Transient Stability Analysis of the IEEE 14-Bus Test System Using Dynamic Computation for Power Systems (DCPS)

2012 Third International Conference on Intelligent Systems Modelling and Simulation Pub Date : 2012-02-08 DOI:10.1109/ISMS.2012.53

N. Hashim, N. Hamzah, M. Latip, A. Sallehhudin

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引用次数: 17

Abstract

Transient Stability Analysis (TSA) is a major analysis in the operation of power systems, due to the increasing stress on power system networks. One of the main goals of this analysis is to gather critical information, such as critical clearing time (tCCT) of the circuit breakers for faults in the system. tCCT is defined as the maximum time between the fault initiation and its clearing, such that the power system is transiently stable. This paper presents a transient stability analysis of the IEEE 14 bus test system using Dynamic Computation for Power Systems (DCPS) software package. This C++ based software package has the ability to handle systems up to 1000 buses and 250 generators, providing an alternative to expensive commercial software packages. To analyze the effect of the distance of the fault location and critical clearing time on the system stability, a three-phase fault has been applied at five different locations in the system. The stability of the system has been observed based on the simulation graphs of terminal voltage, machine's rotor angle, machine's speed and output electrical power. The simulation results showed that tCCT decreases as the fault location becomes closer to the main generator.

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基于动态计算的电力系统IEEE 14总线测试系统暂态稳定性分析

暂态稳定分析(TSA)是电力系统运行中的一项重要分析，因为电力系统对电网的压力越来越大。该分析的主要目的之一是收集关键信息，例如系统中断路器故障的关键清除时间(tCCT)。tCCT被定义为电力系统从故障发生到故障清除的最大时间。本文利用电力系统动态计算(DCPS)软件包对ieee14总线测试系统进行暂态稳定性分析。这个基于c++的软件包能够处理多达1000个总线和250个发电机的系统，为昂贵的商业软件包提供了另一种选择。为了分析故障定位距离和临界清除时间对系统稳定性的影响，在系统的五个不同位置应用了三相故障。通过对终端电压、电机转子角度、电机转速和输出电功率的仿真图，观察了系统的稳定性。仿真结果表明，故障位置越靠近主发电机，tCCT越小。

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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2012 Third International Conference on Intelligent Systems Modelling and Simulation

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