Multiresolution Models of DC Traction Power Supply Systems With Reversible Substations

IF 1.9 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Fulin Fan, Yafang Li, Smail Ziani, Brian G. Stewart
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Abstract

Reversible substations (RSs) permitting bidirectional power flows can recover the regenerative braking energy of trains in DC traction power supply systems (TPSSs), increasing the energy efficiency of railway systems. To predict their effects on system dynamics and energy savings, the paper develops multiresolution models (MRMs) to simulate the RS roles with different fidelities. A high-resolution model for the transient simulation replicates a particular topology where a three-level voltage source inverter is connected to the secondary winding of an existing 12-pulse rectifier transformer and regulated to keep a constant DC voltage in the inverting mode. Furthermore, it can model the transient effects of pantograph-to-line arcing by inserting arc voltage profiles at the train’s input stage. To increase the computation speed in the long-term energy flow simulation, a low-resolution model simplifies the rectifiers into a series connection of a diode and a controlled voltage source depicting their nonlinear output characteristics and then places a DC voltage source in parallel to form a reverse path for braking power recovery. In addition, nonlinear conversion efficiencies are introduced to calculate energy flows across substations. The MRMs are tested based on a 1.5 kV DC TPSS and discussed alongside system dynamics under normal operation or pantograph arcing and the consistencies between different models. The RS using bidirectional voltage source converters only is additionally modelled to compare the technical performance of the two topologies in terms of system dynamics and energy efficiencies.

Abstract Image

具有可逆变电站的直流牵引供电系统的多分辨率模型
允许双向电力流动的可逆变电站(RS)可以回收直流牵引供电系统(TPSS)中列车的再生制动能量,从而提高铁路系统的能源效率。为了预测其对系统动态和节能的影响,本文开发了多分辨率模型(MRM),以模拟不同保真度的 RS 作用。用于瞬态模拟的高分辨率模型复制了一种特定的拓扑结构,即三电平电压源逆变器连接到现有 12 脉冲整流变压器的次级绕组,并在逆变模式下调节以保持恒定的直流电压。此外,它还可以通过在列车输入级插入电弧电压曲线来模拟受电弓对线路电弧的瞬态效应。为了提高长期能量流仿真的计算速度,低分辨率模型将整流器简化为二极管和受控电压源的串联连接,描绘其非线性输出特性,然后并联一个直流电压源,形成制动功率恢复的反向路径。此外,还引入了非线性转换效率,以计算跨变电站的能量流。基于 1.5 千伏直流 TPSS 对 MRM 进行了测试,并讨论了正常运行或受电弓电弧下的系统动态以及不同模型之间的一致性。此外,还对仅使用双向电压源转换器的 RS 进行了建模,以比较两种拓扑结构在系统动态和能效方面的技术性能。
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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来源期刊
CiteScore
5.80
自引率
4.30%
发文量
18
审稿时长
29 weeks
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