Abstract
Based on the droop control, voltage regulation at the secondary control is required to eliminate the deviation of the average voltage across the microgrid. Meanwhile, to prevent any of energy storage (ESs) from over-charging or over-discharging, State-of-Charge (SoC) balancing should be added in the secondary control. This paper proposes a distributed secondary control in the DC microgrid based on the multiagent system (MAS). This controller consists of voltage regulation and time-oriented SoC balancing. In voltage regulation, a PI controller adjusts the droop parameters according to the discrepancy between the average voltage and the reference voltage. In SoC balancing, controller operates in charging mode or discharging mode according to changes of the global average SoC. Being different from the conventional method, the time-oriented SoC balancing method is designed to balance charge/discharge time rather than to balance SoC directly. Thus, SoCs reach a consensus only at the last moment when all ES nodes charge or discharge completely. Furthermore, characteristics, global dynamic model, and steady-state analysis of the proposed control method are studied. Finally, MATLAB/Simulink simulations are performed to verify the effectiveness of the proposed control.
Highlights
In recent years, microgrid has received great attention as an important solution to utilize renewable energy resources such as wind, solar, and tidal energy
Secondary control eliminates the deviation of voltage and power sharing
An islanded 400V DC microgrid comprised of 8 energy storage (ES) nodes is simulated in MATLAB/Simulink to of proposed controller
Summary
Microgrid has received great attention as an important solution to utilize renewable energy resources such as wind, solar, and tidal energy. Microgrid can effectively integrate distributed generations (DGs), converters, battery energy storage systems (BESSs), and loads. Hierarchical control has been generally accepted since it was put forward [3]. Hierarchical control is composed of primary control, secondary control, and tertiary control. Primary control is the droop control that realizes reference voltage and power sharing. Secondary control eliminates the deviation of voltage and power sharing. According to the configuration of the communication system, secondary control can be divided into 3 types: centralized control, decentralized control, and distributed control. Information like voltages and currents of all nodes including power generation nodes and energy storage (ES) nodes is delivered through network communication to the central controller, PI controllers calculate droop correction
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