Flexible Responsive Systems in Wave Energy: FlexWave
Find Similar History 36 Claim Ownership Request Data Change Add FavouriteTitle
CoPED ID
Status
Value
Start Date
End Date
Description
Wave energy convertors (WECs) offer opportunities for niche (powering aquaculture and offshore stations) and grid-scale applications. However, disruptive innovation is essential to unlock the potential of wave energy, achieve step change reduction in cost of energy, and prove competitiveness against other renewable energy options. Here we investigate the opportunity to transform the development of WEC systems by utilising intelligent design concepts that exploit novel use of deformable materials. WECs based on deformable materials may offer improved performance, survivability, reliability, and reduced cost compared with steel or concrete alternatives for the following reasons:
1. To achieve a given resonant frequency, a flexible fabric device can be smaller and lighter.
2. Hydrodynamic characteristics of such a device can be modified by controlling its internal fluid pressure, enabling it to be tuned to suit incident wave conditions. These adjustments can be made by an on-board intelligent responsive system.
3. Controlled non-linear changes of geometry would enable a deformable fabric structure to accommodate or shed high loads without reaching critical stress concentrations, improving survivability and reducing installation and lifetime costs.
4. Flexibility opens up the possibility to use a range of PTOs, such as novel distributed embedded energy converters (DEECs) utilising distributed bellows action, electro active polymers, electric double layer capacitors or micro-hydraulic displacement machines.
5. A lightweight flexible structure with largely elastic polymer construction is unlikely to cause collision damage, and so is therefore a low risk option for niche applications, such as co-location with offshore wind devices.
The performance of flexible responsive systems in wave energy, their optimisation in operating conditions, and their ability to survive storm waves, will be assessed through a programme of wave basin experiments and numerical modelling of different flexible WEC concepts. Survivability is a critical hurdle for all WEC concepts as by their nature they need to respond in energetic sea states while avoiding critical stresses in extreme seas. For a flexible responsive structure, this means avoiding concentration of stress (naturally avoided by collapse/folding) or of strain (avoided by use of a distributed PTO during operational conditions).
Numerical models will be developed that account for complex interactions between wave action, deforming membrane structure, and internal fluid. The models will be informed, calibrated, and validated using results from materials testing and fundamental hydro-elastic experiments. Advantages and disadvantages of rubber-based, polyurethane and other reinforced polymer materials will be assessed in terms of manufacturing cost, join, bonding, and fatigue performance in the marine environment. The research will draw on origami theory and the technology of deployable structures to avoid problems with wrinkling, folding, or aneurysm formation, and an entirely new design may emerge through this innovative approach. We aim to demonstrate a pathway to cost reduction for flexible fabric WECs optimising for performance, structural design and manufacture for both utility scale and niche applications.
Plymouth University | LEAD_ORG |
Single Buoy Mooring Inc | COLLAB_ORG |
Griffon Hoverwork | COLLAB_ORG |
Wave Energy Scotland | COLLAB_ORG |
U.S. Department of Energy | COLLAB_ORG |
Koninklijke Philips Electronics N.V. | COLLAB_ORG |
Offshore Renewable Energy Catapult | COLLAB_ORG |
BP (British Petroleum) | COLLAB_ORG |
LOC Group (London Offshore Consultants) | PP_ORG |
Bombora Wave Power Europe | PP_ORG |
Single Buoy Moorings Inc. | PP_ORG |
Offshore Renewable Energy Catapult | PP_ORG |
BP (United Kingdom) | PP_ORG |
Checkmate Flexible Engineering | PP_ORG |
National Renewable Energy Laboratory | PP_ORG |
Wave Venture Ltd | PP_ORG |
Seawind Ocean Technology Ltd | PP_ORG |
Wave Energy Scotland | PP_ORG |
Griffon Hoverworks Ltd | PP_ORG |
Rod Rainey & Associates | PP_ORG |
Private Address | PP_ORG |
Deborah Greaves | PI_PER |
Maozhou Meng | COI_PER |
Edward Ransley | COI_PER |
Shanshan Cheng | COI_PER |
Martyn Hann | COI_PER |
Siming Zheng | COI_PER |
Subjects by relevance
- Renewable energy sources
- Polymers
- Optimisation
- Costs
- Waves
Extracted key phrases
- Flexible Responsive Systems
- Flexible fabric WECs
- Wave energy convertor
- Flexible responsive structure
- Different flexible WEC concept
- Flexible fabric device
- Lightweight flexible structure
- Wave Energy
- Renewable energy option
- Energy converter
- Deformable fabric structure
- Suit incident wave condition
- Board intelligent responsive system
- Wave basin experiment
- Wave action