This paper proposes an optimal design method for an hybrid active power filters (HAPFs) set at high voltage levels to satisfy the requirements of Harmonic filtering, Power factor correction and reactive power compensation for Different Loads to Enhance Power Quality Using PSO [16]-[19]. Multi objective Optimization models for HAPF were constructed. Detuning effects and faults were also considered by constructing Constraints during the optimal process, which improved the reliability and practicability of the designed filters. Furthermore, the Particle swarm optimization algorithm was developed for searching an optimal solution of planning of filters.

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Hybrid Active Power Filter Design for 3-Phase, 4-wire System for Different Loads to Enhance Power Quality Using PSO

S. Praveena*, B. Suresh Kumar**, K.P. Krishna Prasad***
* Assistant Professor, Department of ECE, M.G.I.T, Hyderabad.
** Assistant Professor, Department of EEE, C.B.I.T, Hyderabad.
*** P.G Scholar, Department of EEE, C.B.I.T, Hyderabad.
Periodicity:May - July'2013
DOI : https://doi.org/10.26634/jps.1.2.2364

Abstract

This paper proposes an optimal design method for an hybrid active power filters (HAPFs) set at high voltage levels to satisfy the requirements of Harmonic filtering, Power factor correction and reactive power compensation for Different Loads to Enhance Power Quality Using PSO [16]-[19]. Multi objective Optimization models for HAPF were constructed. Detuning effects and faults were also considered by constructing Constraints during the optimal process, which improved the reliability and practicability of the designed filters. Furthermore, the Particle swarm optimization algorithm was developed for searching an optimal solution of planning of filters.

Keywords

Hybrid Active Power Filters (HAPF), Multiobjective Optimization, Particle Swarm Optimization (PSO), Total Harmonic Distortion (THD), Power Factor, Reactive Power

How to Cite this Article?

Praveena, S., Kumar, B. S., and Prasad, K. P. K. (2013). Hybrid Active Power Filter Design For 3-Phase, 4-Wire System For Different Loads To Enhance Power Quality Using PSO. i-manager’s Journal on Power Systems Engineering, 1(2), 37-45. https://doi.org/10.26634/jps.1.2.2364

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