Low Voltage Ride Through Estimation in Microgrid using Deep Neural Network

Pretty Mary Tom, J. Edward
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Abstract

One of the vital needs for the distribution systems is the Low-Voltage-Ride-through (LVRT) capability which has to meet the grid code standards. The capability of the distribution system to stay connected even during voltage sag issues is termed as LVRT. A solar-wind-battery based hybrid renewable energy system (HRES) for microgrid applications is considered in this work which enables the use of renewable energy resources effectively, each and every system of HRES is controlled exclusively. The output of PV is boosted with the aid of a LUO converter which is controlled by a closed loop control based on Crow Search Algorithm. The wind energy conversion system utilizes doubly-fed-induction generator (DFIG), the output of which is converted to DC by a PWM rectifier and this is controlled by a PI controller. The battery system uses a bidirectional Buck-Boost converter and the state of charge (SOC) of the battery is monitored by artificial neural network (ANN). The key aspect of this work is the estimation of LVRT and this is accomplished by Signal processing approach based Deep Neural Network (DNN). Notch filter is used for pre-processing by which the noises are removed, Hilbert transform is used for segmentation and SIFT for feature extraction. The trained and test data are classified with DNN classifier from which the LVRT is estimated. The proposed strategy is implemented in MATLAB and the results were attained. The grid current THD is observed as 4.72% and the LVRT is estimated at 2.6sec.
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基于深度神经网络的微电网低压穿越估计
低压穿越能力是配电系统的重要需求之一,它必须满足电网规范标准。配电系统在电压暂降期间保持连接的能力被称为LVRT。本文研究了一种基于太阳能-风能-电池的混合可再生能源系统(HRES),该系统能够有效地利用可再生能源资源,并且每个HRES系统都是独家控制的。采用基于Crow搜索算法的闭环控制,利用LUO变流器提高PV的输出功率。风能转换系统采用双馈感应发电机(DFIG),其输出通过PWM整流器转换为直流电,并由PI控制器控制。电池系统采用双向Buck-Boost转换器,电池的荷电状态(SOC)由人工神经网络(ANN)监测。这项工作的关键方面是LVRT的估计,这是通过基于深度神经网络(DNN)的信号处理方法来完成的。利用陷波滤波进行预处理,去除噪声,利用希尔伯特变换进行分割,利用SIFT进行特征提取。使用DNN分类器对训练和测试数据进行分类,并从中估计LVRT。在MATLAB中实现了该策略,并取得了一定的效果。观察到栅极电流THD为4.72%,LVRT估计为2.6秒。
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