Design and analysis of a Three Phase Transformerless Hybrid Series Active Power Filter based on sliding mode control using PQ-theory and stationary reference frames

• Main Authors: Naguboina Vinay Kumar, Gudey Satish Kumar
• Format: Article
• Language: English
• Published: Faculty of Technical Sciences in Cacak 2019-01-01
• Series: Serbian Journal of Electrical Engineering
• Subjects: electrical distribution system (eds); sliding mode control (smc); transformerless hybrid series active power filter (thseaf); voltage source converter (vsc)
• Online Access: http://www.doiserbia.nb.rs/img/doi/1451-4869/2019/1451-48691903289N.pdf
• ISSN: 1451-4869; 2217-7183

In this work, a Three phase Transformerless Hybrid Series Active Power Filter (THSeAF) based on Sliding Mode Control (SMC) is proposed to mitigate the voltage and current distortions present in an electrical distribution systems (EDS). A Sliding Mode Controller is designed by controlling the parameters present on the load side as well as source side of the system. Three separate voltage source converters (VSC) are used. The mod1elling of the system is derived by considering a single-phase system by using state space analysis. The frequency response characteristics have been derived for the single-phase system and the stability of the system is studied. It is observed that the system has good stability margins when the SMC is applied at the source side compared to load side. Simulation results obtained in PSCAD/EMTDC v4.6 have been observed for power quality issues like voltage sags, voltage swells, voltage distortions, voltage unbalances and their concurrent occurrence. The approach of stationary reference frame was used for source side control and PQ theory is used for load side control. It is observed that the proposed controller works well in obtaining a stable and constant load voltage during these power quality issues. The difference in settling time observed is around 4 ms for the load side and source side control. The THD present in the load voltage is near about 1%. The SMC is found to be robust in obtaining a constant load voltage with low THD and an improved power factor.