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 | Content type | Technology | Collection Method | Engineering |
---|---|---|---|---|---|---|
Aerodynamic characteristics of airfoils used in high tip-speed-ratio tidal rotors for less energetic flows | Martinez, R.; Encarnacion, J.; Ordonez-Sanchez, S.; et al. | Conference Paper | Current, Tidal | Lab Data, Modeling | Performance, Structural | |
Numerical modelling of rock anchor uplift capacity for offshore applications | Cerfontaine, B.; Brown, M.; Caton, A.; et al. | Conference Paper | Current, Wave | Modeling | Mooring, Substructure | |
Failure and reliability growth in tidal stream turbine deployments | Walker, S.; Thies, P. | Conference Paper | Current, Tidal | Performance | ||
Mooring types of point absorbing wave energy converters | Chatzigiannakou, M.; Temiz, I. | Conference Paper | Wave, Point Absorber | Mooring | ||
Guidelines for Health and Safety in the Marine Energy Industry | RenewableUK | Report | Current, Tidal, Wave | |||
Design and Analysis of a Mooring System for a Wave Energy Converter | Depalo, F.; Wang, S.; Xu, S.; et al. | Journal Article | Wave | Field Data, Lab Data, Modeling, Test Center | Materials, Mooring, Performance, Structural | |
Risk-based Operation and Maintenance Approach for Wave Energy Converters Taking Weather Forecast Uncertainties into Account | Ambühl, S.; Kramer, M.; Sorenson, J. | Conference Paper | Wave | Modeling | ||
Increased reliability of tidal turbines thanks to a better knowledge of realistic tidal conditions, use of RAM analysis, advanced monitoring, maintenance strategies and intelligent design components. | Le Diagon, V.; Mayorga, P.; Sukendro, M.; et al. | Conference Paper | Current, Tidal | Modeling | Control, Performance | |
Wave Farm Design: Simulation of Marine Operations for Improved Cost of Energy | Henry, A.; Giorgi, S.; Kennedy, B.; et al. | Conference Paper | Wave | Modeling | ||
3D Numerical Study of the Impact of Macro-Roughnesses on a Tidal Turbine, on Its Performance and Hydrodynamic Wake | Robin, I.; Bennis, A.; Dauvin, J. | Journal Article | Current, Tidal | Modeling | Performance | |
The marine electrical power industry with the use of renewable energy carriers. Part 2. Axial multipole synchronous generators with permanent magnets for wind and wave offshore power plants | Khrisanov, V.; Dmitriev, B. | Journal Article | Wave | Hybrid Devices, Performance, Substructure | ||
Effects of turbulence on tidal turbines: Implications to performance, blade loads, and condition monitoring | Blackmore, T. ; Myers, L.; Bahaj, A. | Journal Article | Current, Tidal | Lab Data, Modeling, Scale Device | Hydrodynamics, Structural | |
A Decision Support Tool for Long-Term Planning of Marine Operations in Ocean Energy Projects | Fonseca, F.; Amaral, L.; Chainho, P. | Journal Article | Current, Tidal, Wave | |||
Sea Wave Energy. A Review of the Current Technologies and Perspectives | Curto, D.; Franzitta, V.; Guercio, A. | Journal Article | Wave | Performance | ||
The rebirth and eco-friendly energy production of an artificial lake: A case study on the tidal power in South Korea | Park, E.; Lee, T. | Journal Article | Current, Tidal | Lab Data, Modeling | Structural | |
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 | |
Pelamis Mooring and Connections | Quoceant Ltd | Report | Wave | Mooring | ||
Pelamis Power Take Off | Quoceant Ltd | Report | Wave | Test Center | Power Take Off | |
AWS Report on Parametric Cost Modelling | AWS Ocean Energy | Guidance | Wave | Modeling | Materials, Mooring, Power Take Off | |
Technology Description and Status – Self-drilled Pile System | AWS Ocean Energy | Report | Wave | Control, Materials, Mooring | ||
Technology Description and Status – Electric Eel | AWS Ocean Energy | Report | Wave | Control, Materials, Mooring | ||
Technology Description and Status – AWS III | AWS Ocean Energy | Report | Wave | Control, Materials, Mooring, Power Take Off | ||
Technology Description and Status – Waveswing | AWS Ocean Energy | Report | Wave | Control, Materials | ||
AWS Ocean Energy Project Overview | Wave Energy Scotland | Report | Wave | Materials | ||
Maintainability Improvements | Aquamarine Power Ltd | Report | Wave | |||
Offshore Operational Experience | Aquamarine Power Ltd | Report | Wave | Full Scale | ||
Aquamarine Power Ltd Project Overview | Wave Energy Scotland | Report | Wave | Test Center | ||
A Floating Ocean Energy Conversion Device and Numerical Study on Buoy Shape and Performance | Song, R.; Zhang, M.; Qian, X.; et al. | Journal Article | Current, Wave | Modeling | Structural | |
Condition-based maintenance methods for marine renewable energy | Mérigaud, A.; Ringwood, J. | Journal Article | Current, Wave | |||
Wave Energy Technologies for Chile: Critical Analysis | Tampier, G.; Cifuentes, C.; Parra, C. | Report | Wave | |||
Tank Testing of WECs | Aquamarine Power Ltd | Report | Wave | Test Center | ||
An International Evaluation and Guidance Framework for Ocean Energy Technology | Hodges, J.; Henderson, J.; Ruedy, L.; et al. | Report | Current, Tidal, Wave | Control, Performance |
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