Energía eólica. Integración a la red eléctrica

En esta obra se aborda el estudio de la estabilidad de pequeña señal en sistemas de potencia con alta penetración eólica utilizando la herramienta computacional PSAT para MATLAB. Adicionalmente, se analiza el efecto de aumento de penetración eólica en varias redes eléctricas hasta lograr su estabili...

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Autores:: López Castrillón, Yuri Ulianov

Tipo de recurso:: Book

Fecha de publicación:: 2016

Institución:: Universidad Autónoma de Occidente

Repositorio:: RED: Repositorio Educativo Digital UAO

Idioma:: spa

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dc.title.spa.fl_str_mv	Energía eólica. Integración a la red eléctrica
title	Energía eólica. Integración a la red eléctrica
spellingShingle	Energía eólica. Integración a la red eléctrica Energía eólica Wind power Sistemas de energía eléctrica Electric power systems Recursos energéticos renovables Renewable energy sources
title_short	Energía eólica. Integración a la red eléctrica
title_full	Energía eólica. Integración a la red eléctrica
title_fullStr	Energía eólica. Integración a la red eléctrica
title_full_unstemmed	Energía eólica. Integración a la red eléctrica
title_sort	Energía eólica. Integración a la red eléctrica
dc.creator.fl_str_mv	López Castrillón, Yuri Ulianov
dc.contributor.author.none.fl_str_mv	López Castrillón, Yuri Ulianov
dc.subject.lemb.spa.fl_str_mv	Energía eólica
topic	Energía eólica Wind power Sistemas de energía eléctrica Electric power systems Recursos energéticos renovables Renewable energy sources
dc.subject.lemb.eng.fl_str_mv	Wind power
dc.subject.armarc.spa.fl_str_mv	Sistemas de energía eléctrica Electric power systems
dc.subject.armarc.eng.fl_str_mv	Recursos energéticos renovables Renewable energy sources
description	En esta obra se aborda el estudio de la estabilidad de pequeña señal en sistemas de potencia con alta penetración eólica utilizando la herramienta computacional PSAT para MATLAB. Adicionalmente, se analiza el efecto de aumento de penetración eólica en varias redes eléctricas hasta lograr su estabilidad. Con este fin, se centra en los modelos de las máquinas generadoras, pasando por la técnica de los escenarios, para finalizar con la propuesta de estabilizadores de sistema de potencia. Finalmente, para mejorar el amortiguamiento del sistema a dichos disturbios, se propone una metodología para la sintonización de un estabilizador de potencia. Para su validación, esta se aplica en las redes inestables que se han encontrado previamente, demostrando los resultados obtenidos, los cuales arrojan que las redes con implementación sintonizada de PSS son estables
publishDate	2016
dc.date.issued.none.fl_str_mv	2016
dc.date.accessioned.none.fl_str_mv	2019-10-01T18:26:27Z
dc.date.available.none.fl_str_mv	2019-10-01T18:26:27Z
dc.type.spa.fl_str_mv	Libro
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dc.type.content.eng.fl_str_mv	Text
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dc.identifier.citation.spa.fl_str_mv	Castrillón L., Y. U. (2016). Energía eólica. Integración a la red eléctrica Programa Editorial Universidad Autónoma de Occidente
dc.identifier.isbn.spa.fl_str_mv	9789588994215
dc.identifier.uri.none.fl_str_mv	http://hdl.handle.net/10614/11161
identifier_str_mv	Castrillón L., Y. U. (2016). Energía eólica. Integración a la red eléctrica Programa Editorial Universidad Autónoma de Occidente 9789588994215
url	http://hdl.handle.net/10614/11161
dc.language.iso.spa.fl_str_mv	spa
language	spa
dc.relation.references.none.fl_str_mv	Ackermann, T. (2002). Söder, Lennart. An overview of wind energystatus 2002. Royal Institute of Technology, Department of Electric Power Engineering. Electric Power Systems. Renewable and Sustainable Energy Reviews. Elsevier Science Ltd. Alboyaci, B., Dursun, B. (2008). Electricity restructuring in Turkey and the share of wind energy production Renewable Energy. doi:10.1016/j.renene. 2008. Anaya-Lara, O. (2006). Modelling and control of Wind Generation Systems. Transmission and Integration of Wind Power Systems: Issues and Solutions. TUTORIAL: 2nd International conference on Integration of Renewable and Distributed Energy Resources. Napa, CA, USA. Dec. 4-8. Anaya-Lara, O., Jenkins, N., Ekanayake, J., Cartwright, P., Hughes, M. (2009). Wind Energy Generation – Modeling and Control. Wiley. Angelidis, G., Semlyen, A. (1996). Improved methodologies for the calculation of critical eigenvalues in small signal stability analysis Power Systems, IEEE Transactions on Volume 11, Issue 3, Page(s):1209 – 1217 Bu, L., Xu, W., Wang, L., Howell, F., Kundur, P. (2003). A PSS Tuning Toolbox and Its Applications. Power Engineering Society General Meeting, 2003, IEEE. Publication Date: 13-17 July. Chen, W., Libao S., Liming, W., Yixin, N. (2008). Small signal stability analysis considering grid-connected wind farms of DFIG type. Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century, Page(s):1 - 6IEEE 20-24 July 2008 Dica, C., Dragoi, C., Dica, C., Vasiliu, N.(2008). Integrating Large Wind Power Plant in The National Power System. The International Conference on Hydraulic Machinery and Equipments Timisoara, Romania. Scientific Bulletin of the Politehnica University of Timisoara Transactions on Mechanics Special Issue ISSN 1224 - 6077; Tom 53 (67). EWEA, European Wind Energy Association (2003). Wind Energy - The Facts. The European Wind Energy Association. Fernández, R., Mantz, R. J., Battaiotto, P. (2007). Potential Contribution of wind farms to damp oscillations in weak grids with high wind penetration. Renewable Energy 32 doi:10.1016/ jser.2007.01013. 2007 Gipe, P. (2004). Wind Power: Renewable Energy for Home, Farm, and Business. Chelsea Green Gourieres, D. Le. (1982). Wind power plants—theory and design. Pergamon Press, Oxford, 1982, 300 pp Holttinen, H., Uhlen, K., Meibom, M., Söder, L., Andersen, J., Weber, C., Barth, R., Nielsen, C. (2005). WP9 Recommendations. WILMAR – Wind Power Integration in Liberalised Electricity Markets Hughes, F. M., Anaya-Lara, O., Jenkins, N., Strbac, G. (2005). Control of DFIG-based wind generation for power network support. Power Systems, IEEE Transactions on. Volume: 20 , Issue: 4. pp. 958 – 1966 IEEE (1990). Power & Energy Society. Power System Dynamic Performance Committee. System dynamic performance subcommittee. “Voltage Stability of Power Systems: Concepts, Analytical tools, and industry experience”, IEEE 90TH0358-2-PWR, Piscataway, NJ, USA, 1990. IEEE (2004). IEEE Guide for the Preparation of Excitation System Specifications. IEEE Std 421.4-2004. (Revision of IEEE Std 421.4TM-1990). IEEE/CIGRE (2004). Joint Task Force on Stability Terms and Definitions. Definition and Classification of Power System Stability. IEEE Transactions On Power Systems, Vol. 19, No. 2, pp. 1387 – 1401. Jauch, C., Sorensen, P., Jensen, B. B. (2004). International Review of Grid Connection Requirements for Wind Turbines. Nordic Wind Power Conference, (NWPC 04), Göteborg, 1-2. Kim Dong, J., Nam Hae-Kon, M. (2007). SSR Small-Signal Stability Analysis Program of Power Systems and its Application to IEEE Benchmark Systems. Power Tech 2007. Lausanne, Switzerland. Kling, W., Ummels, B., Hendrik, R. (2007). Transmission and System Integration of Wind Power in the Netherlands Power Engineering Society General Meeting. IEEE 24-28 June 2007:1 – 6. Kundur, P., Rogers, G. J., Wong, D. Y., Wang, L., Lauby, M. G. (1990). A Comprehensive Computer Program Package For Small Signal Stability Analysis Of Power Systems. IEEE Transactions on Power Systems, Vol. 5, No. 4 Laín, S., Quintero, B., López, Y. (2007). Aerodynamic and structural evaluation of horizontal axis wind turbines with rated power over 1MW. ICREPQ07. Sevilla, Spain Larsen, E. V., Swann. (1981). Applying Power System Stabilizers. Part I,II,III.IEEE Transaction on power apparatus and systems, Vol. PAS100, No6, pp.3017-3024 Lundberg, S. (2003). Performance comparisons of wind park configurations. Technical Report No. 30R. Department of Electric Power Engineering. CHALMERS. UNIVERSITY OFTECHNOLOGY. Göoteborg, Sweden. Makarov, Y., Yang, Z., Hill, D. (1998), A General Method for Small Signal Stability Analysis. IEEE Transactions on Power Systems, Vol. 13, No. 3, August. Martins, N., Pinto, H. (1995). Modern Tools for the Small-Signal Stability Analysis and Design of FACTS Assisted Power System. In: STOCKHOLM POWER TECH. Conference, 1995, Stockolm. Proceedings of Stockholm Power Tech. Conference Mignard, D., Harrison, G. P., (2007). Pritchard C.L. Contribution of wind power and HP to exports from Western Denmark during 2000– 2004 Renewable Energy December;32(15):2516–2528 100. Mithulananthan, N., Canizares, C. A., Reeve, J., Rogers, G. J. (2003). Comparison of PSS, SVC, and STATCOM controllers for damping power system oscillations. Power Systems, IEEE Transactions on Volume 18, Issue 2. Naimi, D., Bouktir, T. Impact of Wind Power on the Angular Stability of a Power System. Leonardo Electronic Journal of Practices and Technologies. Issue 12, January-June 2008. ISSN 1583-1078 National Academy Press (2000). Renewable Power Pathways. A Review Of the U.S. Department Of Energy’s Renewable Energy Programs. Washington D.C National Centre of Renewable Energies (2005). Socintec, Foundation for the Promotion of Industrial Innovation (F212). Renovalia Project, Situation Of Renewable Energies In Spain. Final Report. Parashar, M., Eto, J., Dyer, J. (2006). Phasor Applications for Monitoring, Alarming & Control. SSS and phasor applications. Consortium for Electric Reliability Technology Solutions – CERTS, California USA - CERTS-CAISO Meeting Peterson, A. (2005). Analysis, Modeling and Control of Doubly –Fed Induction Generators for Wind Turbines. Ph.D. Thesis at Division of Electric Power Engineering. Department of Energy and Environment. Chalmers University of Technology. Göteborg Polinder, H., Sjoerd, W. De H., Dubois, M., Johannes, G. (2004). Basic Operation Principles and Electrical Conversion Systems of Wind Turbines. 4th Nordic Workshop on Power and Industrial Electronics. Trondheim 14-16 June Quintero, J. (2005). A Real-Time Wide-Area Control For Mitigating Small-Signal Instability In Large Electric Power Systems. Ph.D. thesis. Washington State University. Rosas, P. (2003). Dynamic Influences Of Wind Power On The Power System. Ph.D. thesis . Ørsted Institute, Section of Electric Power Engineering. Technical University of Denmark. Ørsted Institute, Risø National Laboratory & Brazilian Wind Energy Centre Denmark, R-1408 ISBN: 87-91184-16-9. Rouco, L., Perez, M., Diez, M. (2007). Contribution of wind power generation to power system stabilization. International Journal of Tomography & Statistics. Indian Society for Development & Environment Research. Copyright 2008 Gale, Cengage Learning Sadrià, A., Chindris, M., Sumper, A., Gross, G., Ferrer, F. (2005). Politechnical University of Catalonia. Spain. Technical University of ClujNapoca, Romania. Wind Turbine Operation in Power Systems and Grid Connection Requirements. ICREPQ, Zaragoza Spain SINTEF (2009). Power system stability and wind power integration in the Nordel system. http://www.sandc.com/services/seminars/voltagestability.asp Slootweg, J. G., Kling, W. L. (2003). The impact of large scale wind power generation on power system oscillations. Electric Power Systems Research Vol.67. Issue 1. Pages 9-20 Slootweg, J. G., Kling, W. L.(2002). Modelling and Analysing Impacts of Wind Power on Transient Stability of Power Systems, Wind Engineering. Vol. 26, no. 1, pp. 3-20. Soens, J., Driesen, J., Belmans, R. (2004). Wind Turbine Modelling Approaches for Dynamic Power System Simulations. Technical report of research project ‘Embedded Generation: A Global Approach To Energy Balance And Grid Power Quality And Security’. http://www. esat.kuleuven.be/electa/publications/fulltexts/pub_1188.pdf. Taylor, G. A., Irving, M. R., Axon, C., Hobson, P. R. Scalable Integration of Wind Power on Transmission Systems using Grid Computing. The Sixth International Workshop on Large-scale Integration of Wind Power and Transmission Networks for Offshore Wind Farms TERNA-Studie. (2002). Energiewirtschaftliche Rahmenbedingungen und Anreizsysteme fur netzgekoppelte Stromproduktion aus erneuerbaren Energien; published by: Deutsche Gesellschaft fur Technische Zusammenarbeit (GTZ)—German Technical Cooperation, Eschborn, Germany Tsourakis, G., Nomikos, B. M., Vournas, C. D. (2009). Effect of wind parks with doubly fed asynchronous generators on small-signal stability electric Power Systems Research. Volume 79, Issue 1, Pages 190-200 Ulianov, Y., Domínguez, J. (2008). Small signal stability analysis of wind turbines with squirrel cage induction generators. IEEE .Transmission and Distribution Conference and Exposition: Latin America, IEEE/PES Vargas, L. S., Verdejo, H., Kliemann, W. (2008). A stochastic methodology for modeling PSS in small signal stability analysis. 40th North American Power Symposium, 2008. NAPS ‘08.. Publication Page(s): 1 - 6. Wang, C., Libao, S., Liming, W., Yixin, N. (2008). Small Signal Stability Considering Grid-Connected Wind Farms of DFIG Type. IEEE Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century Wu, F. X. P., Zhang, K., Godfrey y Ju, P. (2007). Small Signal Stability Analysis and optimal control of a wind turbine with doubly fed induction generator. The Institution of Engineering and Technology 2007. IET Generation Transmission and Distribution, Vol. 1, No. 5. 07, 1, (5), pp. 751–760. Xu, Z., Mohsin, A., Dong, Z., Li, X. (2006). A novel grid computing approach for probabilistic small signal analysis. IEEE Power Engineering Society General Meeting Zhou, Y. (2008). Grid Friendly Wind Power Plant - Concept and Control. Proceedings ewec 2008. Dutch Wind Workshops, October 2008 Zima, M. (2002). Special Protection Schemes in Electric Power Systems - Literature survey. Swiss Federal Institute of Technology. Technical Report Zinger, D. S., Muljadi, E. (1997). Annualized Wind Energy Improvement Using Variable Speeds. IEEE Transactions on Industry Applications. Vol. 33, no. 6. November-December, pp. 1444-1447.
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spelling	López Castrillón, Yuri Ulianovvirtual::2771-1Universidad Autónoma de Occidente. Calle 25 115-85. Km 2 vía Cali-Jamundí2019-10-01T18:26:27Z2019-10-01T18:26:27Z2016Castrillón L., Y. U. (2016). Energía eólica. Integración a la red eléctrica Programa Editorial Universidad Autónoma de Occidente9789588994215http://hdl.handle.net/10614/11161En esta obra se aborda el estudio de la estabilidad de pequeña señal en sistemas de potencia con alta penetración eólica utilizando la herramienta computacional PSAT para MATLAB. Adicionalmente, se analiza el efecto de aumento de penetración eólica en varias redes eléctricas hasta lograr su estabilidad. Con este fin, se centra en los modelos de las máquinas generadoras, pasando por la técnica de los escenarios, para finalizar con la propuesta de estabilizadores de sistema de potencia. Finalmente, para mejorar el amortiguamiento del sistema a dichos disturbios, se propone una metodología para la sintonización de un estabilizador de potencia. Para su validación, esta se aplica en las redes inestables que se han encontrado previamente, demostrando los resultados obtenidos, los cuales arrojan que las redes con implementación sintonizada de PSS son establesAntecedentes de la estabilidad en pequeña señal en sistemas eléctricos. Clasificación de la Estabilidad de Sistemas de Potencia. Estabilidad de Pequeña Señal. Estabilidad de Pequeña Señal en Sistemas de Potencia con Aerogeneradores. Modelado de Turbinas Eólicas. Modelado de Altos Niveles de Penetración Eólica. Mejora de la estabilidad con soluciones clásicas. PSS en Generadores Tradicionales. Estabilizadores del Sistema de Potencia (PSS). Objetivo del PSS. Diseño y configuración. Sintonizado. Mejora de la estabilidad de Pequeña Señal en Aerogeneradores. Mejora de la estabilidad con PSS en Aerogeneradores. Simulación y análisis de estabilidad. Turbina Eólica de Velocidad Constante con SCIG. Parámetros del Modelo. Modelo del Generador en PSAT. Análisis de valores propios. Simulación en el Dominio del Tiempo. Turbina Eólica con Generador Síncrono de Acople Directo – DDSG. Parámetros del Modelo. Modelo del Generador en PSAT. Análisis de Valores Propios. Simulación en el Dominio del Tiempo. Turbina Eólica con Generador de Inducción. Doblemente Alimentado DFIG. Parámetros del Modelo. Modelo del Generador en PSAT. Análisis de Valores Propios. Simulación en el Dominio del Tiempo. Parque Eólico usando Generadores de Inducción Jaula de Ardilla – SCIG. Penetración de Bajos Niveles de Generación Eólica. Penetración de Altos Niveles de Energía Eólica. Mejora de la Estabilidad con Estabilizadores de Potencia (PSS) en Aerogeneradores. Modelado del Sistema de Potencia con Turbina Eólica y Sistema Equivalente para PSS. Modelado y Simulación del Sistema Equivalente. Definición de Ganancias y Constantes de Tiempo. Determinar Compensación usando Diagrama Bode. Parámetros de Cálculo del Sistema Compensado. Análisis de Compensación de Faseapplication/pdf210 páginasspaUniversidad Autónoma de OccidenteDerechos Reservados - Universidad Autónoma de Occidentehttps://creativecommons.org/licenses/by-nc-nd/4.0/info:eu-repo/semantics/restrictedAccessAtribución-NoComercial-SinDerivadas 4.0 Internacional (CC BY-NC-ND 4.0)http://purl.org/coar/access_right/c_16echttps://editorial.uao.edu.co/energia-eolica-integracion-a-la-red-electrica-ingenieria-de-la-energia.htmlreponame:Repositorio Institucional UAOEnergía eólica. Integración a la red eléctricaLibrohttp://purl.org/coar/resource_type/c_2f33Textinfo:eu-repo/semantics/bookhttps://purl.org/redcol/resource_type/LIBinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/version/c_970fb48d4fbd8a85Energía eólicaWind powerSistemas de energía eléctricaElectric power systemsRecursos energéticos renovablesRenewable energy sourcesAckermann, T. (2002). Söder, Lennart. An overview of wind energystatus 2002. Royal Institute of Technology, Department of Electric Power Engineering. Electric Power Systems. Renewable and Sustainable Energy Reviews. Elsevier Science Ltd.Alboyaci, B., Dursun, B. (2008). Electricity restructuring in Turkey and the share of wind energy production Renewable Energy. doi:10.1016/j.renene. 2008.Anaya-Lara, O. (2006). Modelling and control of Wind Generation Systems. Transmission and Integration of Wind Power Systems: Issues and Solutions. TUTORIAL: 2nd International conference on Integration of Renewable and Distributed Energy Resources. Napa, CA, USA. Dec. 4-8.Anaya-Lara, O., Jenkins, N., Ekanayake, J., Cartwright, P., Hughes, M. (2009). Wind Energy Generation – Modeling and Control. Wiley.Angelidis, G., Semlyen, A. (1996). Improved methodologies for the calculation of critical eigenvalues in small signal stability analysis Power Systems, IEEE Transactions on Volume 11, Issue 3, Page(s):1209 – 1217Bu, L., Xu, W., Wang, L., Howell, F., Kundur, P. (2003). A PSS Tuning Toolbox and Its Applications. Power Engineering Society General Meeting, 2003, IEEE. Publication Date: 13-17 July.Chen, W., Libao S., Liming, W., Yixin, N. (2008). Small signal stability analysis considering grid-connected wind farms of DFIG type. Power and Energy Society General Meeting - Conversion and Delivery of Electrical Energy in the 21st Century, Page(s):1 - 6IEEE 20-24 July 2008Dica, C., Dragoi, C., Dica, C., Vasiliu, N.(2008). Integrating Large Wind Power Plant in The National Power System. The International Conference on Hydraulic Machinery and Equipments Timisoara, Romania. Scientific Bulletin of the Politehnica University of Timisoara Transactions on Mechanics Special Issue ISSN 1224 - 6077; Tom 53 (67).EWEA, European Wind Energy Association (2003). Wind Energy - The Facts. The European Wind Energy Association.Fernández, R., Mantz, R. J., Battaiotto, P. (2007). Potential Contribution of wind farms to damp oscillations in weak grids with high wind penetration. Renewable Energy 32 doi:10.1016/ jser.2007.01013. 2007Gipe, P. (2004). Wind Power: Renewable Energy for Home, Farm, and Business. Chelsea GreenGourieres, D. Le. (1982). Wind power plants—theory and design. Pergamon Press, Oxford, 1982, 300 ppHolttinen, H., Uhlen, K., Meibom, M., Söder, L., Andersen, J., Weber, C., Barth, R., Nielsen, C. (2005). WP9 Recommendations. WILMAR – Wind Power Integration in Liberalised Electricity MarketsHughes, F. M., Anaya-Lara, O., Jenkins, N., Strbac, G. (2005). Control of DFIG-based wind generation for power network support. Power Systems, IEEE Transactions on. Volume: 20 , Issue: 4. pp. 958 – 1966IEEE (1990). Power & Energy Society. Power System Dynamic Performance Committee. System dynamic performance subcommittee. “Voltage Stability of Power Systems: Concepts, Analytical tools, and industry experience”, IEEE 90TH0358-2-PWR, Piscataway, NJ, USA, 1990.IEEE (2004). IEEE Guide for the Preparation of Excitation System Specifications. IEEE Std 421.4-2004. (Revision of IEEE Std 421.4TM-1990).IEEE/CIGRE (2004). Joint Task Force on Stability Terms and Definitions. Definition and Classification of Power System Stability. IEEE Transactions On Power Systems, Vol. 19, No. 2, pp. 1387 – 1401.Jauch, C., Sorensen, P., Jensen, B. B. (2004). International Review of Grid Connection Requirements for Wind Turbines. Nordic Wind Power Conference, (NWPC 04), Göteborg, 1-2.Kim Dong, J., Nam Hae-Kon, M. (2007). SSR Small-Signal Stability Analysis Program of Power Systems and its Application to IEEE Benchmark Systems. Power Tech 2007. Lausanne, Switzerland.Kling, W., Ummels, B., Hendrik, R. (2007). Transmission and System Integration of Wind Power in the Netherlands Power Engineering Society General Meeting. IEEE 24-28 June 2007:1 – 6.Kundur, P., Rogers, G. J., Wong, D. Y., Wang, L., Lauby, M. G. (1990). A Comprehensive Computer Program Package For Small Signal Stability Analysis Of Power Systems. IEEE Transactions on Power Systems, Vol. 5, No. 4Laín, S., Quintero, B., López, Y. (2007). Aerodynamic and structural evaluation of horizontal axis wind turbines with rated power over 1MW. ICREPQ07. Sevilla, SpainLarsen, E. V., Swann. (1981). Applying Power System Stabilizers. Part I,II,III.IEEE Transaction on power apparatus and systems, Vol. PAS100, No6, pp.3017-3024Lundberg, S. (2003). Performance comparisons of wind park configurations. Technical Report No. 30R. Department of Electric Power Engineering. CHALMERS. UNIVERSITY OFTECHNOLOGY. Göoteborg, Sweden.Makarov, Y., Yang, Z., Hill, D. (1998), A General Method for Small Signal Stability Analysis. IEEE Transactions on Power Systems, Vol. 13, No. 3, August.Martins, N., Pinto, H. (1995). Modern Tools for the Small-Signal Stability Analysis and Design of FACTS Assisted Power System. In: STOCKHOLM POWER TECH. Conference, 1995, Stockolm. Proceedings of Stockholm Power Tech. ConferenceMignard, D., Harrison, G. P., (2007). Pritchard C.L. Contribution of wind power and HP to exports from Western Denmark during 2000– 2004 Renewable Energy December;32(15):2516–2528 100.Mithulananthan, N., Canizares, C. A., Reeve, J., Rogers, G. J. (2003). Comparison of PSS, SVC, and STATCOM controllers for damping power system oscillations. Power Systems, IEEE Transactions on Volume 18, Issue 2.Naimi, D., Bouktir, T. Impact of Wind Power on the Angular Stability of a Power System. Leonardo Electronic Journal of Practices and Technologies. Issue 12, January-June 2008. ISSN 1583-1078National Academy Press (2000). Renewable Power Pathways. A Review Of the U.S. Department Of Energy’s Renewable Energy Programs. Washington D.CNational Centre of Renewable Energies (2005). Socintec, Foundation for the Promotion of Industrial Innovation (F212). Renovalia Project, Situation Of Renewable Energies In Spain. Final Report.Parashar, M., Eto, J., Dyer, J. (2006). Phasor Applications for Monitoring, Alarming & Control. SSS and phasor applications. 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