The objective of this project is to develop, design, build, test, optimize and commission FPPs first full-scale wave PTO system. The resulting PTO design will be used to build four identical PTO units
The goal of the project is to develop a barge to jack-up vessel loading technology, which can operate in wavw height of 2.5 m, and that will increase the operation window significantly.
The first purpose is to optimize and demonstrate Exowave wave energy concept in a coastal offshore environment, where the produced seawater under high pressure is led ashore and converted to fresh
WindCal2.0 will develop and demonstrate a nacelle-mounted lidar calibration method where highly accurate lidars replace cup anemometers as the calibration reference and robots automate and speed up
The project develops a drone inspection solution and digital documentation that recognize and categorize surface errors and measure parts of industrial structures with high precision.
An increasing number of wind turbines are reaching end of life and will soon have to be decommissioned. However, wind turbine blades (WTBs) made of glass fiber reinforced thermoset composites are not
The objective is to ensure future large-scale nacelle test facilities are technical and economically feasible for the wind industry. This will be done by further developing and demonstrating R&D Test
The Ocean Energy Systems (OES) Task 10, Part II continues the work on verification and validation of numerical models of Wave Energy Converters (WECs) previously supported by EUDPJ.nr. 64017-05197.
The project partners aim to develop and demonstrate a subsea robot, ACOMAR - Auto COmpact MArine growth Remover, which increases atomization of the marine growth removal process on offshore structures
The project purpose is to deliver easily accessible metocean siting data for design and planning anywhere offshore. Through a scalable quality/cost structure ranging from free general data analytics