Plans for floating wind turbines of Malta coast – Ref: Maritime Journal

Technology presently considered is “Hexicon AB’s concept based around two different types of turbines mounted on a floating, hexagon shaped platform, which uses a specifically designed swivel system to rotate around its own axis and automatically align itself into the wind”.

“[…] Malta’s plans involve a 36 turbine, 54MW, 460m wide Hexicon platform to be located 11 miles off the island’s north east coast in water depths between 100m and 150m. If the application is successful, and EU funding is forthcoming, Hexicon consider the project could be completed by 2014”

Ref: Maritime Journal – Malta’s different approach to offshore wind

Testing Offshore Floating Wind at WaveHub?

Last year, the UK Energy Technology Institute announced plans for a floating wind demonstration project to confirming feasibility and reducing generation cost.

Now the ETI has announced that they are investigating if the test system could be deployed at the WaveHub site in Cornwall. Results should be available “before the summer”.

In their own words, the idea would be to operate the system “for at least two years to show it can generate high levels of electricity, be maintained without using specially designed vessels and to verify the predicted technical and economic performance”.

Design, construction and installation should be completed by 2016.

References:
http://www.eti.co.uk/news/article/eti_to_explore_testing_offshore_floating_wind_platform_at_wave_hub
http://www.eti.co.uk/news/article/investment_in_offshore_wind_opportunities

Bureau Veritas issues guidance for Floating Offshore Wind Turbines

Issued on 12th January 2011

<Leading international classification society Bureau Veritas has issued guidelines for the Classification and Certification of Floating Offshore Wind Turbines. The guidelines specify the environmental conditions under which floating offshore wind turbines may serve, the principles of structural design, load cases for the platform and mooring system, stability and the structural division and design criteria for the top structure. The Guidance Note NI 572 covers floating platforms supporting single- or multiple-turbines with horizontal or vertical axes.
Maxime Pachot, Offshore Wind Turbine Manager, Bureau Veritas, says, "There is growing demand for offshore wind turbines which can be safely installed in very deep water locations. They will use one or more types of floating platform to mount the turbine and may need a service life equivalent to offshore oil and gas projects. Both operators and authorities need to know these platforms are safe and will be up to the job. Although this is a new way of generating energy out at sea, it builds on proven technology and experience in offshore energy. These guidelines bring together Bureau Veritas’ experience with and rules for offshore floating units and moorings and marries them with the internationally accepted standards for wind turbines set out in IEC 61400-3: Wind turbines – Design requirements for offshore wind turbines. They will help field developers choose the right system and the right pathway for approval to meet local and international regulations and their own industrial requirements."
Three categories of floating platforms are covered: Ballast floating platforms that achieve stability by using ballast weights placed below a global buoyancy centre; Tension Leg Platforms (TLP), that achieve stability through the use of tendons; and Buoyancy floating platforms, that achieve stability by the use of distributed buoyancy.
The top structure with the rotor-nacelle and tower will be certified in accordance with International Standard IEC 61400-3 and/or national regulations. The floating platform on which the generating assembly is mounted will be classified by Bureau Veritas under its Rules for the Classification of Offshore Units (Offshore Rules), which also extend to cover the mooring system.
In addition to classification and certification of offshore wind projects, Bureau Veritas is able to provide extensive expertise in site analysis, meteo-ocean studies, hydrodynamic simulation and fatigue life planning and on-site inspection and maintenance.
Bureau Veritas is the only classification society partner in the EU HiPRWIND project which brings together 19 companies with the aim of developing enabling technology elements for deep-water offshore wind. It is also involved in certifying wind projects in a number of countries globally and has an extensive wind R&D programme.>

Ref:  Bureau Veritas issues guidance for Floating Offshore Wind Turbines

Research And Investment In Wave Power Strategies – Engineer Live / Process Engineer Magazine

 

Research And Investment In Wave Power Strategies

Areva and Sway Announce Partnership on Deep Water Floating Wind Turbine Solutions | Ocean Power Magazine

Areva and Sway Announce Partnership on Deep Water Floating Wind Turbine Solutions

SWAY

The partnership with AREVA Multibrid AREVA and Sway have recently announced their cooperation in offering new solutions to provide technology that makes it possible to exploit offshore winds in deep water for energy production.

AREVA, via its German subsidiary AREVA Multibrid, is currently delivering turbines to the first German offshore test field Alpha-Ventus.

AREVA-Multibrid was recently awarded a Memorandum of Understanding for delivery of 80 wind turbines to Global Tech 1 wind farm, which is planned outside the coast of Northern Germany with seabed anchored installations.

The Multibrid M5000 turbine has a capacity of 5 MW and is designed solely for offshore installation.

 

Félix Debierre, CEO AREVA Multibrid:

We believe the floating M5000 wind turbine under development with SWAY provides an attractive solution for tomorrow’s deep water offshore projects.

The turbine will be adapted to enable downwind turbine operation on SWAY’s tower solution. This is the first time their turbine is applied on a floating foundation, which has been made possible through SWAY’s technology.

The company’s founder and CEO Eystein Borgen, adds:

Our aim is to demonstrate that deep water wind power is commercially attractive within the next 4 years. The use of AREVA-Multibrid’s technology is essential for our project. The combination makes it possible to produce energy at a commercially attractive price.

Areva SWAY

Full scale test licence in Norway SWAY AS has been granted a license from the Norwegian Water Resources and Energy Directorate for building a floating wind turbine plant for offshore wind power approximately 7 km outside Karmøy on the west coast of Norway. The prototype construction is conditional on financial support from the recently established Norwegian financial support programme for marine renewable energy (Enova). A customer for this project is essential and Sway is ready to start negotiations with possible international or national buyers as soon as possible. When the right customer is found the wind turbine can be up and running in 18-24 months.

The purpose of the project is to test a full-scale SWAY wind power plant and collect sufficient operational experience for both SWAY and the customer for building future floating wind power facilities offshore.

Our ambition is to demonstrate that such plants in a commercial phase shall be able to supply power at a price competitive to shallow water wind parks. SWAY’s floating wind turbines have several advantages which will make this possible.

The test plant The demonstration plant will consist of a Sway floating tower and an AREVA Multibrid wind turbine with a capacity of 5MW. The tower is 188 metre high, whereof 84 metre is above water and 104 metre is under water. Heavy ballast is placed at the bottom of the tower and it is anchored to the seabed with a tension leg and a suction anchor. The tension leg is attached to the tower through a subsea yaw mechanism which enables the wind turbine including tower to revolve with the wind. This will allow using a tension rod system to strengthen the tower, similar to the wire stays on a sailboat, so that a significantly larger turbine can be utilized.. This will increase the production capacity, and thus reduce the power production costs. The technology is suitable and safe for ocean depths between 80 and 400 metres. The wind turbine that is mounted on the top of the tower is placed downwind. This is to allow the floating tower to tilt (6-8 degrees) due to the pressure from the wind, without resulting in a large misalignment between the rotor and the wind. Transformers, switchgear and other electric equipment will be placed in the tower. The plant will be connected to the existing electrical grid onshore through a sea cable.

Offshore wind power has enormous potential All reports indicate an enormous energy potential in offshore wind world wide. A report published in April 2009 by the Department of Interior in the U.S. estimates the recoverable energy potential in offshore wind power in the U.S. to be enough to cover the power consumption of 53 million households (1000-1500TWh).

According to Borgen’

It is maybe neglected by many people that in several areas only deep water locations are available and fixed base installations is no alternative for utilizing this potential”, and in addition we can produce more power from a floating wind turbine located out of sight from shore because normally the wind blows stronger farther offshore. Offshore wind power also entails less conflicts related to use of land, animal and plant life, as well as various opinions related to aesthetics.This does not mean that we want to play down the importance of fishery and ship traffic and we will gain experience on these issues through our demonstration plant. Our ambition is to produce more energy at a lower price, hence making the floating wind turbine an attractive asset for energy producers worldwide.

 

via Areva and Sway Announce Partnership on Deep Water Floating Wind Turbine Solutions | Ocean Power Magazine.