Sustainable Marine has recorded the first major milestone in the Canadian-German EvoFoil Project after completing extreme load testing on a new 4.3m tidal turbine foil (blade).
The marine solutions provider is leading the EvoFoil Project in partnership with German organizations M&D Composites Technology and Leibniz Universität Hannover Institute of Production Engineering and Machine Tools.
It aims to deliver a series of design innovations to optimize the performance of tidal turbine foils while driving down production and operation costs.
In latest developments, Sustainable Marine’s new 4.3m foil underwent a comprehensive ‘static-bending test campaign’ to demonstrate its future durability within some of the most challenging tidal environments on earth.
The new foil has been specifically designed to withstand conditions in the Bay of Fundy’s Minas Passage, located in Nova Scotia, Canada. The site will play host to the firm’s Pempa’q Project to showcase the world’s first floating tidal energy array.
Results show continued evolution with a 7pc energy yield increase, compared to previous 4m rotors designs.
“Successful extreme load testing marks an important milestone demonstrating the reliability of our new foil design, which is a key factor in tidal turbine development,” said Ralf Starzmann, Head of Power Systems at Sustainable Marine. “Working closely with our partners, we developed a tailor-made test rig to meet the requirements of our new 4.3m foil and prove it can manage loads up to 3.8t (equivalent to four old VW Beetles). This verifies the short-term strength of the new foil design against the extreme loads it will experience at the FORCE (Fundy Ocean Research Centre for Energy) test site in the Minas Passage, where our tidal platform will soon be located.”
Testing took place at M&D Composites’ facilities in Friedeburg, Germany, enabling direct feedback to the production team. The tests also proved the passive-adaptive pitch properties of the new design – increasing energy generating potential.
“The EvoFoil Project involves an extensive field and lab testing campaign, to integrate Sustainable Marine’s foil design, including the tip geometry and the overall composition,” said M&D Composites Technology Managing Director Tim Markwald. “A key focus for M&D Composites involves optimizing the manufacturing process of the turbine foils and designing a novel generation of tools to reduce fabrication time and costs. By increasing the energy yield and reducing production costs we can help scale down the overall cost of energy.”
“During the latest lab test campaign, we also monitored foil deformation and fibre strains,” said Carsten Schmidt Leibniz Universität Hannover Head of Research Group High Performance Production of CFRP-Structures. “This is helping to inform broader work to develop a new ‘multi-layer’ material which will improve the mechanical behaviour of the foil and help counteract the various loads. We introduced a novel fibre-optic strain measuring system to improve the monitoring process, providing strain information with a very high spatial and temporal resolution all across the foils surface. We now have unique data which will be used to further improve the design concept.”
Sustainable Marine is receiving advisory services and up to $578,244 in research and development funding from the National Research Council of Canada Industrial Research Assistance Program (NRC IRAP) for the two-year project.
Additionally, the German partners on this project are receiving funding support from the German Federal Ministry for Economic Affairs and Energy (BMWi) through the Central Innovation Programme for SMEs (ZIM).
Sustainable Marine is an innovative solutions provider empowering the development of a sustainable blue economy. The company has developed several pioneering products, including PLAT-I, a floating tidal energy platform that delivers predictable and clean energy to coastal communities.
It also offers a range of unique anchoring solutions, which are delivered by the specialist Swift Anchors team, that provide rapid, secure, and precise mooring, or fixation, of support structures for renewable energy systems, and other infrastructure in high energy marine environments with challenging geotechnical conditions.
Through a talented team of engineers and innovators operating from the United Kingdom, Germany, Portugal, and Canada, Sustainable Marine provides turnkey project management with world-class expertise in naval architecture, site assessment and selection, front-end engineering and design, mooring and station-keeping, floating structure design and construction, hydrokinetic power systems, and the development of logistics, installation, operational, environmental monitoring and performance monitoring solutions. To learn more visit www.sustainablemarine.com