Hydrogen is envisioned to become a key enabler and energy carrier in the future 100% renewable energy system with predicted applications within transportation, grid stability, industry, re
The aim of this project is to develop a comprehensive approach, to produce large wind turbine blades fully recyclable and sustainable. To tackle the waste issue of wind turbine blades and
HT-PEMFC with Danish industry in the lead is on the threshold of market entry and consortium partners are committed to establish a production line of cell components at a production rate of 1
Hydrogen is envisioned to become a key energy carrier in the future 100% renewable energy system with predicted applications within transportation, grid stability, industry, re
Floating wind energy is a cornerstone of a carbon-free electricity supply. The Danish offshore wind industry is in a key position to play a leading role in the coming market, which is
Conventional manual manufacturing methods - hand lay-up and vacuum infusion - are to date predominantly used to produce large-scale Continuous Fiber Composite (CFC) structures for industries
The project aims to develop a symbiotic teleoperation solution to the Wind Turbine Blade (WTB) maintenance. The current solution to the WTB maintenance largely relies on human technicians who
The starting point of the project is DTU’s development of a phosphate solid hydrogen ion conducting membrane which is “ionic-protonic-superconducting” in the temperature range 230 – 350 °C
The scope of the project is to recycle high value precious metal catalyst and polymer components from HT-PEMFC MEAs, implement inhouse MEA production using alternative components and test the
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