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Portada de Planning of Interconnected Powers Systems Considering Security Under Cascading Outages and Catastrophic Events

Planning of Interconnected Powers Systems Considering Security Under Cascading Outages and Catastrophic Events

Varios autores

Ediciones Uniandes ·Colombia ·2011
Impreso ISBN 9789586955546

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Esta publicación no tiene una declaración de licencia TDM (minería de texto y datos) registrada. La editorial titular puede declararla desde su cuenta en SIMEH; quedará publicada aquí con fecha y hora certificadas.

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FormatoISBNRecordreferenceDOIAño
Impreso 9789586955546 SIMEHPRINTUWB8JQQG5YBU3J3IFBUG 2011

Sobre esta obra

This dissertation presents a method for assessing the vulnerability of a composite power system. It is based on the modeling of failures and repairs using stochastic point process theory and a procedure of the sequential Monte Carlo simulation to compute the indices of vulnerability. Stochastic point process modeling allows including constant and time-varying rates, a necessity in those scenarios considering aging and diverse maintenance strategies. It also allows representing the repair process performed in the power system as it really is: a queuing system. The sequential Monte Carlo simulation is applied because it can artificially generate all the aspects involved in the operating sequence of a power system and also because it can easily manage non-stationary probabilistic models. The indices of vulnerability are the probability of occurrence of a high-order 1055 of component scenario, its frequency and its duration. A high-order loss of component scenario is that one higher than n - 2. Examples using the IEEE One Area RTS show how the presence of aging and others factors that produce increasing component failure rates dramatically increase the risk of occurrence of high-order loss of component scenarios. On the other hand, the improvement in aspects such as preventive maintenance and repair performance reduces this risk. Although the main focus of this method is composite power systems, its development produced other outcomes, such as procedures for assessment of power distribution systems, protective relaying schemes and power substations.The sequential Monte Carlo simulation is applied because it can artificially generate all the aspects involved in the operating sequence of a power system and also because it can easily manage non-stationary probabilistic models. The indices of vulnerability are the probability of occurrence of a high-order 1055 of component scenario, its frequency and its duration. A high-order loss of component scenario is that one higher than n - 2. Examples using the IEEE One Area RTS show how the presence of aging and others factors that produce increasing component failure rates dramatically increase the risk of occurrence of high-order loss of component scenarios. On the other hand, the improvement in aspects such as preventive maintenance and repair performance reduces this risk. Although the main focus of this method is composite power systems, its development produced other outcomes, such as procedures for assessment of power distribution systems, protective relaying schemes and power substations.On the other hand, the improvement in aspects such as preventive maintenance and repair performance reduces this risk. Although the main focus of this method is composite power systems, its development produced other outcomes, such as procedures for assessment of power distribution systems, protective relaying schemes and power substations.

Editorial

Ediciones Uniandes · Colombia

Año de publicación

2011