Low latency communication infrastructure for synchrophasor applications in distribution networks

K. Katsaros, Binxu Yang, W. Chai, G. Pavlou
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引用次数: 25

Abstract

With the introduction of new power sources, such as distributed renewable energy resources, and loads, such as electric vehicles, electrical distribution networks must accommodate new energy flow patterns in a considerably dynamic environment. This leads to the need for increasing the observability of the grid to enable a series of mission-critical applications such as voltage/congestion control and fault detection/location. The deployment of Phasor Measurement Units appears to be a promising approach, offering high precision grid monitoring. However, while the low delay requirements of such applications raise a significant challenge to the communication infrastructure, there is currently no clear vision on the exact communication technologies and network topologies that could support these requirements. In this paper, we address this challenge by taking a systematic approach on the design of low latency communication infrastructures. Based on a large set of real medium voltage grid topologies from a European distribution network, we first perform a detailed analysis of the communication requirements. Guided by this analysis, we then propose two algorithms, PLeC and BW-PLeC algorithms, for the design of low latency communication infrastructures that enhance the currently available power-line communication technology with newer high-speed communication links at strategic points in the grid to satisfy the delay requirements while reducing deployment costs.
配电网中同步性应用的低延迟通信基础设施
随着新能源(如分布式可再生能源)和负荷(如电动汽车)的引入,配电网络必须在相当动态的环境中适应新的能源流模式。这导致需要增加电网的可观察性,以实现一系列关键任务应用,如电压/拥塞控制和故障检测/定位。相量测量单元的部署似乎是一种很有前途的方法,可以提供高精度的电网监测。然而,虽然这些应用程序的低延迟要求对通信基础设施提出了重大挑战,但目前还没有明确的通信技术和网络拓扑来支持这些要求。在本文中,我们通过采用系统的方法设计低延迟通信基础设施来解决这一挑战。基于来自欧洲配电网的大量真实中压电网拓扑结构,我们首先对通信需求进行了详细分析。在此分析的指导下,我们提出了两种算法,PLeC和BW-PLeC算法,用于设计低延迟通信基础设施,在电网战略点上使用更新的高速通信链路增强现有电力线通信技术,以满足延迟要求,同时降低部署成本。
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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