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The voltage and frequency response model of microgrid is significant for its application in the design of secondary voltage frequency controller and system stability analysis. However, most models developed for this aspect are complex in structure due to the difficult mechanism modeling process and are only suitable for offline identification. To solve these problems, this paper proposes a black-box modeling method to identify the voltage and frequency response model of microgrid online. Firstly, the microgrid system is set as a two-input, two-output black-box system and can be modeled only by data sampled at the input and output ports. Therefore, the simplicity of modeling steps can be guaranteed. Meanwhile, the recursive damped least squares method is used to realize the online model identification of the microgrid system, so that the model parameters can be adjusted with the change of the microgrid operating structure, which makes the model more adaptable. The paper analyzes the black-box modeling process of the microgrid system in detail, and the microgrid platform, including 100 kW rated power inverters, is employed to validate the analysis and experimental results.
Yong Shi; Dong Xu; Jianhui Su; Ning Liu; Hongru Yu; Huadian Xu. Black-Box Behavioral Modeling of Voltage and Frequency Response Characteristic for Islanded Microgrid. Energies 2019, 12, 2049 .
AMA StyleYong Shi, Dong Xu, Jianhui Su, Ning Liu, Hongru Yu, Huadian Xu. Black-Box Behavioral Modeling of Voltage and Frequency Response Characteristic for Islanded Microgrid. Energies. 2019; 12 (11):2049.
Chicago/Turabian StyleYong Shi; Dong Xu; Jianhui Su; Ning Liu; Hongru Yu; Huadian Xu. 2019. "Black-Box Behavioral Modeling of Voltage and Frequency Response Characteristic for Islanded Microgrid." Energies 12, no. 11: 2049.
Conventional photovoltaic (PV) systems interfaced by grid-connected inverters fail to support the grid and participate in frequency regulation. Furthermore, reduced system inertia as a result of the integration of conventional PV systems may lead to an increased frequency deviation of the grid for contingencies. In this paper, a grid-supporting PV system, which can provide inertia and participate in frequency regulation through virtual synchronous generator (VSG) technology and an energy storage unit, is proposed. The function of supporting the grid is implemented in a practical PV system through using the presented control scheme and topology. Compared with the conventional PV system, the grid-supporting PV system, behaving as an inertial voltage source like synchronous generators, has the capability of participating in frequency regulation and providing inertia. Moreover, the proposed PV system can mitigate autonomously the power imbalance between generation and consumption, filter the PV power, and operate without the phase-locked loop after initial synchronization. Performance analysis is conducted and the stability constraint is theoretically formulated. The novel PV system is validated on a modified CIGRE benchmark under different cases, being compared with the conventional PV system. The verifications demonstrate the grid support functions of the proposed PV system.
Huadian Xu; Jianhui Su; Ning Liu; Yong Shi. A Grid-Supporting Photovoltaic System Implemented by a VSG with Energy Storage. Energies 2018, 11, 3152 .
AMA StyleHuadian Xu, Jianhui Su, Ning Liu, Yong Shi. A Grid-Supporting Photovoltaic System Implemented by a VSG with Energy Storage. Energies. 2018; 11 (11):3152.
Chicago/Turabian StyleHuadian Xu; Jianhui Su; Ning Liu; Yong Shi. 2018. "A Grid-Supporting Photovoltaic System Implemented by a VSG with Energy Storage." Energies 11, no. 11: 3152.