Unconventional wind turbines#Observation deck

Nearly all modern wind turbines use rotors with three blades, but some use only two blades. This was the type used at Kaiser-Wilhelm-Koog, Germany, where a large experimental two-bladed unit—the GROWIAN, or Große Windkraftanlage (big wind turbine)—operated from 1983 to 1987. Other prototypes and wind turbine types were manufactured by NedWind. The Eemmeerdijk Wind Park in Zeewolde, Netherlands uses only two-bladed turbines. Wind turbines with two blades are manufactured by Windflow Technology, Mingyang Wind Power, GC China Turbine Corp and Nordic Windpower.[https://www.en.wind-turbine-models.com/turbines/330-nedwind-nw-43-500 NedWind Rhenen bV NW 43/500 (Turbine)] {{Webarchive|url=https://web.archive.org/web/20130307033819/http://www.wind-turbine-models.com/turbine/330/nedwind-rhenen-bv/nw-43-500 |date=2013-03-07 }}, Nedwind website. Retrieved 27 January 2013. The NASA wind turbines (1975–1996) each had 2-blade rotors, producing the same energy at lower cost than three-blade rotor designs.

Nearly all wind turbines place the rotor in front of the nacelle when the wind is blowing (upwind design). Some turbines place the rotor behind the nacelle (downwind design). This design has the advantage that the turbine can be made to passively align itself with the wind, reducing cost. The main drawback is that the load on the blades changes as they pass behind the tower, increasing fatigue loading, and potentially exciting resonances in other turbine structures.

A research project,{{Cite web|url=http://www.ifb.uni-stuttgart.de/~doerner/diffuser.html|archive-url=https://web.archive.org/web/20061025011240/http://www.ifb.uni-stuttgart.de/~doerner/diffuser.html|url-status=dead|title=Uni-Stuttgart.de website|archive-date=October 25, 2006}} the ducted rotor consists of a turbine inside a duct that flares at the back. They are also referred as Diffuser-Augmented Wind Turbines (i.e. DAWT). Its main advantage is that it can operate in a wide range of winds and generate a higher power per unit of rotor area. Another advantage is that the generator operates at a high rotation rate, so it doesn't require a bulky gearbox, allowing the mechanical portion to be smaller and lighter. A disadvantage is that (apart from the gearbox) it is more complicated than the unducted rotor and the duct's weight increases tower weight. The Éolienne Bollée is an example of a DAWT.

Two or more rotors may be mounted to a single driveshaft, with their combined co-rotation together turning the same generator: fresh wind is brought to each rotor by sufficient spacing between rotors combined with an offset angle (alpha) from the wind direction. Wake vorticity is recovered as the top of a wake hits the bottom of the next rotor. Power was multiplied several times using co-axial, multiple rotors in testing conducted by inventor and researcher Douglas Selsam in 2004. The first commercially available co-axial multi-rotor turbine is the patented dual-rotor American Twin Superturbine from Selsam Innovations in California, with 2 propellers separated by 12 feet. It is the most powerful {{convert|7|ft|m|adj=mid|-diameter}} turbine available, due to this extra rotor. In 2015, Iowa State University aerospace engineers Hui Hu and Anupam Sharma were optimizing designs of multi-rotor systems, including a horizontal-axis co-axial dual-rotor model. In addition to a conventional three-blade rotor, it has a smaller secondary three-blade rotor, covering the near-axis region usually inefficiently harvested. Preliminary results indicated 10–20% gains, less efficient than is claimed by existing counter-rotating designs.{{Cite web|url=https://www.news.iastate.edu/news/2015/03/06/dualrotorturbines|title=Iowa State engineers study the benefits of adding a second, smaller rotor to wind turbines – News Service – Iowa State University|website=www.news.iastate.edu}}

File:Counter rotating wind turbine animation.gif

When a system expels or accelerates mass in one direction, the accelerated mass causes a proportional but opposite force on that system. The spinning blade of a single rotor wind turbine causes a significant amount of tangential or rotational air flow. The energy of this tangential air flow is wasted in a single-rotor propeller design. To use this wasted effort, the placement of a second rotor behind the first takes advantage of the disturbed airflow, and can gain up to 40% more energy from a given swept area as compared with a single rotor. Other advantages of contra-rotation include no gear boxes and auto-centering on the wind (no yaw motors/mechanism required). A patent application dated 1992 exists based on work done with the Trimblemill.[http://www.wipo.int/pctdb/en/wo.jsp?wo=1992012343&IA=WO1992012343&DISPLAY=DESC (WO1992012343) Wind Turbine], Patentscope website, 1992.

When the counter-rotating turbines are on the same side of the tower, the blades in front are angled forwards slightly so as to avoid hitting the rear ones. If the turbine blades are on opposite sides of the tower, it is best that the blades at the back be smaller than the blades at the front and set to stall at a higher wind speed. This allows the generator to function at a wider wind speed range than a single-turbine generator for a given tower. To reduce sympathetic vibrations, the two turbines should turn at speeds with few common multiples, for example 7:3 speed ratio.{{Citation needed|date=October 2016}}

When land or sea area for a second wind turbine does not come at a premium the 40% gain with a second rotor has to be compared with a 100% gain via the expense of a separate foundation and tower with cabling for the second turbine. The overall power coefficient of a Counter-rotating horizontal-axis wind turbine may depend by the axial and the radial shift of the rotors {{Cite journal|last1=Hetyei|first1=Csaba|last2=Szlivka|first2=Ferenc|title=Counter-Rotating Dual Rotor Wind Turbine Layout Optimisation |date=2021-04-30|url=https://ojs.cvut.cz/ojs/index.php/ap/article/view/6721|journal=Acta Polytechnica|language=en|volume=61|issue=2|pages=342–349|doi=10.14311/AP.2021.61.0342|issn=1805-2363|doi-access=free|hdl=10467/98345|hdl-access=free}} and by the rotors' size.{{Cite journal|last1=Hetyei|first1=Csaba|last2=Szlivka|first2=Ferenc|date=2020-12-20|title=Rotor size optimisation of a counter-rotating dual-rotor wind turbine|url=https://biztonsagtudomanyi.szemle.uni-obuda.hu/index.php/home/article/view/86|journal=Safety and Security Sciences Review|language=en|volume=2|issue=4|pages=89–104|issn=2676-9042}} {{As of|2005}}, no large, counter-rotating HAWTs are commercially sold.

In addition to variable pitch blades, furling tails and twisting blades are other improvements on wind turbines. Similar to the variable pitch blades, they may also greatly increase efficiency and be used in "do-it-yourself" construction.[http://www.rebelwolf.com/essn/ESSN-Aug2005.pdf Furling tail windturbines] (page 18) PDF

De Nolet is a wind turbine in Schiedam disguised as a windmill.

Instead of airplane-inspired wing blades, the design takes after the Archimedean screw turbine, a helix-patterned pipe used in ancient Greece to pump water up from a deeper source.

{{cite news |title=Is this odd-looking wind turbine the most efficient you can buy? |url=https://www.washingtonpost.com/news/innovations/wp/2014/06/10/is-this-odd-looking-wind-turbine-the-most-efficient-you-can-buy/ |newspaper=Washington Post |access-date=19 February 2022}}{{cite web |title=StarWind, roof mountable wind turbine |url=https://www.youtube.com/watch?v=BchzNf5lNmw |website=YouTube |access-date=19 February 2022}}

The boundary layer or Tesla turbine uses boundary layers instead of blades.

One modern version is the Fuller turbine.{{Cite web|url=https://newatlas.com/bladeless-wind-turbines/14977/|title=Virtually silent, fully enclosed, bladeless wind turbines on the way|website=newatlas.com|date=7 May 2010 }} The concept is similar to a stack of disks on a central shaft, separated by a small air gap. The surface tension of air in the small gaps creates friction, rotating the disks around the shaft. Vanes direct the air for improved performance, hence it is not strictly bladeless.

{{main article|Vaneless ion wind generator}}

A vaneless ion wind generator is a theoretical device that produces electrical energy by using the wind to move electric charge from one electrode to another.

{{see also|Piezoelectricity}}

Piezoelectric wind turbines work by flexing piezoelectric crystals as they rotate, sufficient to power small electronic devices. They operate with diameters on the scale of 10 centimeters.{{Cite web|url=http://www.worldchanging.com/archives/003739.html#piezo|title=Description of several types of wind turbines –including piezoelectric|access-date=2008-03-05|archive-url=https://web.archive.org/web/20080514200852/http://www.worldchanging.com/archives/003739.html#piezo|archive-date=2008-05-14|url-status=dead}}

{{Main|Solar updraft tower}}

Wind turbines may be used in conjunction with a solar collector to extract energy from air heated by the sun and rising through a large vertical updraft tower.

The Vortex Bladeless device maximizes vortex shedding, using the vorticity in wind to flutter a lightweight vertical pole, which delivers that energy to a generator at the bottom of the pole.

Sam Davis.

[http://powerelectronics.com/blog/wind-turbine-without-blades "A Wind Turbine Without Blades"].

2015.

Phil McKenna.

[http://www.technologyreview.com/news/537721/bladeless-wind-turbines-may-offer-more-form-than-function/ "Bladeless Wind Turbines May Offer More Form Than Function"].

2015.

Liz Stinson.

[https://www.wired.com/2015/05/future-wind-turbines-no-blades/ "The future of wind turbines? No blades"].

2015.

{{Cite web|url=https://www.kcet.org/redefine/you-should-probably-be-skeptical-about-this-bladeless-wind-turbine|title=You Should Probably Be Skeptical About This Bladeless Wind Turbine|last=Clarke|first=Chris|date=May 15, 2015|website=KCET}} The design has been criticized for its efficiency of 40%, compared to 70% for conventional designs.{{Cite web|url=https://www.technologyreview.com/s/537721/bladeless-wind-turbines-may-offer-more-form-than-function/|title=Why the Bladeless Wind Turbine Has Its Skeptics|last=McKenna|first=Phil|date=May 15, 2015|website=MIT Technology Review|language=en|access-date=2019-02-28}} However, individual poles can be placed more closely together, offsetting the losses. The design avoids mechanical components, lowering costs. The system also does not threaten bird life and operates silently.{{Cite magazine|url=https://www.wired.com/2015/05/future-wind-turbines-no-blades/|title=The Future of Wind Turbines? No Blades|last=Stinson|first=Elizabeth|date=2015-05-15|magazine=Wired|access-date=2019-02-28|issn=1059-1028}}

The Saphonian design uses an oscillating dish to drive a piston, which then connects to a generator.{{Cite web|url=https://newatlas.com/saphonian-bladeless-wind-turbine/24890/|title=Saphonian bladeless turbine boasts impressive efficiency, low cost|website=newatlas.com|date=8 November 2012 }}{{Cite web|url=https://www.kcet.org/redefine/bladeless-wind-turbine-too-good-to-be-true|title=Bladeless Wind Turbine Too Good To Be True?|last=Clarke|first=Chris|date=December 12, 2013|website=KCET}}

The Windbeam generator consists of a beam suspended by springs within an outer frame. The beam oscillates rapidly when exposed to airflow due to multiple fluid flow phenomena. A linear alternator converts the beam motion. The absence of bearings and gears eliminates frictional inefficiencies and noise. Costs are low due to low cost components and simple construction.{{Cite web|url=http://zephyrenergy.com/|title=Zephyr Energy | Windbeam | | Zephyr Energy Corporation’s patented Windbeam micro generator captures energy from airflow to recharge batteries and power electronic devices. Zephyr Energy | Windbeam | | Zephyr Energy Corporation’s patented Windbeam micro generator captures energy from airflow to recharge batteries and power electronic devices.}}

{{Main article|Windbelt}}

Windbelt is a flexible, tensioned belt that vibrates from the passing flow of air, due to aeroelastic flutter. A magnet, mounted at one end of the belt oscillates in and out of coiled windings, producing electricity. The inventor is Shawn Frayne.Ward, Logan. [http://www.popularmechanics.com/technology/industry/4224763.html Windbelt, Cheap Generator Alternative, Set to Power Third World] {{Webarchive|url=https://web.archive.org/web/20090421173218/http://www.popularmechanics.com/technology/industry/4224763.html |date=2009-04-21 }}, Popular Mechanics website, October 1, 2007.Sofge, Erik. [http://www.popularmechanics.com/science/energy/solar-wind/4287795 Shawn Frayne Makes Another Leap in Wind Power: Breakthrough Winner Update], Popular Mechanics website, December 18, 2009.

File:Airborne wind generator-en.svg

{{Main article|Airborne wind turbine|High-altitude wind power|Crosswind kite power}}

Airborne wind turbines may operate in low or high altitudes; they are part of a wider class of airborne wind energy systems (AWES) addressed by high-altitude wind power and crosswind kite power. Wind turbines could be flown in high-speed winds using high-altitude wind power tactics, taking advantage of high altitude winds.

When the generator is on the ground, then the tethered aircraft need not carry the generator mass or have a conductive tether. When the generator is aloft, then a conductive tether would be used to transmit energy to the ground or used aloft or beamed to receivers using microwave or laser.

File:Principle of kite energy.png

File:KiteEight.png

For instance, a system of tethered kites{{Cite web|url=http://www.kiteenergysystems.com/|title=Kite Energy at KiteEnergySystems|website=www.kiteenergysystems.com}} could capture energy from high-altitude winds. Another concept uses a helium balloon with attached sails to generate pressure and drive rotation around a horizontal axis. Circular motion of ropes transfer kinetic energy to ground-based generator.{{Citation |last=Michailidis |first=Giannis |title=High-Altitude-Wind-Turbine-Concept |date=2023-01-09 |url=https://github.com/John-Mich/High-Altitude-Wind-Turbine-Concept |access-date=2023-02-22}}

File:Vertical axis wind turbine offshore.gif

{{Main|Vertical axis wind turbine}}

The Gorlov helical turbine (GHT) is a modification of the Darrieus turbine design that uses helical blades/foils.A.M. Gorlov, [https://patents.google.com/patent/US5451137 Unidirectional helical reaction turbine operable under reversible fluid flow for power systems], [http://patft.uspto.gov/netacgi/nph-Parser?Sect2=PTO1&Sect2=HITOFF&p=1&u=%2Fnetahtml%2FPTO%2Fsearch-bool.html&r=1&f=G&l=50&d=PALL&RefSrch=yes&Query=PN%2F5451137 United States Patent 5,451,137], Sept. 19, 1995.A.M. Gorlov, [https://patents.google.com/patent/US6253700 Method for maintaining flotation using a helical turbine assembly], [http://patft.uspto.gov/netacgi/nph-Parser?Sect2=PTO1&Sect2=HITOFF&p=1&u=%2Fnetahtml%2FPTO%2Fsearch-bool.html&r=1&f=G&l=50&d=PALL&RefSrch=yes&Query=PN%2F6253700 United States Patent 6,253,700], July 3, 2001.

One design uses many nylon blades to run a generator. Its permanent magnets are on the tips of the blades, while the stator is a ring outside the blades.[http://www.windtronics.eu.com/wp-content/uploads/International-Catalog.pdf Windtronics]]

{{main article | Giromill }}

The giromill is a vertical axis turbine that rotates one blade in one direction while another moves in the opposite direction. Consequently, only one blade is working at a time. Its efficiency is low.S. Brusca, R. Lanzafame, M. Messina. [https://link.springer.com/article/10.1007%2Fs40095-014-0129-x "Design of a vertical-axis wind turbine: how the aspect ratio affects the turbine’s performance"]. 2014.

Revolving-wing wind turbines or rotating-wing wind turbines are a category of lift-type vertical-axis wind turbines that use one vertically standing, non-helical airfoil to generate 360-degree rotation around a vertical shaft which runs through the center of the airfoil.

A omnidirectional turbine which uses the Bernoulli principle to generate energy using wind from any direction. The design is spherical with a number of ducts across the surface, a pressure difference causes the rotation. The design won the James Dyson Award 2018.{{Cite web|url=https://www.jamesdysonaward.org/2018/project/o-wind-turbine/|title=O-Wind Turbine|website=James Dyson Award|language=en|access-date=2019-05-21}}{{Cite news|url=https://www.theguardian.com/environment/2018/sep/05/groundbreaking-spinning-wind-turbine-wins-uk-dyson-award|title=Groundbreaking 'spinning' wind turbine wins UK Dyson award|last=Smithers|first=Rebecca|date=2018-09-05|work=The Guardian|access-date=2019-05-21|language=en-GB|issn=0261-3077}}

Airloom is developing a turbine that uses vertical blades that move around an oval track. The system is 25 meters tall. The system is modular: blades can be added and the track length adjusted accordingly. The vendor claimed that the levelized cost of electricity is one-third of conventional turbines. The design is a terrestrial equivalent of an airborne turbine whose trajectory is fixed. A system can be installed and operating within one day.{{Cite news |last=Hanson |first=Karen |date=November 20, 2023 |title=Airloom CEO: Small Wind Turbine Functions Like a Roller Coaster |url=https://eepower.com/news/airloom-ceo-small-wind-turbine-functions-like-a-roller-coaster/# |access-date=February 17, 2024 |work=EE Power}}

SheerWind's INVELOX technology was developed by Daryoush Allaei. The invention captures and delivers wind to a turbine. In a sense, INVELOX is a wind-injection system, much like a fuel-injection system for cars. A large intake captures wind and funnels it to a concentrator that ends in a Venturi section and finally wind exits from a diffuser. Turbines are placed inside the Venturi section of the INVELOX. Inside the Venturi the dynamic pressure is high while the static pressure is low. The turbine converts dynamic pressure or kinetic energy to mechanical rotation and thereby to electrical power using a generator.{{Cite web|url=https://www.technologyreview.com/s/508136/ducted-wind-turbines-an-energy-game-changer/|title=Ducted Wind Turbines: An Energy Game Changer?|last=McKenna|first=Phil|website=MIT Technology Review |date=2012-12-03}}{{Cite web |url=http://sheerwind.com/ |archive-url=https://web.archive.org/web/20150207003734/http://sheerwind.com/ |access-date=2019-04-22 |archive-date=2015-02-07 |title=SheerWind, Changing the Course of Power Generation }} The device has been constructed and tested, but has been criticized for lack of efficiency.{{cite web|url=http://cleantechnica.com/2014/07/08/invelox-ducted-turbine-latest-long-line-failures/|title=Sheerwind Invelox: All Hype, No Substance|date=8 July 2014|work=CleanTechnica|access-date=24 September 2016}} {{as of|2017}}, prototypes are being installed.{{cite web|url=http://wwmt.com/news/local/strange-structure-at-fort-custer-harnesses-wind-power|title=Strange structure at Fort Custer harnesses wind power|date=16 March 2016|work=WWMT|access-date=20 January 2017}}{{cite web|url=http://nedpowerswh.com/nieuws/|title=Nieuws – NedpowerSWH|work=NedpowerSWH|date=28 February 2016 |access-date=20 January 2017}}

{{main article|Wind turbines on public display}}

Wind-turbines can be installed on building roofs. Examples include Marthalen Landi-Silo in Switzerland, Council House 2 in Melbourne, Australia. Ridgeblade in the UK is a vertical wind turbine on its side mounted on the apex of a pitched roof. Another example installed in France is the Aeolta AeroCube. Discovery Tower is an office building in Houston, Texas, that incorporates ten wind turbines.

The Museum of Science in Boston, Massachusetts began constructing a rooftop Wind Turbine Lab in 2009.{{cite web|url=http://www.renewableenergyworld.com/rea/news/article/2009/06/new-us-rooftop-wind-turbine-lab|title=New US Rooftop Wind Turbine Lab|date=2009-06-01|publisher=Renewable Energy World|access-date=2009-07-07}} The lab is testing nine wind turbines from five different manufacturers. Rooftop wind turbines may suffer from turbulence, especially in cities, which reduces power output and accelerates turbine wear.{{cite news|url=http://www.timesonline.co.uk/tol/news/uk/article706123.ece|title=Home wind turbines dealt killer blow|last=Leake|first=Jonathan|date=2006-04-16|access-date=2009-07-13|publisher=The Sunday Times|location=London}}{{dead link|date=September 2024|bot=medic}}{{cbignore|bot=medic}} The lab seeks to address the general lack of performance data for urban wind turbines.

Due to structural limitations of buildings, limited space in urban areas, and safety considerations, building turbines are usually small (with capacities in the low kilowatts). An exception is the Bahrain World Trade Centre with three 225 kW wind turbines mounted between twin skyscrapers.

File:Highway wind turbine.gif

Proposals call for generating power from the energy in the draft created by traffic.{{Cite web|url=https://www.freepatentsonline.com/7427173.html|title=Power generation system utilizing wind draft from vehicular traffic}}{{Cite web|url=http://www.metropolismag.com/story/20070110/the-new-i-jersey-barrier|title=Mark Oberholzer's roadside Darrieus wind turbine design|access-date=2009-09-01|archive-url=https://web.archive.org/web/20090817224235/http://www.metropolismag.com/story/20070110/the-new-i-jersey-barrier|archive-date=2009-08-17|url-status=dead}}

Some installations have installed visitor centers on turbine bases, or by providing viewing areas.{{cite web|url=http://www.canada.com/edmontonjournal/news/business/story.html?id=63a5438a-ae99-4b76-9629-b7b59d238932|title=Canada wind farms blow away turbine tourists|last=Young|first=Kathryn|date=2007-08-03|publisher=Edmonton Journal|archive-url=https://web.archive.org/web/20090425064111/http://www2.canada.com/edmontonjournal/news/business/story.html?id=63a5438a-ae99-4b76-9629-b7b59d238932|archive-date=2009-04-25|url-status=dead|access-date=2008-09-06}} The wind turbines themselves are generally of conventional design, while serving the unconventional roles of technology demonstration, public relations, and education.

• EWICON
• Compact wind acceleration turbine
• Savonius wind turbine
• Wind lens
• Unconventional oil
• Unconventional gas

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