David Roger Lande-Sudall
Field of work
David is an Associate Professor in Marine Engineering in the Department of Mechanical and Marine Engineering at the Western Norway University of Applied Sciences (HVL). David also leads the Water, Wind and Waves (W3) research group and is currently Principal Investigator on the RCN-funded FRIPRO project, HYDROMORE – HYDROdynamic Mooring analysis for Ocean Renewable Energy. After completing his PhD in Co-location of Offshore Wind and Tidal Stream Turbines from the University of Manchester, UK, David’s research now focusses on ocean renewable energy devices (offshore wind, tidal stream and wave), with lab-scale testing in MarinLab to validate numerical modelling of hydrodynamic interactions. David teaches on the Marine Technology and Sustainable Energy Technology master’s programmes, in subjects: MAS540 Ocean Renewable Energy, MAS532 Marine Structures, and MAS304 Experimental Methods for Marine Engineers.
- MAS532
- Marine Renewable Energy
- Offshore Wind Turbines
- Tidal Stream Turbines
- Wave energy
- Marine hydrodynamics
Publications
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Grid Turbulence Measurements with an Acoustic Doppler Current Profiler
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Linear modelling of the mass balance and energy demand for a recirculating aquaculture system
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Eksperimentell og numerisk sammenligning av ikke-lineære fokuserte bølger
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Preliminary performance assessment from towing tank testing of a horizontal-axis turbine
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Hydrodynamic modelling of a multi-body wave energy converter using the Moving Frame Method
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A comparison of extreme mooring loads and response of a spar-buoy wind turbine using conditional waves
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Experimental time-domain comparison of a hydrodynamic model for a lightly moored spar buoy wind turbine
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Eksperimentell undersøkelse med modellturbin under konstant slep og bølgebelastning
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Lab-scale measurements of wind farm blockage effects
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Energy Storage and Stabilization Simulation of Floating Wind Turbines
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Wave-induced collision loads and moments between a spar-buoy floating wind turbine and an installation vessel
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Wave-induced collision loads and moments between a spar-buoy floating wind turbine and an installation vessel
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A hydrodynamic model of the M4 wave energy converter using the moving frame method
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A hydrodynamic model of the M4 wave energy converter using the Moving Frame Method
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Bending moments and collision loads between a floating offshore wind turbine and a supporting barge.
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Co-located deployment of offshore wind turbines with tidal stream turbine arrays for improved cost of electricity generation
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Dynamisk analyse og levetidsberegning på utviklingsprosjektet «Havliljen»
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Co-located offshore wind and tidal stream turbines: Assessment of energy yield and loading
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Experimental Study of the Wakes due to Tidal Rotors and a Shared Cylindrical Support
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Energy yield for co-located offshore wind and tidal stream turbines
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Wake characteristics of a scaled tidal rotor with monopile support structure for co-located wind and tidal farms
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Simplified Wake Models for Small Tidal Farms: Reduced Scale Evaluation and Array Loading Study