Blade dynamics and ETI Very Long Blade Project moves forward with Siemens Wind Power
17 December 2013
17th December 2013
Blade Dynamics and ETI Very Long Blade Project moves forward with Siemens Wind Power
Blade Dynamics has announced that the design phase of their ‘Very Long Blade Project’ for the Energy Technologies Institute (ETI) has successfully concluded and that the prototyping phase will now begin.
Blade Dynamics will now assemble an approximately 80-metre long blade prototype, and will begin static and fatigue tests before the end of 2014.
Siemens Wind Power has confirmed its continued support to the development of this advanced rotor technology. This ETI commissioned and funded project is the first application of Blade Dynamics’ innovative technology for large offshore blades, with a rotor designed specifically for the Siemens SWT-6.0 turbine.
Henrik Stiesdal, Chief Technology Officer of Siemens Wind Power said: "We are pleased to confirm our ongoing collaboration with the ETI and Blade Dynamics in this interesting project. After this next phase of further prototype testing, we will consider demonstration of a full rotor on a 6.0 MW turbine.
“Subject to successful conclusion of the tests it is clear that the potentials of the split-blade technology of Blade Dynamics would be expected to become even more interesting as we move to even larger turbine platforms.”
Andrew Scott, Programme Manager for Offshore Wind at the ETI added: "The ETI’s vision is to support the development of next-generation blade technology because improved rotor performance is fundamental to achieving the goal of reducing the cost of offshore wind energy. We greatly appreciate the ongoing commitment of Siemens to this project with Blade Dynamics.
“As leaders in this field, this partnership for the development of next-generation rotor technology has the potential to have a huge impact on the cost of offshore wind energy in the future”.
The £15.5m project was launched in January 2013 and the Blade Dynamics technology will demonstrate blades that are both longer and lighter than those made from conventional glass fibre.