Recursos y sistemas energéticos renovables del entorno marino y sus requerimientos de control

E. García; A. Correcher; E. Quiles; F. Morant

doi:10.1016/j.riai.2016.03.002

Autores/as

E. García Universitat Politècnica de València
A. Correcher Universitat Politècnica de València
E. Quiles Universitat Politècnica de València
F. Morant Universitat Politècnica de València

DOI:

https://doi.org/10.1016/j.riai.2016.03.002

Palabras clave:

Generadores Eólicos Flotantes, Turbinas de Corrientes Marinas, Energía Undimotriz

Resumen

En este artículo se presentan una serie de dispositivos generadores de energía renovable procedente del entorno marino, que en los últimos años han despertado creciente interés. En especial se describen los tipos principales de Generadores Eólicos Flotantes, las Turbinas de Corriente Marina y diversos dispositivos basados en Energía Undimotriz. Se destacan los principales requerimientos a considerar bajo el punto de vista de la ingeniería de control, considerando los objetivos de viabilidad económica a alcanzar teniendo en cuenta su estabilidad, fiabilidad y disponibilidad en un medio marino especialmente agresivo, donde las operaciones de mantenimiento resultan especialmente costosas.

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Biografía del autor/a

E. García, Universitat Politècnica de València

Departamento de Ingeniería de Sistemas y Automática, Universitat Politècnica de València

A. Correcher, Universitat Politècnica de València

Departamento de Ingeniería de Sistemas y Automática, Universitat Politècnica de València

E. Quiles, Universitat Politècnica de València

Departamento de Ingeniería de Sistemas y Automática, Universitat Politècnica de València

F. Morant, Universitat Politècnica de València

Departamento de Ingeniería de Sistemas y Automática, Universitat Politècnica de València

Citas

Avia F. 2008. Plantas Eólicas Marinas. Departamento de Energía Eólica. CENER www.fundacionenergia.es/pdfs/Eolica%20Nov%202008

Ben Elghali, S.E., Benbouzid, M.E.H., Ahmed-Ali, T., Charpentier J.F., Mekri, F. 2009. High-Order Sliding Mode Control of DFIG-Based Marine Current Turbine. Electric Machines and Drives Conference. IEMDC '09. IEEE International.

Ben Elghali, S. E., Benbouzid, M. E. H., & Charpentier, J. F. 2007. Marine tidal current electric power generation technology: State of the art and current status. In Electric Machines & Drives Conference, 2007. IEMDC'07. IEEE International (Vol. 2, pp. 1407-1412). IEEE.

Betti, G., Farina, M., Marzorati, A., Scattolini, R., Guagliardi., G. A. 2012. Modeling and control of a floating wind turbine with spar buoy platform. In Energy Conference and Exhibition (ENERGYCON), 2012 IEEE International (pp. 189-194). IEEE.

Betti, G., Farina, M., Guagliardi, G. A., Marzorati, A., Scattolini, R. 2014. Development of a Control-Oriented Model of Floating Wind Turbines. IEEE Transactions On Control Systems Technology, Vol. 22, No. 1, January 2014.

Blue Energy Canada Inc., (2000), www.bluenergy.com, Canada.

Boud, R., 2003. Status and Research and Developement Priorities. Wave and Marine Current Energy. UK Department of Trade and Industry (DTI).

Caraiman, G., Nichita, C., Mînzul, V., Dakyio, B., Jo, C.H. 2011. Concept study of offshore wind and tidal hybrid conversion based on real time simulation. International Conference on Renewable Energies and Power Quality (ICREPQ’11) Las Palmas de Gran Canaria (Spain), 13th to 15th April.

CEC (Commission of the European Communities), DGXII. 1996. Wave Energy Project Results: The Exploitation of Tidal Marine Currents. Report EUR16683EN.

Comission, E. Ocean energy conversion in Europe: Recent advancements and prospects. 2006. Centre for Renewable Energy Sources: Pikermi, Greece, 36.

de Sousa Prado, M. G., Gardner, F., Damen, M., & Polinder, H. 2006. Modelling and test results of the Archimedes wave swing. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 220(8), 855-868.

Drew, B., Plummer, A. R., & Sahinkaya, M. N. 2009. A review of wave energy converter technology. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 223(8), 887-902.

Edwards, K., & Mekhiche, M. 2013. Ocean Testing of a Wave-Capturing PowerBuoy. In Marine Energy Technology Symposium, Washington, DC.

Fantidis, J.G., Potolias, C., Bandekas D.V. 2011. Wind turbine blade nondestructive testing with a transportable Radiography system. Science and Technology of Nuclear Installations. Volume 2011.

Fuglseth T.P., Undeland, T. M. 2006. Modelling of floating wind turbines for simulation and design of axial thrust and power control strategies. Proceedings of Renewable Energy 2006, Chiba, Japan. 2006.

García, E., Morant, F., Correcher, A., Quiles, E., Llanes, O. 2009. Seguimiento de Estado, Diagnóstico de Fallos y Mantenimiento Industrial: una visión integrada. Proceedings de la Novena Semana Tecnológica. La Habana. 2009.

García, E., Fabuel, D., Pizá, R., Morant, F., Correcher, A., Quiles, E. 2012. Hydro-wind kinetics integrated module for the renewable energy generation. In OCEANS, 2012-Yeosu (pp. 1-6). IEEE.

García, E., Morant, F., Correcher, A., Quiles, E., Fabuel, D., Rodriguez, L., Llanes, O. 2012. Módulo Integrado de Cinética Hidro-Eólica para la Generación Eléctrica Renovable. Congreso Latinoamericano de Control. Lima. 2012.

García, E., Pizá, R., Benavides, X., Quiles, E., Correcher, A., Morant, F. 2014. Mechanical Augmentation Channel Design for Turbine Current Generators. Advances in Mechanical Engineering, 6, 650131.

García, F. P. G., Tobias, A. M., Pérez, J. M. P., Papaelias, M. 2012b. Condition monitoring of wind turbines: Techniques and methods. Renewable Energy, 46, 169-178.

Geyler, M., Caselitz, P. 2007. Individual Blade Pitch Control Design for Load Reduction on Large Wind Turbines. Proc. EWEC 2007, Milano.

González, A. M. 2008. Estado del arte del control de la potencia en generadores eólicos” Revista Investigaciones Aplicadas. Universidad Pontificia Bolivariana (2008)

Guo, P., Infield, D., Yang, X. 2012. Wind turbine generator conditionmonitoring using temperature trend analysis. Sustainable Energy, IEEE Transactions on, 3(1), 124-133.

Hameed, Z., Hong, Y.S., Cho, Y.M., Ahn, S.H., Song, C.K. 2009. Condition monitoring and fault detection of wind turbines and related algorithms: A review. Renewable and Sustainable Energy Reviews, 13(1):1–39.

Henderson, R. 2006. Design, simulation, and testing of a novel hydraulic power take-off system for the Pelamis wave energy converter. Renewable energy, 31(2), 271-283.

Isaacs, J.D., Seymour, R.J. 1973. The Ocean as a Power Resource, Int. Journal of Environmental Studies, vol. 4(3), pp 201-205.

Jonkman, J. M., Buhl Jr, M. L. 2007. Loads analysis of a floating offshore wind turbine using fully coupled simulation. In Wind Power Conference and Exhibition, Los Angeles, CA.

Jonkman, J. M., Matha, D. 2011. Dynamics of offshore floating wind turbinesâ€”analysis of three concepts. Wind Energy, 14(4), 557-569.

Justino, P.P., de O. Falcão, A.F. 1999. Rotational Speed Control of an OWC Wave Power Plant. ASME. Journal of Offshore Mechanics and Arctic Enineering. 1999;121(2):65-70. doi:10.1115/1.2830079.

Kanade, N., Joshi, A., Sudhakar. K. 2008. Multivariable Control Strategy for Large Scale Wind Turbine. (2008). XXXII National Systems Conference. Department of Electrical Engineering & Systems Society of India Dec. 17- 19, 2008.

Kivikunnas, S. 1998. Overview of process trend analysis methods and applications. In ERUDIT Workshop on Applications in Pulp and Paper Industry (pp. 395-408).

Kofoed, J. P., Frigaard, P., Friis-Madsen, E., Sørensen, H. C. 2006. Prototype testing of the wave energy converter wave dragon. Renewable energy, 31(2), 181-189.

Kristiansen, E., Hjulstad, Å., & Egeland, O. 2005. State-space representation of radiation forces in time-domain vessel models. Ocean Engineering, 32(17), 2195-2216.

Lackner, M., Rotea. M. 2011. Structural control of floating wind turbines. Mechatronics 21 (2011) 704-719.

Legaz, R. 2013. Situación y perspectivas de las energias marinas en España. Jornada sobre Proyectos y Tecnologías de Captación de Energía Marina y Off-shore. 16 de Enero de 2013.

López, A., Andres Somolinos, J., & Ramon Nunez, L. 2014. Energetic modelling of primary converters for marine renewable energies. Revista Iberoamericana de Automatica e Informatica Industrial, 11(2), 224-235.

Luo, N., Bottasso, C.L., Karimi, H.R., Zapateiro, M. Semiactive Control for Floating Offshore Wind Turbines Subject to Aero-hydro Dynamic Loads. International Conference on Renewable Energies and Power Quality (ICREPQ’11) Las Palmas de Gran Canaria (Spain), 13th to 15th April, 2011

May, A., McMillan, D., & Thöns, S. 2015. Economic analysis of condition monitoring systems for offshore wind turbine sub-systems. Renewable Power Generation, IET, 9(8), 900-907.

Mehlum, E. 1986. Tapchan. In Hydrodynamics of Ocean Wave-Energy Utilization (pp. 51-55). Springer Berlin Heidelberg.

Musial, W., Jonkman, J., Sclavounos, P., & Wayman, L. 2007. Engineering challenges for floating offshore wind turbines. Golden Colorado: National Renewable Energy Laboratory.

Namik, H., Stol, K. 2010. Individual blade pitch control of floating offshore wind turbines." Wind Energy 13.1 (2010): 74-85.

Namik, H., & Stol, K. J. 2014. Individual blade pitch control of a spar-buoy floating wind turbine. Control Systems Technology, IEEE Transactions on, 22(1), 214-223.

Nasa Standard. Trend analysis techniques, 1988. NASA Data Systems/Trend Analisys Division. Office of the Associate Administrator for Safety, Reliability, Maintainability and Quality Assurance

Nielsen, F.G., Hanson, T. D., Skaare, B. 2006a. Integrated Dynamic Analysis of Floating Offshore Wind Turbines. OMAE 2006, Hamburg, Germany.

Nielsen, F.G., Hanson, T. D., Skaare, B. 2006b. Integrated Dynamic Analysis of Floating Offshore Wind Turbines. EWEC 2006, Athens, Greece.

Ocean Energy Conversion in Europe. Recent advancements and prospects. 2006. Published in the framework of the “Co-ordinated Action on Ocean Energy” (http://www.ca-oe.org) EU project under FP6 Priority: 6.1.3.2.3; Renewable Energy Technologies.

de O Falcão, A. F. 2002. Control of an oscillating-water-column wave power plant for maximum energy production. Applied Ocean Research, 24(2), 73-82.

de O Falcão, A. F., Rodrigues, R. J. A. 2002. Stochastic modelling of OWC wave power plant performance. Applied Ocean Research, 24(2), 59-71.

Ormaza, M. A. 2012. La energía renovable procedente de las olas. Ikastorratza, e-Revista de didáctica, (8), 1-14.

Panicker, N.N., 1976. Power Resource Potential of Ocean Surface Waves”, pp J1-J48, Proceedings of the Wave and Salinity Gradient Workshop, Newark, Delaware, USA.

Pontes, M.T., Falcão, A. 2001. Ocean Energies: Resources and Utilisation. 18th World Energy Council Congress, Buenos Aires, October.

Raisutis R., Jasiuniene E, Sliteris R, Vladisauskas A. 2008. The review of nondestructive testing techniques suitable for inspection of the wind turbines blades. Ultragarsas (Ultrasound) 2008;63(1):26-30.

Retzler, C. 2006. Measurements of the slow drift dynamics of a model Pelamis wave energy converter. Renewable Energy, 31(2), 257-269.

Rocha, R., Martins Filho L.S., Bortolus, M. V. 2005. Optimal Multivariable Control for Wind Energy Conversion System - A comparison between H2 and Hâˆž controllers” Proceedings of the 44th IEEE Conference on Decision and Control, and the European Control Conference 2005 Seville, Spain, December 12-15, 2005

Sarmento, A. J. N. A., Gato, L. M. C., Falcão, A. D. O. 1990. Turbinecontrolled wave energy absorption by oscillating water column devices. Ocean Engineering, 17(5), 481-497.

Seymour, R. J. (Ed.). 1992. Ocean energy recovery: the state of the art. ASCE Publications.

Sturm, A., Billhardt, S. 1992. Envelope curve analysis of machines with rolling-element bearings. PERGAMON PRESS INC, TARRYTOWN, NY(USA). 1992.

Suryanarayanan, S., Dixit, A. 2005. Control of large wind turbines: Review and suggested approach to multivariable design, Proc. of the American Control Conference 2005, Portland, USA, pp. 686-690.

Tandon N, Yadava GS, Ramakrishna KM. 2007. A comparison of some condition monitoring techniques for the detection of defect in induction motor ball bearings. Mechanical Systems and Signal Processing 2007;21(1):244-256.

Thorpe, T.W. 1992. A Review of Wave Energy. ETSU Report R-72, Harwell, Oxfordshire, UK.

Thorpe, T.W. 1998. 2001. An Overview of Wave Energy Technologies. ETSU. WEC (World Energy Council), Survey of Energy Resources, 19th Edition, London, England.

Valera-García, J. J. and Atutxa-Lekue, I. 2016. Sistemas Integrados de Potencia en Buques Offshore: Control, tendencias y retos. Revista Iberoamericana de Automática e Informática Industrial RIAI, 13(1), 3-14.

Washio, Y., Osawa, H., Nagata, Y., Fujii, F., Furuyama, H., & Fujita, T. 2000. The offshore floating type wave power device" Mighty Whale": open sea tests. In The Tenth International Offshore and Polar Engineering Conference. International Society of Offshore and Polar Engineers.

www.bkvibro.com/en/download/uptime-magazine.html. Uptime megazine 2007-2008.

www.statoil.com/en/TechnologyInnovation/NewEnergy/RenewablePowerPrd uction/Offshore/Hywind/Pages/

www.wisions.net/files/uploads/Aquaret_Race_Rocks.pdf

www.textoscientificos.com/energia/dispositivos-generacion-energia-olas