Project

The purpose of the project is to develop a gyroelectric energy conversion unit for wave energy. In order to demonstrate the technology under realistic conditions, a series of experimental tests will be carried out at the Nissum Bredning Test Station on a 5 kW unit.
The following main activities will be held:
Continuation of wave basin tests on an existing prototype at AAU. Including determination of the absorbed power at different standard sea conditions. Tests with irregular waves to optimize energy absorption under realistic conditions.
Design and manufacture of a 5 kW PTO unit. In the design and in the choice of manufacturing methods, emphasis will be placed on using standard components and manufacturing methods that can also be used in a possible production of a full-scale PTO unit (15, 30 and 50 kW).
Testing and demonstration of a 5 kW PTO unit at the Nissum Bredning Test Station. Over a period of approx. 10 months from August 2015 to June 2016, a series of tests will be carried out with the PTO unit mounted to the test station platform approx. 140 m from shore.
Preparation of a measurement program data processing for the tests at AAU, as well as the testing at Nissum Bredning.
Contact with wave power developers. In the final part of the project, a number of Danish and foreign wave power developers will be contacted with a view to starting an end-user dialogue with 2-3 wave power developers.

The Danish wave energy sector consists of several large floating and loosely anchored wave power plants. These plants require specially designed anchoring systems, as “standard” solutions (largely coming from the offshore oil and gas industry) are not designed for the conditions and specifications applicable to wave power plants. For these wave power plants, it is necessary to reduce the resulting anchoring and structural loads, which can be done by making the anchoring solutions more compliant. This will reduce the costs of the anchoring solution and the structure of the plant and thereby the overall costs of the plant and its produced energy, while making the systems more reliable.

The four plants selected to be part of this project are all at a stage of development where they have either completed, or are about to complete, testing of the plants at sea. The four plants are Floating Power Plant, Wave Dragon, Weptos and Leancon. They all require comparable anchoring solutions, as the plants are large, floating, loosely anchored structures operating in water depths of around 30 – 100 m at full commercial scale. This project investigates and compares different anchoring solutions that are useful for these wave power plants. The anchoring solutions are assessed step by step, in order to carry out a systematic and thorough evaluation. The project is organised in the following work packages:

- WP 1: Design practices and tools.
- WP 2: Anchoring solutions.
- WP 3: Preliminary design.
- WP 4: Full analysis.
- WP 5: Cost evaluation.
- WP 6: Selection and results.
- WP 7: Dissemination and project management.

Throughout the project, reports will be produced presenting the results of the selected studies and milestones according to the project Gantt chart. Each of them is crucial for the next step of the analysis and will thus be of great importance. The final results of this project are numerous. It will provide experience and insight into the development of anchoring solutions for all project partners. Furthermore, it will provide the developers with detailed analyses of the various anchoring solutions, and evaluate their prices and practical applicability. Aalborg University will build up experience and know-how in the field, which will enable them, and/or a possible spin-off company, to offer design services in the field to companies in the future. It is also expected to be significant cost and reliability benefits, in addition to having an effective anchoring solution, for the partner plants.

The purpose of this proof of concept project is to further investigate the WaveSpring technology and how it can benefit wave energy plants. The results from the project will increase the efficiency of wave energy plants and reduce the price of the energy produced from the plants.

The long-term goals of this task are:
1. To assess the accuracy and establish confidence in the use of numerical WEC models
2. To determine a range of validity of existing computational modeling tools
3. To identify uncertainty related to simulation methodologies in order to:
a. Reduce risk in technology development
b. Improve WEC energy capture estimates
c. Improve loading estimates
d. Reduce uncertainty in LCOE models
4. To define future research and develop methods of verifying and validating the different types of numerical models required depending on the conditions

Description
100 kW EXOWAVE wave energy testing in Hanstholm.

Key results
• Design, build and demonstrate an Exowave wave energy converter (WEC) block at a 14-meter water depth in the Danish North Sea in conjunction with a hydro turbine driven electrical generator connected to the grid. The power generation would be +100 kW.
• Include learnings from EUDP1: numerical model verified by tank test (AAU) and CFD analysis (Delft University), feasibility study: wind and wave plant in very large scale, WEC detailed design and engineering, FAT and demonstration at DanWEC site.
• Assess the environmental impact and improve animal life by shaping the WEC foundation for fish breeding grounds.
• Life cycle analysis and include eco-friendly materials as waste materials from wind turbine blade waste materials.
• Assess supply chain in the North Sea region with special focus in Denmark and its raw material, production facilities, knowledge provider for fulfilling the aim above LOI target and support the Danish national energy target in 2030 and 2050. And to include the results in the design phase. The overall KPI here is to lower LCOE.
• TRL improve from 6 to 7

This project aims at designing mooring system for floating wave energy converters (WECs) using a design approach based on numerical uncertainty quantification to estimate loads to a given tolerance level. This approach is to be compared to traditional deterministic approach with safety factors in terms of cost of the designed system. This is to be achieved by: (i) using an uncertainty quantification (UQ) toolbox based on general polynomial chaos (gPC) into a state-of-the-art mooring dynamics solver; (ii) to perform detailed numerical investigation on the influence on snap-loads on the mooring design. All parts aim at providing a base for lowering the economic cost of the mooring system.

The general aim of the PhD project is to develop and evaluate innovative methods for mitigation of flooding and coastal erosion hazard in the context of increasing storminess and sea level rise. The PhD project will be related mainly to experimental testing of various innovative methods for improving the safety of European coasts in a changing climate. These methods will among others be upgrade of existing defenses (dikes, breakwaters etc.) and reduction of wave energy at the coasts by utilization of wave energy converters placed near-shore.