Primary Frequency Control in Islanded Microgrids Using a Novel Smart Load

2020 IEEE Canadian Conference on Electrical and Computer Engineering (CCECE) Pub Date : 2020-08-30 DOI:10.1109/CCECE47787.2020.9255760

Javad Khodabakhsh, E. Mohammadi, G. Moschopoulos

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引用次数: 2

Abstract

Islanded microgrids are an inexpensive way to supply electricity to consumers in remote areas. They consist of synchronous diesel generators, distributed generators (DGs) that use renewable energy resources, energy storage systems (ESSs), and loads. The low inertia of the DGs; however, interfaces increase the complexity of frequency control in islanded microgrids and increases the possibility of system instability. In this paper, a new frequency control framework that is based on using single-stage AC-DC converters as virtual synchronous machine (VSM) smart loads to emulate the behavior of a synchronous machine (SM) is proposed to increase system inertia and reduce frequency oscillations. The AC-DC converter is based on a new topology that has been proposed by the authors. In this paper, the topology and the control system are explained and an IEEE 37 bus test feeder with the smart loads is simulated as an islanded microgrid. It is shown that using the proposed smart load results in frequency fluctuations being damped considerably faster.

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基于新型智能负载的孤岛微电网一次频率控制

孤岛微电网是一种向偏远地区的消费者供电的廉价方式。它们由同步柴油发电机、利用可再生能源的分布式发电机(dg)、储能系统(ess)和负载组成。DGs的惯性小;然而，接口增加了孤岛微电网频率控制的复杂性，增加了系统不稳定的可能性。本文提出了一种新的频率控制框架，该框架基于单级交流-直流转换器作为虚拟同步机(VSM)智能负载来模拟同步机(SM)的行为，以增加系统惯性并减少频率振荡。该AC-DC转换器基于作者提出的一种新的拓扑结构。本文对其拓扑结构和控制系统进行了阐述，并对具有智能负载的ieee37总线测试馈线作为孤岛微电网进行了仿真。结果表明，使用所提出的智能负载可以更快地抑制频率波动。

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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2020 IEEE Canadian Conference on Electrical and Computer Engineering (CCECE)

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