DC corrective optimal power flow based on generator and branch outages modelled as fictitious nodal injections

This study deals with a new formulation for the direct current corrective optimal power flow. The formulation is based on the outage of generators and/or branches modelled as fictitious injections of active power. By including that fictitious injections in the optimisation problem, the injections ar...

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Bibliographic Details
Published in:IET generation, transmission & distribution transmission & distribution, 2014-03, Vol.8 (3), p.401-409
Main Authors: Martínez-Lacañina, Pedro Jose, Martínez-Ramos, José Luis, de la Villa-Jaén, Antonio, Marano-Marcolini, Alejandro
Format: Article
Language:English
Subjects:
Acceptability
active power
Applied sciences
branch outages
branch power flows
classical topological analysis
Constants
Contingency
contingency analysis
Direct current
direct current corrective optimal power flow
distribution network
distribution networks
Disturbances. Regulation. Protection
electric generators
Electrical engineering. Electrical power engineering
Electrical power engineering
Exact sciences and technology
fictitious nodal injections
generation‐load scenario
generator outage
Generators
generator‐based DC corrective optimal power flow
IEEE‐RTS
load flow
Mathematical models
Miscellaneous
Operation. Load control. Reliability
optimisation
Optimization
Outages
post‐contingency state
Power flow
Power networks and lines
power system
sensitivity matrix
short computation time
subsequent analyses
topology
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Summary:This study deals with a new formulation for the direct current corrective optimal power flow. The formulation is based on the outage of generators and/or branches modelled as fictitious injections of active power. By including that fictitious injections in the optimisation problem, the injections are adjusted to the post-contingency state as a consequence of the corrective actions carried out to bring the system back to its normal state. So, when the analysis of contingencies is performed, the classical topological analysis and the subsequent analyses are avoided with this approach. This new formulation uses the sensitivity matrix between branch power flows and powers injected in a power system. An important feature of this matrix is to remain constant during the contingency analysis performed for the generation-load scenario (base case) of each period of time to be analysed. The approach proposed is illustrated in the IEEE-RTS of 24 buses. The results obtained in this distribution network demonstrate that the proposed methodology can assess the impact of contingencies with an acceptable accuracy and a short computation time.
ISSN:1751-8687
1751-8695
1751-8695
DOI:10.1049/iet-gtd.2013.0322