Performance assessment of single and dual loops discrete PR controllers with LCL filter for inverter-based distributed generation

2014 International Symposium on Power Electronics, Electrical Drives, Automation and Motion Pub Date : 2014-06-18 DOI:10.1109/SPEEDAM.2014.6872120

H. M. El-Deeb, A. Elserougi, A. Abdel-Khalik, S. Ahmed, A. Massoud

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引用次数: 3

Abstract

Due to the rapid growth of the electric energy demands, the necessity of involvement of distributed generation (DG) to overcome this demand became a must. When distributed generation renewable energy sources are coupled to the grid through a DC-AC inverter, the injected currents to the grid should be characterized by high quality and low distortion. Many factors play an important role to produce high quality output beginning with the order of the passive filter used, type of controller used and last but not least the presence of distortions in the grid. This paper demonstrates the evaluation of performance, in normal and abnormal grid conditions, between single and dual loop control for the three phase inverter tied to the grid through a LCL passive filter and controlled with discrete proportional resonant (PR) controller, taking into account how filter parameters, control gains and sampling frequency would affect the dynamics of the system as well as its stability in order to perform adequate tuning. The concluded assumptions were simulated & verified through Matlab/Simulink.

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基于逆变器的分布式发电中带LCL滤波器的单环和双环离散PR控制器的性能评估

由于电力能源需求的快速增长，分布式发电(DG)参与的必要性，以克服这一需求成为必须。当分布式发电可再生能源通过直流-交流逆变器耦合到电网时，注入电网的电流应具有高质量和低畸变的特点。许多因素在产生高质量输出方面起着重要作用，从使用的无源滤波器的顺序、使用的控制器类型开始，最后但并非最不重要的是电网中存在的扭曲。本文演示了在正常和异常电网条件下，通过LCL无源滤波器和离散比例谐振(PR)控制器控制的三相逆变器的单环和双环控制之间的性能评估，考虑到滤波器参数，控制增益和采样频率如何影响系统的动力学及其稳定性，以便进行适当的调谐。通过Matlab/Simulink对所得假设进行了仿真验证。

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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2014 International Symposium on Power Electronics, Electrical Drives, Automation and Motion

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