A Fully Decentralized Control Approach for Hybrid Energy Storage System in DC Microgrids Based on Fractional Order Voltage Compensation

2021 North American Power Symposium (NAPS) Pub Date : 2021-11-14 DOI:10.1109/NAPS52732.2021.9654758

M. Alam, F. Al-Ismail, Abdullah A. Almehizia, M. A. Abido

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引用次数: 1

Abstract

Recently, power networks are observing high-level integration of renewable energy, direct current (DC) loads, and energy storage devices. As a result of more power electronic-based components integration, the conventional alternating current (AC) microgrid is gradually transforming to DC microgrid. However, DC bus voltage control and power-sharing among energy storage devices are challenging tasks. This study proposes a new voltage compensation control strategy for DC microgrids based on fractional-order differential-integral (FODI) controller. In the proposed approach, a voltage compensation term which is processed by the FODI controller is added to the droop control loop. The advantages of the proposed controller are manyfold such as autonomous bus voltage restoration, power split between battery and supercapacitor, and autonomous state of charge (SOC) control. The DC microgrid consisting of battery, supercapacitor, and DC loads is simulated in MATLAB Simulink. The results show that the proposed controller is superior to the conventional controller in controlling DC bus voltage, active power, and SOC.

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基于分数阶电压补偿的直流微电网混合储能系统全分散控制方法

最近，电网正在观察可再生能源、直流(DC)负载和储能设备的高水平整合。由于更多的电力电子元件集成，传统的交流微电网正逐步向直流微电网转变。然而，直流母线电压控制和储能设备之间的功率共享是一项具有挑战性的任务。提出了一种基于分数阶微分积分(FODI)控制器的直流微电网电压补偿控制策略。该方法在下垂控制回路中加入电压补偿项，该补偿项由FODI控制器处理。该控制器具有自主母线电压恢复、电池和超级电容器之间的功率分配以及自主充电状态(SOC)控制等优点。在MATLAB Simulink中对由电池、超级电容器和直流负载组成的直流微电网进行了仿真。结果表明，该控制器在控制直流母线电压、有功功率和SOC方面优于传统控制器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 North American Power Symposium (NAPS)

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