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Passive flow control mechanisms with bioinspired flexible blades in cross-flow tidal turbines

Stefan Hoerner, Shokoofeh Abbaszadeh, Olivier Cleynen, Cyrille Bonamy, Thierry Maı̂tre, Dominique Thévenin

2021Experiments in Fluids26 citationsDOIOpen Access PDF

Abstract

Abstract State-of-the-art technologies for wind and tidal energy exploitation focus mostly on axial turbines. However, cross-flow hydrokinetic tidal turbines possess interesting features, such as higher area-based power density in array installations and shallow water, as well as a generally simpler design. Up to now, the highly unsteady flow conditions and cyclic blade stall have hindered deployment at large scales because of the resulting low single-turbine efficiency and fatigue failure challenges. Concepts exist which overcome these drawbacks by actively controlling the flow, at the cost of increased mechatronical complexity. Here, we propose a bioinspired approach with hyperflexible turbine blades. The rotor naturally adapts to the flow through deformation, reducing flow separation and stall in a passive manner. This results in higher efficiency and increased turbine lifetime through decreased structural loads, without compromising on the simplicity of the design. Graphic abstract

Topics & Concepts

Stall (fluid mechanics)TurbineTidal powerWind powerMarine engineeringFlow (mathematics)Computer scienceRotor (electric)TurbomachineryTurbine bladeFlow control (data)Software deploymentEnvironmental scienceAerospace engineeringMechanical engineeringGeologyMechanicsEngineeringPhysicsElectrical engineeringComputer networkOperating systemWind Energy Research and DevelopmentBiomimetic flight and propulsion mechanismsAerospace Engineering and Energy Systems