Abstract
Filtration-based (FB) power/current allocation of battery-supercapacitor (SC) hybrid energy storage systems (HESSs) is the most common approach in DC microgrid (MG) applications. In this approach, a low-pass or a high-pass filter is utilized to decompose the input power/current of HESS into high-frequency and low-frequency components and then assign the high-frequency parts to SC. Moreover, to avoid the state of charge violation (SoC) of SC, this approach requires a rule-based supervisory controller which may result in the discontinuous operation of SC. This paper first provides a small-signal stability analysis to investigate the impact of an FB current allocation system on the dynamic stability of an islanded DC MG in which a grid-forming HESS supplies a constant power load (CPL). Then, it shows that the continuous operation of SC is essential if the grid-forming HESS is loaded by large CPLs. To address this issue, this paper proposes a model predictive control (MPC) strategy that works in tandem with a high-pass filter to perform the current assignment between the battery and SC. This approach automatically restores the SoC of SC after sudden load changes and limits its SoC variation in a predefined range, so that ensure the continuous operation of SC. As a result, the proposed FB-MPC method indirectly enables the MG’s proportional-integral (PI) voltage controller to operate with higher gain values leading to better transient response and voltage quality. The performance of the proposed approach is then validated by simulating the system in MATLAB/Simulink.
Highlights
Control of DC MGs can be challenging in the presence of constant power loads (CPLs) and pulsed power loads (PPLs) which require fast dynamic response and large stability margin of control system [4–6]
FB strategies are widely used in hybrid energy storage systems (HESSs) applications to perform the power/current allocation between the Battery energy storage systems (BESSs) and SC
This paper firstly provides a smallsignal stability analysis to investigate the impact of the HESS current assignment filter on the dynamic stability of a single bus DC MG in which a grid-forming HESS supplies a CPL
Summary
A. LITERATURE REVIEW Microgrids (MGs) are independent active distribution networks that can enhance the performance of traditional power systems through increasing consumer participation, sustainable energy resources penetration, power system stability, and grid resiliency [1,2]. Control of DC MGs can be challenging in the presence of constant power loads (CPLs) and pulsed power loads (PPLs) which require fast dynamic response and large stability margin of control system [4–6]. To tackle this challenge, highly-dispatchable distributed energy resources (DERs) as well as advanced control and management techniques are required to improve the transient response, stability, and flexibility of the system [7]
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