Comparative Study of Various Communication Technologies for Secondary Controllers in DC Microgrid

2021 9th IEEE International Conference on Power Systems (ICPS) Pub Date : 2021-12-16 DOI:10.1109/ICPS52420.2021.9670303

A. Shyam, S. R. Sahoo, S. Anand, J. Guerrero

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Abstract

With the increased emphasis on power generation from renewable sources, microgrids are considered as the best solution for distributed generation. Control of distributed sources in dc microgrid have been a topic of interest for both academia and industry. Reliable operation of secondary controller of a dc microgrid depends on a good communication network. However, the literature on dc microgrid does not give the methodology to select a particular communication technology from a wide variety of wired and wireless technologies. The selection of proper technology is based on many factors like the size of the microgrid, bandwidth, number of power electronic converters supported, latency, range, etc. A comparison of wired and wireless communication technologies based on these factors, and their suitability to use in dc microgrid is performed in this paper. Expressions are derived to calculate the maximum permissible number of devices supported and the network latency for each communication technology. The observations made in this paper are validated with case studies on low and medium power dc microgrids.

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直流微电网二次控制器各种通信技术的比较研究

随着对可再生能源发电的日益重视，微电网被认为是分布式发电的最佳解决方案。直流微电网中分布式电源的控制一直是学术界和工业界感兴趣的话题。直流微电网二级控制器的可靠运行依赖于良好的通信网络。然而，关于直流微电网的文献并没有给出从各种有线和无线技术中选择特定通信技术的方法。选择合适的技术是基于许多因素，如微电网的大小、带宽、支持的电力电子转换器的数量、延迟、范围等。基于这些因素，本文对有线和无线通信技术进行了比较，并分析了它们在直流微电网中的适用性。推导表达式来计算支持的最大允许设备数量和每种通信技术的网络延迟。本文的观察结果通过中、低功率直流微电网的实例研究得到了验证。

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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2021 9th IEEE International Conference on Power Systems (ICPS)

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