Abstract
Reactive power sharing among distributed generators (DGs) in islanded microgrids (MGs) presents control challenges, particularly in the mismatched feeder line condition. Improved droop control methods independently struggle to resolve this issue and centralized secondary control methods exhibit a high risk of collapse for the entire MG system under any failure in the central control. Distributed secondary control methods have been recently proposed to mitigate the reactive power error evident in the presence of mismatched feeder lines. This paper details a mathematical model of an adaptive virtual impedance control that is based on both leaderless and leader-followers consensus controls with a novel triangle mesh communication topology to ensure accurate active and reactive power sharing. The approach balances an enhanced rate of convergence with the anticipated implementation cost. A MATLAB/Simulink model with six DG units validates the proposed control performance under three different communication structures: namely, ring, complete, and triangle mesh topologies. The results suggest that leaderless consensus control is a reliable option with large DG systems, while the leader-followers consensus control is suitable for the small systems. The triangle mesh communication topology provides a compromise approach balancing the rate of convergence and the expected cost. The extensibility and scalability are advantages of this topology over the alternate ring and complete topologies.
Highlights
Increased power demand has been one of the primary challenges associated with the power systems in many countries
This study describes the design of a new adaptive virtual impedance secondary control that is based on a consensus control algorithm to provide accurate reactive power sharing among distributed generators (DGs) in an islanded microgrid with mismatched feeder line impedances
This section confirms that the proposed control methodology provides accurate active and reactive power sharing among DG units in an islanded microgrid
Summary
Increased power demand has been one of the primary challenges associated with the power systems in many countries. Smart Grid (SG) technologies provide solutions for meeting the increased load demand; ensuring power quality, reliability, and efficiency; and, reducing the emission of carbon dioxide associated with global climate change [1]. Microgrids (MGs) are one of the dominant Smart Grid technologies that have attracted research interest in response to efforts to integrate distributed generators (DG) into the utility grid or as standalone systems [1]. An AC microgrid is a standalone system that is disconnected from the main grid that has full responsibility to manage the entire MG system to supply the demand power to the loads [3,4,5,31]. The islanded microgrid is considered as a ring feeder distribution system developed to connect the DG units in one electric power distribution system, as shown in Figure 1 below.
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