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Deep Ocean Floating Wind Turbines. How do they do that?
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Deep Ocean Floating Wind Turbines. How do they do that?

New Section

In this section, the speaker introduces the topic of offshore wind power and its potential for generating electricity.

Offshore Wind Power Opportunities

  • Offshore wind power has the potential to generate massive quantities of electricity due to stronger and steadier winds at sea compared to on land.
  • Offshore turbines can provide useful power during peak times of the day as winds in open seas often blow in the afternoon.
  • There are already several offshore wind farms in the UK and other European countries, but they are located in relatively shallow waters. The focus now is on developing turbines that can be deployed in deeper ocean waters where winds are even stronger and more consistent.

New Section

This section discusses the challenge of installing wind turbines in deep ocean waters and how floating turbines are being developed as a solution.

Floating Turbines

  • Due to the depth of open ocean waters, traditional tower-based turbines cannot be extended down and bolted to the seabed. As a result, floating turbines are being developed.
  • The idea is for these turbines to float on water rather than being fixed to the seabed.

New Section

This section provides an overview of the history and growth of offshore wind power.

History and Growth

  • The first offshore wind farm was opened in Denmark in 1991 with a capacity of 5 megawatts, providing electricity for over 2,000 Danish households annually.
  • Despite initial skepticism about offshore installations, the offshore wind market has grown significantly with 162 offshore wind farms worldwide and a combined generating capacity of nearly 33 gigawatts.
  • Europe and China are leading in offshore wind installations, but the United States is also starting to enter the market, with President Biden pledging to deploy 30 gigawatts of offshore wind power within the next decade.

New Section

This section explores the reasons for expanding offshore wind farms into deeper waters.

Expanding into Deeper Waters

  • Near-shore shallow water locations that are easily accessible are being rapidly utilized, so going further out to sea is becoming necessary.
  • Installing turbines in deep waters reduces risks for bird species as the density of turbines in deep sea arrays is lower and bird flights are more thinly distributed.
  • Floating wind farms have been successfully demonstrated in deep waters, such as Highwind Scotland, which has been generating electricity for over 20,000 homes since 2017.

New Section

This section discusses the technology and operation of floating wind turbines.

Technology and Operation

  • Floating wind turbines use buoyant concrete and steel keels to keep them upright on the water's surface. They are held in place by mooring cables attached to anchors on the seabed. Control software constantly monitors turbine operation and adjusts blade pitch for optimal performance.
  • Floating wind farms have proven their resilience against harsh weather conditions, including hurricane Ophelia and winter storms with high winds and large waves.
  • The world's largest floating wind farm off the coast of Aberdeen will be fully operational in 2022 with six turbines installed on floating platforms.

The Potential of Floating Wind Turbines

This section discusses the vast potential of offshore wind energy and the focus on deep water areas. It introduces General Electric's (GE) efforts in developing floating wind turbines.

The Untapped Potential of Offshore Wind Energy

  • 80% of the world's maritime waters are beyond the reach of conventional offshore turbines.
  • The total potential production capacity of offshore wind farms in the United States is nearly double its annual power consumption.
  • Fixed-base offshore turbines are being developed in shallow waters off the eastern seaboard, while deep water areas hold 58% of US offshore potential power.

GE's Floating Wind Turbines

  • Rogier Blom, Senior Principal Engineer at GE global research, has designed a 12 megawatt floating version of the Haliade X, the most powerful offshore wind turbine.
  • These turbines will have a height of 260 meters and a rotor diameter of 220 meters, capable of generating 67 gigawatt hours per year.
  • The system involves bolting towers to floating platforms called floaters, which carry the turbine's weight and respond to ocean motion.
  • The floating platforms are tethered to the ocean floor using actuated tension legs to reduce mechanical load.

Cost Reduction and Future Prospects

  • GE's concept focuses on control co-design, optimizing both turbine and platform design to avoid additional mass for withstanding high winds and waves.
  • Despite higher costs compared to near-shore or land-based wind turbines, advocates believe that as efficiency improves, costs will decrease for floating wind turbines too.
  • Offshore wind power alone has the potential to meet Europe, US, and Japan's electricity needs multiple times over according to projections by the International Energy Agency.

Challenges and Future Outlook

This section highlights challenges faced by floating wind turbines and the need for significant support from governments and investors. It also emphasizes the transformative potential of this renewable energy source.

Challenges in Scaling Up

  • Skepticism remains regarding the high cost of floating offshore wind turbines compared to other clean energy technologies.
  • The corrosive marine environment makes construction, deployment, and maintenance more expensive with shorter operational life spans.
  • Building a large number of floating turbines requires robust supply chains, shipyards, ports, and factories for serial fabrication.

Potential Transformational Impact

  • Despite challenges, the potential for floating wind turbines to provide vast quantities of renewable energy globally is attractive.
  • Offshore wind power alone could eventually meet the electricity needs of Europe, US, and Japan according to projections by the International Energy Agency.
  • China's involvement in offshore wind could help reduce their reliance on coal mines.

Conclusion

This section concludes the video by inviting viewers to share their thoughts or experiences related to floating wind turbines.

Engaging with Viewers

  • Viewers are encouraged to share their opinions or experiences related to floating wind turbines in the comments section.
  • The video expresses gratitude towards supporters who enable independent and ad-free content through Patreon.

Timestamps have been associated with relevant bullet points as requested.

Video description

Offshore wind turbines powered almost 40% of all the UK's homes in 2020. The International Energy Agency says there's enough potential accessible energy out there to power all of Europe, the US and Japan several times over. But to get at all of it, developers will have to go out into the very deep waters of the open oceans and find a way to make their turbines float safely and securely in all weather conditions. So how on earth are they going to do that? Video Transcripts available at our website http://www.justhaveathink.com Help support this channels independence at http://www.patreon.com/justhaveathink Or with a donation via Paypal by clicking here https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=GWR73EHXGJMAE&source=url You can also help keep my brain ticking over during the long hours of research and editing via the nice folks at BuyMeACoffee.com https://www.buymeacoffee.com/justhaveathink Download the Just Have a Think App from the AppStore or Google Play Interested in mastering and remembering the concepts that I present in my videos? Check out the FREE Dive Deeper mini-courses offered by the Center for Behavior and Climate. These mini-courses teach the main concepts in select JHAT videos and go beyond to help you learn additional scientific or conservation concepts. The courses are great for teachers to use or for individual learning.https://climatechange.behaviordevelopmentsolutions.com/just-have-a-think-jhat Check out other YouTube Climate Communicators zentouro: https://www.youtube.com/user/zentouro Climate Adam: https://www.youtube.com/user/ClimateAdam Kurtis Baute: https://www.youtube.com/user/ScopeofScience Levi Hildebrand: https://www.youtube.com/user/The100LH Simon Clark: https://www.youtube.com/user/SimonOxfPhys Sarah Karvner: https://www.youtube.com/channel/UCRwMkTu8sCwOOD6_7QYrZnw ClimateTown: https://www.youtube.com/channel/UCuVLG9pThvBABcYCm7pkNkA Jack Harries: https://www.youtube.com/user/JacksGap Beckisphere: https://www.youtube.com/channel/UCT39HQq5eDKonaUV8ujiBCQ Our Changing Climate : https://www.youtube.com/channel/UCNXvxXpDJXp-mZu3pFMzYHQ Research Links BBC Article https://www.bbc.com/future/article/20201013-is-wind-powers-future-in-deep-water Hywind https://www.equinor.com/en/what-we-do/floating-wind/how-hywind-works.html Kincardine https://www.offshorewind.biz/2021/07/05/worlds-largest-floating-wind-farm-takes-final-shape/ GE Article https://www.ge.com/news/reports/deep-water-wind-these-huge-floating-wind-turbines-could-help-america-meet-its-renewable Orsted Report https://orsted.com/en/about-us/whitepapers/making-green-energy-affordable/1991-to-2001-the-first-offshore-wind-farms World Forum Offshore Wind report https://wfo-global.org/wp-content/uploads/2021/02/WFO_Global-Offshore-Wind-Report-2020.pdf Wind Europe report https://windeurope.org/wp-content/uploads/files/about-wind/reports/Floating-offshore-statement.pdf