A Line Outage Study for Prediction of Static Power Flow Redistribution

Transmission line is a crucial role in power transmission network which connects generating units to consumers. Some unpredicted failure events such as lightening or system faults can cause transmission line tripped, which may bring about a large interruption to the system and causes damage. When li...

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Main Author: Wei, Nan
Other Authors: Electrical and Computer Engineering
Format: Others
Published: Virginia Tech 2016
Subjects:
Online Access:http://hdl.handle.net/10919/72887
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spelling ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-728872021-12-08T05:44:48Z A Line Outage Study for Prediction of Static Power Flow Redistribution Wei, Nan Electrical and Computer Engineering De La Ree, Jaime Centeno, Virgilio A. Kekatos, Vasileios Transmission Line Outage Contingency Analysis Power Flow Redistribution Line Outage Distribution Factor Thevenin Equivalent Electrical Distance Transmission line is a crucial role in power transmission network which connects generating units to consumers. Some unpredicted failure events such as lightening or system faults can cause transmission line tripped, which may bring about a large interruption to the system and causes damage. When line outage happens, the power flow on the tripped line will be redistributed to the rest of lines in the system. It may cause risk of overload happens on other lines, and results in a cascading failure and system collapse. Reasonably, a single line outage will not affect all other lines in the system. Therefore, when a line outage happens, it is important for the system operator to have a preview of which lines will have serious impact and which lines will not, so that the operator can only focus on monitoring certain lines which will be seriously affected, rather than keeping monitoring the whole system. In this thesis, A Line Outage Distribution Factor (LODF) method is proposed and implemented in the IEEE 118 bus system to estimate active power flow redistribution after a line outage. After that, a definition of Thevenin electrical distance between two transmission lines is derived and applied to calculate electrical distances between the outage line and each line in the system. An exponential convergence tendency is found between maximum possible LODF predicted power flow variations and electrical distance, and an exponential regression method is applied to analyze this tendency. The contribution of this work is a rule has been found that starting from the outage line, the maximum possible active power flow variation on transmission lines exponentially decreases exponentially while the electrical distance increases. With only the information of system's normal operating condition and topological information, the maximum possible active power change on each lines caused by single line outage, and the margin of the impact of single line outage on power flow variations may propagate along electrical distance can be easily and quickly predicted. Ultimately, the goal of this work is to allow operators at the control center can concentrate on lines within a certain electrical distance instead of keeping monitoring the whole system when a line outage happens. Master of Science 2016-09-07T08:00:42Z 2016-09-07T08:00:42Z 2016-09-06 Thesis vt_gsexam:8876 http://hdl.handle.net/10919/72887 In Copyright http://rightsstatements.org/vocab/InC/1.0/ ETD application/pdf Virginia Tech
collection NDLTD
format Others
sources NDLTD
topic Transmission Line Outage
Contingency Analysis
Power Flow Redistribution
Line Outage Distribution Factor
Thevenin Equivalent Electrical Distance
spellingShingle Transmission Line Outage
Contingency Analysis
Power Flow Redistribution
Line Outage Distribution Factor
Thevenin Equivalent Electrical Distance
Wei, Nan
A Line Outage Study for Prediction of Static Power Flow Redistribution
description Transmission line is a crucial role in power transmission network which connects generating units to consumers. Some unpredicted failure events such as lightening or system faults can cause transmission line tripped, which may bring about a large interruption to the system and causes damage. When line outage happens, the power flow on the tripped line will be redistributed to the rest of lines in the system. It may cause risk of overload happens on other lines, and results in a cascading failure and system collapse. Reasonably, a single line outage will not affect all other lines in the system. Therefore, when a line outage happens, it is important for the system operator to have a preview of which lines will have serious impact and which lines will not, so that the operator can only focus on monitoring certain lines which will be seriously affected, rather than keeping monitoring the whole system. In this thesis, A Line Outage Distribution Factor (LODF) method is proposed and implemented in the IEEE 118 bus system to estimate active power flow redistribution after a line outage. After that, a definition of Thevenin electrical distance between two transmission lines is derived and applied to calculate electrical distances between the outage line and each line in the system. An exponential convergence tendency is found between maximum possible LODF predicted power flow variations and electrical distance, and an exponential regression method is applied to analyze this tendency. The contribution of this work is a rule has been found that starting from the outage line, the maximum possible active power flow variation on transmission lines exponentially decreases exponentially while the electrical distance increases. With only the information of system's normal operating condition and topological information, the maximum possible active power change on each lines caused by single line outage, and the margin of the impact of single line outage on power flow variations may propagate along electrical distance can be easily and quickly predicted. Ultimately, the goal of this work is to allow operators at the control center can concentrate on lines within a certain electrical distance instead of keeping monitoring the whole system when a line outage happens. === Master of Science
author2 Electrical and Computer Engineering
author_facet Electrical and Computer Engineering
Wei, Nan
author Wei, Nan
author_sort Wei, Nan
title A Line Outage Study for Prediction of Static Power Flow Redistribution
title_short A Line Outage Study for Prediction of Static Power Flow Redistribution
title_full A Line Outage Study for Prediction of Static Power Flow Redistribution
title_fullStr A Line Outage Study for Prediction of Static Power Flow Redistribution
title_full_unstemmed A Line Outage Study for Prediction of Static Power Flow Redistribution
title_sort line outage study for prediction of static power flow redistribution
publisher Virginia Tech
publishDate 2016
url http://hdl.handle.net/10919/72887
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