Publication Type : Journal Article
Publisher : Energy Procedia
Source : Energy Procedia, vol. 117, pp. 1007 - 1014, 2017.
Url : http://www.sciencedirect.com/science/article/pii/S1876610217324633
Keywords : Distributed generation (DG)units, Low Voltage (LV) micro grid, Point of common coupling (PCC), Smart transformer(ST), thyristor controlled on load tap changing transformer
Campus : Amritapuri
School : School of Engineering
Center : Amrita Innovation & Research, Electronics Communication and Instrumentation Forum (ECIF)
Department : Electrical and Electronics
Verified : Yes
Year : 2017
Abstract : An intentional active power flow control between microgrids in a multi micro grid system in the grid connected mode is achieved at the point of common coupling. The thyristor controlled on load tap changing transformer at the point of common coupling is equipped with voltage based power flow controller where different tapping are switched according to the required power flow condition to be satisfied and the amount of power to be transmitted. Accordingly, the voltage based droop control associated with the distributed generation units in each of the micro grid changes their active power generation. Thus, without much communication to other elements of the micro grids, the Smart Transformer at the point of common coupling allows active power exchange. The simulations performed in MATLAB/ SIMULINK for both three phase and single phase system follows that active power flow control is achieved in a multi micro grid system using the thyristor switched Smart Transformer. Hardware implementation has also been initiated to analyze the concept of power flow control with thyristor switched Smart Transformer and results are studied. The proposed system shows its operational effectiveness, which can be employed to solve grid emergencies in real time.
Cite this Research Publication : V. C. Jishnu Sankar, Haritha, G., and Dr. Manjula G. Nair, “Thyristor Switched Smart Transformer for Active Power Flow Control in Multi Micro grid System”, Energy Procedia, vol. 117, pp. 1007 - 1014, 2017.