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dc.contributor.advisorGhandhari Alavijh, Mehrdad
dc.contributor.authorNasri, Amin
dc.contributor.otherUniversidad Pontificia Comillas, Escuela Técnica Superior de Ingeniería (ICAI)es_ES
dc.date.accessioned2015-09-07T08:10:58Z
dc.date.available2015-09-07T08:10:58Z
dc.date.issued2014
dc.identifier.urihttp://hdl.handle.net/11531/2666
dc.descriptionPrograma de Doctorado Erasmus Mundus en Tecnologías y Estrategias Energéticas Sostenibles / Erasmus Mundus Joint Doctorate in Sustainable Energy Technologies and Strategieses_ES
dc.description.abstractNowadays, power systems are dealing with new challenges raised due to some recent changes, e.g., large-scale integration of renewable energy resources such as wind power, deregulation in electricity markets and significant increase of electricity demands. Therefore, system operators must make some adjustments to accommodate these changes into the future of power systems. One of the main challenges is maintaining the system stability since the extra stress caused by the above changes reduces the stability margin, and may lead to rise of many undesirable phenomena. The other important challenge is to cope with uncertainty and variability of renewable energy sources which make power systems more stochastic in nature, and less controllable. Flexible AC Transmission Systems (FACTS) have emerged as a solution to help power systems with these new challenges. This thesis aims to appropriately utilize such devices in order to increase the transmission capacity and flexibility, improve the dynamic behavior of power systems and integrate more renewable energy into the system. To this end, the most appropriate locations and settings of these controllable devices need to be determined. This thesis mainly looks at (i) rotor angle stability, i.e., small signal and transient stability (ii) system operation under wind uncertainty. In the first part of this thesis, trajectory sensitivity analysis is used to determine the most suitable placement of FACTS devices for improving rotor angle stability, while in the second part, optimal settings of such devices are found to maximize the level of wind power integration. As a general conclusion, it was demonstrated that FACTS devices, installed in proper locations and tuned appropriately, are effective means to enhance the system stability and to handle wind uncertainty. The last objective of this thesis work is to propose an efficient solution approach based on Benders’ decomposition to solve an ac unit commitment (ac-UC) problem in a wind-integrated power system. The numerical results show validity, accuracy and efficiency of the proposed approach.es_ES
dc.format.mimetypeapplication/pdfes_ES
dc.language.isoenes_ES
dc.subject33 Ciencias tecnológicases_ES
dc.subject3306 Ingeniería y tecnología eléctricases_ES
dc.subject3308 Ingeniería y tecnología del medio ambientees_ES
dc.titleOn the dynamics and statics of power system operation : optimal utilization of FACTS devices and management of wind power uncertaintyes_ES
dc.typeinfo:eu-repo/semantics/doctoralThesises_ES
dc.rights.accessRightsinfo:eu-repo/semantics/closedAccesses_ES
dc.keywordsTrajectory sensitivity analysis (TSA), Transient stability, Small signal stability, Flexible AC transmission system (FACTS) devices, Dritical clearing time (CCT), Optimal power flow (OPF), ac unit commitment (ac-UC), Wind power uncertainty, Wind power spillage, Stochastic programming, Benders’ decomposition.es_ES


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