellation in Self-Charging Algorithm. IET Power Electron. 9(2): 323-335.
Green, T. C. and Marks, J. H. 2005. Control Techniques for Active Power Filters. Proc. Inst. Elect. Eng.—Elect. Power Appl. 1529(2): 369-381.
Dey, P. and Mekhilef, S. 2015. Current Controllers of Active Power Filter for Power Quality Improvement: A Technical Analysis. AUTOMATIKA. 56(1): 42-54.
Miret, J., de Vicuna, L. C., Castilla, M., Matas, J. and Guerero, J. M. 2009. Design of an Analog Quasi-Steady-State Nonlinear Current-Mode Controller for Single-Phase Active Power Filter. IEEE Trans Ind Electron. 56(12): 4872-4881.
Nise, N. J. 2010. Control System Engineering. John Wiley & Sons.
IEEE Recommended Practice and Requirements for Harmonic Control in Electric Power Systems. 2014. IEEE Std 519-2014 (Revision of IEEE Std 519-1992). 1-29.
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