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Dr. Mohamed Hassan Elsaid Ahmed Shalan :: Publications:

Power Angle Control of Virtual Synchronous Generator
Authors: Prof. Dr. Mohammad Anwar elsayad;Assoc. Prof. Dr. Gamal M. Sarhan;Assis. Prof. Dr. Amr Magdy Abdin;Eng. Mohamed Hassan Shaalan
Year: 2017
Keywords: Distributed generation; Damping; Frequency control; inverter-dominated power system; load sharing; microgrid; parallel inverters; pulse width modulation (PWM) inverter; renewable energy; static synchronous generator (SG); synchronverter (SV); microgrids, power control; renewable energy sources (RES); virtual synchronous generator (VSG)
Journal: Journal of Electrical Engineering
Volume: 17
Issue: 2
Pages: Not Available
Publisher: Eng. Mohamed Hassan Shaalan
Local/International: International
Paper Link:
Full paper Mohamed Hassan Elsaid Ahmed Shalan_Power Angle Control of Virtual Synchronous Generator.pdf
Supplementary materials Not Available

Inverter-based distributed generators (DGs) can be operated in parallel comprising an isolated microgrid or connected to the main power system. In the first case there must be an advanced control system to adjust frequency and power sharing between inverters constituting the microgrid. In grid mode the DGs inject electrical power to grid without any contribution to rotating inertia that give the power system its distinctive stability characteristics and conventional control liability. Improvement to DGs by the relatively new control methods based on virtual synchronous generator (VSG) and synchronverter (SV) have been suggested to control such DGs to emulate conventional synchronous generator. By these methods a controlled amount of virtual inertia can be injected in mains besides load sharing. This paper suggests a control method of such systems based on direct control of power angle between inverter voltage and grid voltage. In this method the grid phase angle is directly computed from the grid 3-phase voltages without phased locked loop (PLL) or other synchronization methods. A linearized small signal model of power angle is used to implement this control method. The model can also emulate rotating inertia, injecting a controllable amount of energy into grid during frequency transients to enhance transient stability. Damping effect of damper bars is taken into account in model and proves to be effective in damping out oscillations.

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