Floating Wind Turbines (0)

Floating Wind Turbines
University of Tartu 2012 Featured topics Basic layout of wind turbines About FWT Technology and advantages Initiatives Conclusion Introduction to how wind turbines work Electricity ­ Kinetic Click to edit Master text styles Second level energy of the wind Third level is converted to Fourth level mehanical energy. Fifth level
Main parts ­ 1. Rotor blades 2. Shaft 3. Generator Introduction to how wind turbines work Click to edit Master text styles Click to edit Master text styles Second level Second level Third level Third level Fourth level Fourth level Fifth level Fifth level About FWT Same energy producing concept as any other WT Professor William E. Heronemus, 1972 First offshore bottom - fixed WT as oflate 20s First FWT Hywind in Norway , late 2009 ( cost 55 mil euros ) Fukushima coast, Japan Technology and advantages Instead of bottom-fixed phycical foundation, floating platforms are attached to the seabed with mooring lines. Three main types of floating wind platforms Ballast stabilized Tension Leg Platforms Buoyancy Stabilized (Hywind) BUOYANCY STABILIZED Technology and advantages Access to previously inaccessible waters . Commissioned and assembled at the quayside. Foundations not necessary 1. Sea life disturbance minimized 2. Reduced geotechnical requirements
Also 3. Considerably less noise and visual pollution 4. Greater energy/cost value Initiatives - Hywind Developed by Norwegian energy company Statoil ASA World's first full - scale floating wind turbine 10 km off the soutwest coast of Norway 100 meters beneath the sea's surface Can be employed at ocean depths of 120 to 700 meters Main objective is to test the impact of wind and waves on the structure over a two- year period Initiatives ­ Blue H Dutch company Blue H Technologies has devised a `Submerged Deepwater Platform ' (SDP) In 2008, the company installed a 75% scale prototype SDP with a small wind turbine in 113-metre deep water 20 km off the coast of Southern Italy After 6 monts at sea, the unit was decommisioned early on 2009 Target goal are units in water depths of 70-300 meters Initiatives - Others WindFloat HiPRwind WinFlo Vertiwind WindSea Sway Conclusion Shallow -water turbines cost between 2.4 and 3 million United States dollars per megawatt to install, according to the World Energy Council . The main reason to develop FWT is the possibility to harness wind energy far off the coast-line, which in return gives greater energy output and less visual/noise pollution. Beneficial to marine biota and fishing industry. The FWT is young and growing wind technology in the field of energy. Potential is great around the world, especially in places where there is deep water coast-lines, such as Norway, Portugal and the West coast of America (continent). Technology is currently expensive , but in the near future it will decrease. Benefits that come with it, definetely out weigh the current conventional offshore WT. Next ten years are essential for the outcome of this prominsing technology. Thank you for your attention