Impact of Reduced Share of Rotary Frequency Converters in a Low Frequency Synchronous Railway Grid: A Transient Stability Study

2019 Joint Rail Conference Pub Date : 2019-07-18 DOI:10.1115/JRC2019-1238

J. Laury, Lars Abrahamsson, M. Bollen

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引用次数: 1

Abstract

Most low-frequency AC single-phase railway grids have both power-electronic based Static Frequency Converters (SFCs) and electrical-machine based Rotary Frequency Converters (RFCs) connecting them to the three-phase public grid. Already today, in some such grids, a majority of the power conversion is from SFCs. As railway traffic (and thus power demand) increases, more SFCs are installed for capacity increase, while the number of RFCs remains (almost) constant. Thus, the share of SFCs is expected to increase, and the ratio of installed rotational inertia over installed power to decrease. This paper investigates how different shares of SFCs affect the transient stability of low-frequency AC railway grids when having a mix of RFCs and SFCs converting three-phase AC power to single-phase AC power. Results from numerical simulations of the interactions that occur between converters when and after the grid is subject to a fault are presented. The numerical studies show that with an increased share of SFCs there is an increased oscillatory behavior, for example in the voltage magnitude and active power after fault clearance.

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低频同步铁路电网中旋转变频器份额减小的影响:暂态稳定性研究

大多数低频交流单相铁路电网都有基于电力电子的静态变频器(sfc)和基于电机的旋转变频器(rfc)将它们连接到三相公共电网。今天，在一些这样的电网中，大部分的电力转换来自sfc。随着铁路交通(以及电力需求)的增加，为了增加容量，安装了更多的sfc，而rfc的数量(几乎)保持不变。因此，预计sfc的份额将增加，安装转动惯量与安装功率的比率将降低。本文研究了当rfc和sfc混合将三相交流电源转换为单相交流电源时，不同份额的sfc如何影响低频交流铁路电网的暂态稳定性。给出了电网发生故障时变流器之间相互作用的数值模拟结果。数值研究表明，随着sfc比例的增加，故障清除后电压幅值和有功功率的振荡行为增加。

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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2019 Joint Rail Conference

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