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The world’s first full-scale floating wind turbine, Hywind, being assembled in the Åmøy Fjord near Stavanger, Norway, before deployment in the North Sea.

A floating wind turbine is a wind turbine mounted on a floating structure that allows the turbine to generate electricity in water depths where bottom-mounted towers are not feasible. The wind can be stronger and steadier over water due to the absence of topographic features that may disrupt wind flow.[1] The electricity generated is sent to shore through undersea cables. The initial capital cost of floating turbines is competitive with bottom-mounted, near-shore wind turbines[2] while the rate of energy generation is higher out in the sea as the wind flow is often more steady and unobstructed by terrain features.[citation needed] The relocation of wind farms into the sea can reduce visual pollution if the windmills are sited more than 12 miles (19 km) offshore, provide better accommodation of fishing and shipping lanes, and allow siting near heavily developed coastal cities.[3][4]

Floating wind parks are wind farms that site several floating wind turbines closely together to take advantage of common infrastructure such as power transmission facilities.

Contents

History

The concept for "large-scale offshore floating wind turbines was introduced by Professor William E. Heronemus at the University of Massachusetts in 1972. [I]t was not until the mid 1990’s, after the commercial wind industry was well established, that the topic was taken up again by the mainstream research community."[1] As of 2003, existing offshore fixed-bottom wind turbine technology deployments had been limited to water depths of 30-meters. Worldwide deep-water wind resources are extremely abundant in subsea areas with depths up to 600 meters, which are thought to best facilitate transmission of the generated electric power to shore communities.[1]

Operational deep-water platforms

A tension leg mooring system as used by Blue H: left-hand tower-bearing structure (grey) is free floating, the right-hand structure is pulled by the tensioned cables (red) down towards the seabed anchors (light-grey)

As of 2009, there have been only two operational floating wind turbines used to farm wind energy over deep-water. Blue H deployed the first floating wind turbine 113 kilometres (70 mi) off of the coast of Italy in December, 2007. It was then decommissioned at the end of 2008 after completing a planned test year of gathering operational data.[5]

The first large-capacity, 2.3 megawatt floating wind turbine is Hywind, which became operational in the North Sea off of Norway in September, 2009 and is still operational As of October 2009.[6]

Blue H Technologies

Blue H Technologies of the Netherlands operated a prototype deep-water platform with an 80-kilowatt turbine off of Puglia, southeast Italy in 2008.[7] Installed 21 km off the coast in waters 113 meters deep in order to gather test data on wind and sea conditions, the small prototype unit was decommissioned at the end of 2008. Blue H has successfully decommissioned the unit as it embarks on plans to build a 38-unit deepwater wind farm at the same location.[5]

The Blue H technology utilizes a tension-leg platform design and a two-bladed turbine. The two-bladed design can have a "much larger chord, which allows a higher tip speed than those of three-bladers. The resulting increased background noise of the two-blade rotor is not a limiting factor for offshore sites."[5]

As of 2009, Blue H is building the first full-scale commercial 2.4 MWe unit in Brindisi, Italy which it expects to deploy at the same site of the prototype in the southern Adriatic Sea in 2010. This is the first unit in the planned 90 MW Tricase offshore wind farm, located more than 20 km off the Puglia coast line.[5]


Hywind

A single floating cylinder moored by catenary cables. Hywind uses a ballasted catenary layout that adds 60 tonne weights hanging from the midpoint of each anchor cable to provide additional tension.

The world's first operational deep-water floating large-capacity wind turbine is the Hywind, in the North Sea off of Norway.[6] The Hywind was towed out to sea in early June 2009.[8] The 2.3 megawatt turbine was constructed by Siemens Wind Power and mounted on a floating tower built by France's Technip[citation needed] with a 100 metre deep draft. The installation is owned by StatoilHydro and will be tested for two years. After assembly in the calmer waters of Åmøy Fjord near Stavanger, Norway, the 120-meter-tall tower with a 2.3 MW turbine was towed 10 km offshore into 220-meter-deep water, 10 km southwest of Karmøy, on 6 June 2009 for a two year test deployment."[7] Alexandra Beck Gjorv of StatoilHydro said, "[The experiment] should help move offshore wind farms out of sight ... The global market for such turbines is potentially enormous, depending on how low we can press costs."[9] The unit became operational in the summer of 2009.[6][10] Hywind was inaugurated on 8 September 2009.[11][12]

The turbine cost 400 million kroner (around US$62 million) to build and deploy.[13][14] The 13-kilometer (8-mile) long submarine power transmission cable was installed in July, 2009 and system test including rotor blades and initial power transmission was conducted shortly thereafter.[15] The installation is expected to generate about 9 GW·h of electricity annually.[16]

Project Mustard Seed

The world's first freshwater wind farm was deployed on Lake Erie, eight miles off the coast of Cleveland, Ohio during November 2009. Twelve yellow barrels filled with foam were used as floats for a test rig that produced up to 1.2 kilowatts of power for on-board electronics. According its parent organization, Operation Mustard Seed, this wind power system was developed with "limited budget and resources" and would eventually lead to larger scale freshwater wind power deployments. Originally anchored to Lake Erie's mud floor, the team lost communication with the system during heavy storms, several days after deployment. To date, it has never been found or recovered. [17]


Topologies

Platform topologies can be classified into:

  • single-turbine-floater (one wind turbine mounted on a floating structure)
  • multiple turbine floaters (multiple wind turbines mounted on a floating structure)

Engineering considerations

Undersea mooring of floating wind turbines are accomplished with three principle mooring systems. Two common types of engineered design for anchoring floating structures include tension-leg and catenary loose mooring systems. Tension leg mooring systems have vertical tethers under tension providing large restoring moments in pitch and roll. Catenary mooring systems provide station keeping for an offshore structure yet provide little stiffness at low tensions."[18] A third form of mooring system is the ballasted catenary configuration, created by adding multiple-tonne weights hanging from the midsection of each anchor cable in order to provide additional cable tension and therefore increase stiffness of the above-water floating structure.[18]

Economics

"Technically, the [theoretical] feasibility of deepwater [floating] wind turbines is not questioned as long-term survivability of floating structures has already been successfully demonstrated by the marine and offshore oil industries over many decades. However, the economics that allowed the deployment of thousands of offshore oil rigs have yet to be demonstrated for floating wind turbine platforms. For deepwater wind turbines, a floating structure will replace pile-driven monopoles or conventional concrete bases that are commonly used as foundations for shallow water and land-based turbines. The floating structure must provide enough buoyancy to support the weight of the turbine and to restrain pitch, roll and heave motions within acceptable limits. The capital costs for the wind turbine itself will not be significantly higher than current marinized turbine costs in shallow water. Therefore, the economics of deepwater wind turbines will be determined primarily by the additional costs of the floating structure and power distribution system, which are offset by higher offshore winds and close proximity to large load centers (e.g. shorter transmission runs)."[1]

As of 2009 however, the economic feasibility of shallow-water offshore wind technologies is more completely understood. With empirical data obtained from fixed-bottom installations off many countries for over a decade now, representative costs are well understood. Shallow-water turbines cost between 2.4 and 3 million United States dollars per megawatt to install, according to the World Energy Council.[7]

The practical feasibility and per-unit economics of deep-water, floating-turbine offshore wind is yet to be seen. Initial deployment of single full-capacity turbines in deep-water locations is only just beginning in the summer of 2009.[7]

Other proposed designs

WindFloat

WindFloat is a patent pending floating foundation for offshore wind turbines aimed at improving dynamic stability. The WindFloat design is intended to dampen wave and turbine induced motion utilizing a tri-column triangular platform with the wind turbine positioned on only one of the three columns. The triangular platform is then "moored with 6 lines, 4 of which are connected to the column stabilizing the turbine, thus creating an asymmetric" mooring to increase stability and reduce motion.[19] This technology could allow wind turbines to be sited in offshore areas that were previously considered inaccessible, areas having water depth exceeding 50 meters and more powerful wind resources than shallow-water offshore wind farms typically encounter.[20]

As of February 2009, there are preliminary plans for the phased development of a deep-water offshore wind farm off the coast of Portugal using WindFloat technology.[20]

Nautica Windpower

Nautica Windpower's AFT design features a downwind two-bladed rotor with passive wind alignment to reduce costs

Nautica Windpower uses a patented technology aimed at reducing system weight, complexity and costs for deep water sites. Scale model tests in open water have been conducted and structural dynamics modeling is under development for a multi-megawatt design.[21] Nautica Windpower's Asymmetric Floating Tower (AFT) uses a single mooring line and a downwind two-bladed rotor configuration that is deflection tolerant and aligns itself with the wind without an active yaw system. Two-bladed, downwind turbine designs that can accommodate flexibility in the blades will potentially prolong blade lifetime, diminish structural system loads and reduce offshore maintenance needs, yielding lower lifecycle costs. [22]

See also

References

  1. ^ a b c d Musial, W.; S. Butterfield, A. Boone (2003-11). "Feasibility of Floating Platform Systems for Wind Turbines". NREL preprint (NREL) (NREL/CP-500-34874): 14. http://www.osti.gov/bridge/servlets/purl/15005820-0aqZAv/native/15005820.pdf. Retrieved 2009-09-10. 
  2. ^ (WMV) sway_movie. SWAY. Event occurs at 1m30s. http://sway.no/assets/files/sway_movie.wmv. Retrieved 2009-10-20. "Due to its simple construction, the capital expenditure of the floating Sway system is competitive to bottom mounted, near-shore wind towers; however, the average wind speeds far off-shore are typically higher so more energy can be produced and the cost of energy is actually reduced when compared with near-shore wind parks." 
  3. ^ Mark Svenvold (2009-09-09). "The world's first floating wind turbine goes on line in Norway". DailyFinance.com. http://www.dailyfinance.com/2009/09/09/the-worlds-first-floating-wind-turbine-goes-on-line-in-norway/. Retrieved 2009-10-20. 
  4. ^ Union of Concerned Scientists (2003-07-15). "Farming the Wind: Wind Power and Agriculture". http://www.ucsusa.org/clean_energy/technology_and_impacts/impacts/farming-the-wind-wind-power.html. Retrieved 2009-10-20. 
  5. ^ a b c d "Floating Wind Turbines, Deep Water Installation". Offshore Industry 2 (4): 48-51. 2009. http://www.bluehgroup.com/press/Offshore_Industry_Blue_H_Technologies_September_2009.pdf. Retrieved 2009-10-20. "In December 2007, Blue H launched the world's first floating wind turbine 21.3 km off the southern Italian coast at a depth of 113 m. The concession ran out at the end of 2008 and Blue H decommissioned the unit successfully.". 
  6. ^ a b c Madslien, Jorn (2009-09-08), Floating challenge for offshore wind turbine, BBC News, http://news.bbc.co.uk/2/hi/business/8235456.stm, retrieved 2009-09-14 
  7. ^ a b c d Patel, Prachi (2009-06-22). "Floating Wind Turbines to Be Tested". IEEE Spectrum. http://www.spectrum.ieee.org/green-tech/wind/floating-wind-turbines-to-be-tested. Retrieved 2009-06-25. 
  8. ^ Madslien, Jorn (2009-06-05). "Floating wind turbine launched". BBC News. http://news.bbc.co.uk/2/hi/business/8085551.stm. Retrieved 2009-09-14. 
  9. ^ "First offshore wind turbine goes to sea". UPI. 2009-06-06. http://www.upi.com/Business_News/2009/06/06/First-offshore-wind-turbine-goes-to-sea/UPI-40901244312888/. Retrieved 2009-06-07. 
  10. ^ RFI - Radio France Internationale in English, international radio news and feature programmes
  11. ^ "Technip and StatoilHydro Announce Inauguration of World's First Full-Scale Floating Wind Turbine". OilVoice. 2009-09-13. http://www.oilvoice.com/n/Technip_and_StatoilHydro_Announce_Inauguration_of_Worlds_First_FullScale_Floating_Wind_Turbine/767657b69.aspx. Retrieved 2009-09-19. 
  12. ^ "Hywind floating wind turbine". StatoilHydro. 2009-09-08. http://www.statoilhydro.com/en/TechnologyInnovation/NewEnergy/RenewablePowerProduction/Onshore/Pages/Karmoy.aspx. Retrieved 2009-09-29. 
  13. ^ Statoil Draws On Offshore Oil Expertise To Develop World's First Floating Wind Turbine. NewTechnology magazine. 2009-09-08. http://www.ntm.nickles.com/issues/story.aspx?aid=1000340202. Retrieved 2009-10-21. 
  14. ^ Turker, Tux (2009-05-19). "Maine task force to identify offshore wind energy sites". Energy Current. http://www.energycurrent.com/index.php?id=3&storyid=18144. Retrieved 2009-06-07. 
  15. ^ Donovan, Matthew (2009-08-11). "Subsea cable installed at Hywind project". Energy Current. http://www.energycurrent.com/index.php?id=3&storyid=19929. Retrieved 2009-09-02. 
  16. ^ Terje Riis-Johansen, Minister of Petroleum and Energy, Norway (2009-10-09). "Speech: Opening of Hywind – the world’s first full-scale floating wind turbine". Norway Ministry of Petroleum and Energy. http://www.regjeringen.no/en/dep/oed/whats-new/speeches-and-articles/the_minister/speeches-and-articles-by-the-minister-of/2009/opening-of-hywind--the-worlds-first-full.html?id=576658. Retrieved 2009-10-21. 
  17. ^ "Operation Mustard Seed Website". Operation Mustard Seed. 2009-12-12. http://www.operationmustardseed.com/OMS_PMS_Page.html. Retrieved 2009-12-12. 
  18. ^ a b Floating Offshore Wind Turbines: Responses in a Seastate -- Pareto Optimal Designs and Economic Assessment, P. Sclavounos et al, October 2007.
  19. ^ Balogh, Emily (2008-12-18). "Deepwater Offshore Wind Power Generation Using Oil and Gas Platform Technology". RenewableEnergyWorld.com. http://www.renewableenergyworld.com/rea/news/article/2008/12/deepwater-offshore-wind-power-generation-using-oil-and-gas-platform-technology-54314. Retrieved 2009-09-03. 
  20. ^ a b "Principle Power & EDP to Develop Floating Offshore Wind". RenewableEnergyWorld.com. 2009-02-20. http://www.renewableenergyworld.com/rea/news/article/2009/02/principle-power-edp-sign-moa-for-offshore-wind. Retrieved 2009-09-03. 
  21. ^ Braciszeski, Kevin (2010-1-23). "Why Not Floating Windmills?". Ludington Daily News. http://www.ludingtondailynews.com/news/47569-why-not-floating-windmills. Retrieved 2010-02-8. 
  22. ^ "U.S. Offshore Wind Energy: A Path Forward". Working Paper page 24. U.S. Offshore Wind Collaborative. 2009-10-16. http://www.usowc.org/pdfs/PathForwardfinal.pdf. Retrieved 2009-11-07. 

External links

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