综合多能微电网中液压故障对电力系统的影响

Proceedings of the 9th Workshop on Modeling and Simulation of Cyber-Physical Energy Systems Pub Date : 2021-05-19 DOI:10.1145/3470481.3472709

Ruihao Song, T. Hamacher, V. Perić

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引用次数: 4

摘要

当能源系统耦合在一起时，跨网络故障等不良行为开始出现。认识这一现象，制定保障能源供应稳定的对策具有重要意义。本文研究了热电耦合系统。如果供热系统发生故障，微电网有可能发生级联故障。这一点很重要，因为供热系统中的液压故障可能经常发生，原因是管道爆裂，有时很难检测到。此类故障可能导致短时或持续的电力浪涌和电能质量下降。本文重点研究了故障跨网传播的动态建模与仿真及其对低惯性微电网的潜在影响。仿真结果表明，爆管故障会对低惯性微电网造成明显的功率增加和频率偏差，其影响取决于水力电网的拓扑结构和微电网的规模。

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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Impact of hydraulic faults on the electric system in an integrated multi-energy microgrid

Undesired behaviors such as cross-network faults start to emerge when energy systems are coupled together. It is important to understand such phenomena and to develop countermeasures to ensure energy supply stability. In this paper, coupled heat and electric system is studied. If a fault happens in the heat system, it is possible that the electric microgrid will get a cascading failure. This is important because hydraulic faults in heat supply systems can happen quite often due to pipe bursts and sometimes can be hard to detect. This fault type may lead to a short-time or constant electrical power surge and power quality degradation. This paper focuses on dynamic modelling and simulation of cross-network fault propagation and its potential impact on low inertia electric microgrid. The presented simulation results suggest that a pipe burst fault can cause significant power increases and a frequency deviation to the low inertia electric microgrid, where the impact depends on the topology of the hydraulic grid and the scale of the microgrid.

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Proceedings of the 9th Workshop on Modeling and Simulation of Cyber-Physical Energy Systems

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