The Knowledge Base provides access to information about technical and engineering aspects of marine energy. Relevant documents from around the world are compiled into a user-friendly table that displays all content available in Tethys Engineering. Results can be narrowed using the keyword filters on the right, or with search terms entered in the text box, including targeted searches (e.g., org:DOE, author:polagye). Content may also be sorted alphabetically by clicking on column headers. Some entries will appear on the next page.
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Title | Author | Date Sort descending | Content type | Technology | Collection Method | Engineering |
---|---|---|---|---|---|---|
Optimization of Wave Energy Absorber of an Attenuator OWC Device with an Air Turbine | Maeda, H.; Kinoshita, T.; Kudo, K.; et al. | Book Chapter | Wave, Oscillating Water Column | Modeling | Hybrid Devices, Structural | |
A Study On a Wave And Wind Energy Hybrid Conversion System - Part I: Output Characteristics of a Wave Energy Convertor Using a Ball Screw | Kojima, N.; Ohmata, K.; Abe, T. | Conference Paper | Wave | Lab Data, Scale Device | Hybrid Devices, Structural | |
A Study of a Wave And Wind Energy Hybrid Conversion System-Part 2: Output Characteristics of the Double Type Wave Energy Converter | Matsuoka, T.; Ohmata, K.; Mizutani, T.; et al. | Conference Paper | Wave | Lab Data, Scale Device | Hybrid Devices, Structural | |
Simulation of electricity supply of an Atlantic island by offshore wind turbines and wave energy converters associated with a medium scale local energy storage | Babarit, A.; Ahmed, H.; Clément, A.; et al. | Journal Article | Wave | Modeling | Grid Integration, Hybrid Devices | |
Large-scale integration of optimal combinations of PV, wind and wave power into the electricity supply | Lund, H. | Journal Article | Wave | Modeling | Hybrid Devices | |
Power output variations of co-located offshore wind turbines and wave energy converters in California | Stoutenurg, E.; Jenkins, N.; Jacobson, M. | Journal Article | Wave | Modeling | Hybrid Devices | |
Modeling of an Oscillating Water Column on the Floating Foundation WindFloat | Aubault, A.; Alves, M.; Sarmento, A.; et al. | Conference Paper | Wave, Oscillating Water Column | Modeling | Hybrid Devices | |
Design of a Point Absorber Inside the WindFloat Structure | Peiffer, A.; Roddier, D.; Aubault, A. | Conference Paper | Wave, Point Absorber | Modeling | Hybrid Devices | |
Co-located wave and offshore wind farms: a preliminary case study of an hybrid array | Pérez-Collazo, C.; Astariz, S.; Abanades, J.; et al. | Journal Article | Wave, Overtopping | Modeling | Hybrid Devices | |
Wave energy extraction by coupled resonant absorbers | Evans, D.; Porter, R. | Journal Article | Wave, Point Absorber, Oscillating Water Column | Modeling | Hybrid Devices, Performance | |
WindWaveFloat (WWF): Final Scientific Report | Weinstein, A.; Roddier, D.; Banister, K. | Report | Wave, Point Absorber, Oscillating Water Column, Oscillating Wave Surge Converter | Lab Data, Modeling, Scale Device | Hybrid Devices | |
Modelling the economic impacts of 500 MW of wave power in Ireland | Deane, J.; Dalton, G.; Gallachóir, B. | Journal Article | Wave | Modeling | Hybrid Devices | |
Numerical Assessment of the Mean Power Production of a Combined Wind and Wave Energy Platform | Soulard, T.; Babarit, A. | Conference Paper | Wave, Oscillating Wave Surge Converter | Modeling | Hybrid Devices | |
Use of a Wave Energy Converter as a Motion Suppression Device for Floating Wind Turbines | Borg, M.; Collu, M.; Brennan, F. | Journal Article | Wave | Modeling | Hybrid Devices | |
Extreme responses of a combined spar-type floating wind turbine and floating wave energy converter (STC) system with survival modes | Muliawan, M.; Karimirad, M.; Gao, Z.; et al. | Journal Article | Wave | Modeling | Hybrid Devices | |
Review of software tools for hybrid renewable energy systems | Sinha, S.; Chandel, S. | Journal Article | Current, Wave | Modeling | Hybrid Devices | |
Feasibility of Combined Wind-Wave Energy Platforms | O'Sullivan, K. | Thesis | Wave, Oscillating Water Column | Lab Data, Modeling | Hybrid Devices | |
Application of the Aero-Hydro-Elastic Model, HAWC2-WAMIT, to Offshore Data from Floating Power Plants Hybrid Wind- and Wave-Energy Test Platform, P37 | Bellew, S.; Yde, A.; Verelst, D. | Conference Paper | Wave, Oscillating Water Column | Field Data, Modeling, Scale Device | Hybrid Devices | |
Integration of wind-power and wave-power generation systems using a DC micro grid | Lu, S.; Wang, L.; Lo, T. | Conference Paper | Wave | Lab Data | Grid Integration, Hybrid Devices | |
A Hybrid Wave-Wind Offshore Farm for an Island | Veigas, M.; Iglesias, G. | Journal Article | Wave | Modeling | Hybrid Devices | |
Co-located wind-wave farm synergies (Operation & Maintenance): A case study | Astariz, S.; Pérez-Collazo, C.; Abanades, J.; et al. | Journal Article | Wave | Modeling | Hybrid Devices | |
Improving wind farm accessibility for operation & maintenance through a co-located wave farm: Influence of layout and wave climate | Astariz, S.; Abanades, J.; Pérez-Collazo, C.; et al. | Journal Article | Wave | Modeling | Hybrid Devices | |
Towards the optimal design of a co-located wind-wave farm | Astariz, S.; Pérez-Collazo, C.; Abanades, J.; et al. | Journal Article | Wave | Modeling | Hybrid Devices, Hydrodynamics | |
Combining wave energy with wind and solar: Short-term forecasting | Reikard, G.; Robertson, B.; Bidlot, J. | Journal Article | Wave | Modeling | Hybrid Devices | |
Experimental and numerical study of hydrodynamic responses of a combined wind and wave energy converter concept in survival modes | Wan, L.; Gao, Z.; Moan, T. | Journal Article | Wave | Lab Data, Scale Device | Hybrid Devices | |
Evaluation of the WEC sub-system of a hybrid wind-wave energy converter | Pérez-Collazo, C. | Thesis | Wave | Modeling | Hybrid Devices | |
Co-located wave-wind farms: Economic assessment as a function of layout | Astariz, S.; Pérez-Collazo, C.; Abanades, J.; et al. | Journal Article | Wave | Modeling | Hybrid Devices | |
Accessibility for operation and maintenance tasks in co-located wind and wave energy farms with non-uniformly distributed arrays | Astariz, S.; Iglesias, G. | Journal Article | Wave | Modeling | Hybrid Devices | |
Comparative experimental study of the survivability of a combined wind and wave energy converter in two testing facilities | Wan, L.; Gao, Z.; Moan, T.; et al. | Journal Article | Wave | Lab Data, Modeling, Scale Device | Hybrid Devices | |
Enhancing marine energy competitiveness: Economic assessment of a co-located wave-wind energy farm | Astariz, S.; Iglesias, G. | Conference Paper | Wave | Modeling | Hybrid Devices | |
Comparative numerical and experimental study of two combined wind and wave energy concepts | Gao, Z.; Moan, T.; Wan, L.; et al. | Journal Article | Wave, Oscillating Water Column | Modeling, Scale Device | Hybrid Devices, Power Take Off | |
Numerical and Experimental Study of a Multi-Use Platform | Armesto, J.; Sarmiento, J.; Ayllón, V.; et al. | Conference Paper | Wave | Lab Data, Modeling | Hybrid Devices | |
Experimental study of the functionality of a semisubmersible wind turbine combined with flap-type Wave Energy Converters | Michailides, C.; Gao, Z.; Moan, T. | Journal Article | Wave | Lab Data | Hybrid Devices, Power Take Off | |
Experimental and numerical comparisons of hydrodynamic responses for a combined wind and wave energy converter concept under operational conditions | Wan, L.; Gao, Z.; Moan, T.; et al. | Journal Article | Wave, Point Absorber | Modeling | Hybrid Devices, Hydrodynamics, Power Take Off | |
Design and control of a point absorber wave energy converter with an open loop hydraulic transmission | Fan, Y.; Mu, A.; Ma, T. | Journal Article | Wave, Point Absorber | Modeling | Control, Hybrid Devices | |
Selecting optimum locations for co-located wave and wind energy farms. Part II: A case study | Astariz, S.; Iglesias, G. | Journal Article | Wave | Modeling | Hybrid Devices | |
Hybrid wave and offshore wind farms: A comparative case study of co-located layouts | Astariz, S.; Pérez-Collazo, C.; Abanades, J.; et al. | Journal Article | Wave | Modeling | Hybrid Devices, Hydrodynamics | |
Co-located wind and wave energy farms: Uniformly distributed arrays | Astariz, S.; Iglesias, G. | Journal Article | Wave | Modeling | Hybrid Devices | |
Wave Dragon - 'Coldward and Stormward' | Russell, I.; Friis-Madsen, E.; Sorensen, H. | Book Chapter | Wave, Overtopping | Modeling | Hybrid Devices | |
WindWEC: Combining wind and wave energy inspired by hywind and wavestar | Karimirad, M.; Koushan, K. | Conference Paper | Wave, Point Absorber | Modeling | Hybrid Devices, Power Take Off | |
Assessing the European offshore wind and wave energy resource for combined exploitation | Kalogeri, C.; Galanis, G.; Spyrou, C.; et al. | Journal Article | Wave | Modeling | Hybrid Devices | |
A combined wind and wave energy-converter concept in survival mode: Numerical and experimental study in regular waves with a focus on water entry and exit | Wan, L.; Greco, M.; Lugni, C.; et al. | Journal Article | Wave, Oscillating Water Column | Modeling | Hybrid Devices, Hydrodynamics, Performance | |
Wave- and Wind-induced Responses of the Semisubmersible Wind Energy and Flap-type Wave Energy Converter Based on Experiments | Michailides, C.; Gao, Z.; Moan, T. | Journal Article | Wave, Oscillating Wave Surge Converter | Lab Data | Hybrid Devices, Hydrodynamics | |
GIS-based multi-criteria decision analysis for site selection of hybrid offshore wind and wave energy systems in Greece | Vasileiou, M.; Loukogeorgaki, E.; Vagiona, D. | Journal Article | Wave | Modeling | Hybrid Devices | |
Design and simulation of multi-energy hybrid power system based on wave and wind energy | Chen, M.; Huang, L.; Yang, J. ; et al. | Conference Paper | Wave | Modeling | Hybrid Devices | |
Dynamic response and power production of a floating integrated wind, wave and tidal energy system | Li, L.; Gao, Y.; Yuan, Z.; et al. | Journal Article | Current, Tidal, Wave, Point Absorber | Modeling | Hybrid Devices, Performance | |
Performance Analysis of Multiple Wave Energy Converters Placed on a Floating Platform in the Frequency Domain | Lee, H.; Poguluri, S.; Bae, Y. | Journal Article | Wave, Point Absorber | Modeling | Hybrid Devices, Performance, Power Take Off, Structural | |
Performance assessment of the CECO wave energy converter: Water depth influence | Ramos, V.; Lopez, M.; Taveira-Pinto, F.; et al. | Journal Article | Wave, Point Absorber | Modeling | Hybrid Devices, Performance | |
Efficient determination of the long-term extreme responses by the modified environmental contour method for a combined wind turbine and wave energy converter system | Li, Q.; Ren, N.; Gao, Z.; et al. | Journal Article | Wave | Modeling | Hybrid Devices, Performance | |
Experimental and numerical study of hydrodynamic responses of a new combined monopile wind turbine and a heave-type wave energy converter under typical operational conditions | Ren, N.; Ma, Z.; Fan, T.; et al. | Journal Article | Wave | Lab Data, Modeling, Scale Device | Hybrid Devices, Hydrodynamics |
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