Soluciones innovadoras de energía marinaCombinando columnas de agua oscilante y turbinas eólicas flotantes para una mayor eficiencia
- Aboutalebi, Payam 1
- M'zoughi, Fares 1
- Ahmad, Irfan 1
- Bagheri Rouch, Tahereh 1
- Garrido, Izaskun 1
- Garrido, Aitor J. 1
- 1 Universidad del País Vasco (UPV/EHU)
- Cruz Martín, Ana María (coord.)
- Arévalo Espejo, V. (coord.)
- Fernández Lozano, Juan Jesús (coord.)
ISSN: 3045-4093
Año de publicación: 2024
Número: 45
Tipo: Artículo
Resumen
This research investigates the incorporation of Oscillating Water Columns (OWCs) into Semi-Submersible Floating WindTurbines (FWTs) to improve offshore energy extraction. The goal of combining OWCs with FWTs is to reduce the oscillatory motions caused by waves and wind, thus enhancing system efficiency and extending operational lifespan. The study involves redesigning the existing FWT platform, known as WINDMOOR, to integrate OWCs into two of its three columns, specifically for a 12 MW FWT system. The redesign process prioritizes hydrostatic stability and hydrodynamic performance to support the additional OWC elements. Hydrodynamic analyses are performed to assess the hybrid platform’s performance relative to the original design, focusing on the reduction of oscillatory motions. The results highlight the potential benefits of integrating OWCs within FWT systems, particularly in terms of improving power generation efficiency and structural resilience. This research advances offshore energy harvesting technologies by offering insights into the feasibility and effectiveness of hybrid systems for sustainable offshore renewable energy production.
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