Jump to content

Wells turbine: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
m robot Modifying: nl:Wellsturbine
m add {{Use dmy dates}}
 
(32 intermediate revisions by 27 users not shown)
Line 1: Line 1:
{{Use dmy dates|date=April 2022}}
[[Image:Wells turbine en.svg|thumb]]
[[Image:Wells_turbine_de.svg|thumbnail|Wells-Turbine<br />1 pipe wall <br />2 Axis<br />3 Hub<br />4 Turbine blade<br />5 Resulting force vector<br />6 direction of rotation<br />7 air flow (can also be in the other direction)]]


The '''Wells turbine''' is a low-pressure [[air turbine]] that rotates continuously in one direction in spite of the direction of the air flow.
The '''Wells turbine''' is a low-pressure [[Wind turbine|air turbine]] that rotates continuously in one direction independent of the direction of the air flow. Its blades feature a symmetrical [[airfoil]] with its plane of symmetry in the [[plane of rotation]] and perpendicular to the air stream.
Its blades feature a symmetrical [[airfoil]] with its plane of symmetry in the plane of rotation and perpendicular to the air stream.


It was developed for use in oscillating-water-column [[wave power]] plants, in which a rising and falling water surface moving in an air compression chamber produces an oscillating air current. The use of this bidirectional turbine avoids the need to rectify the air stream by delicate and expensive [[check valve]] systems.
It was developed for use in [[Oscillating Water Column]] [[wave power]] plants, in which a rising and falling water surface moving in an air compression chamber produces an oscillating air current. The use of this bidirectional turbine avoids the need to rectify the air stream by delicate and expensive [[check valve]] systems.


Its efficiency is lower than that of a turbine with constant air stream direction and asymmetric airfoil. One reason for the lower efficiency is that symmetric airfoils have a higher [[drag coefficient]] than asymmetric ones, even under optimal conditions. Also, in the Wells turbine, the symmetric airfoil is used with a high [[angle of attack]] (i.e., low blade speed / air speed ratio), as it occurs during air velocity maxima in volatile flow. A high angle of attack causes a condition known as "[[Stall (flight)|stall]]" in which the airfoil loses lift. The efficiency of the Wells turbine in oscillating flow reaches values between 0.4 and 0.7.
Its efficiency is lower than that of a turbine with constant air stream direction and asymmetric airfoil. One reason for the lower efficiency is that symmetric airfoils have a higher [[drag coefficient]] than asymmetric ones, even under optimal conditions. Also, in the Wells turbine, the symmetric airfoil runs partly under high [[angle of attack]] (i.e., low blade speed / air speed ratio), which occurs during the air velocity maxima of the oscillating flow. A high angle of attack causes a condition known as "[[Stall (flight)|stall]]" in which the airfoil loses lift. The efficiency of the Wells turbine in oscillating flow reaches values between 0.4 and 0.7.


This simple but ingenious device was developed by Prof. Alan Wells of [[Queen's University Belfast]] in the late 1970s.
The Wells turbine was developed by Prof. [[Alan Arthur Wells]] of [[Queen's University Belfast]] in the late 1970s.


== Annotation ==
== Annotation ==
Another solution of the problem of stream direction independent turbine is the [[Darrieus wind turbine]] (Darrieus rotor).
Another solution of the problem of stream direction independent turbine is the [[Darrieus wind turbine]] (Darrieus rotor).


==See also==
==See also==
*[[Siadar Wave Energy Project]]
*[[Siadar Wave Energy Project]]
*[[Yoshio Masuda]]
*[http://www.wetgen.com Hanna Wave Energy Turbine]
*[http://www.thingiverse.com/thing:224320 free 3D design to print your own]


== External links ==
== External links ==
{{Commons category|Wells turbines}}
* [http://www.uni-leipzig.de/~grw/lit/texte_099/59__1999/59_1999_hansa.htm about wave power generation in general with part on wells turbine] {{de icon}}

* [http://www.archipelago.co.uk/our-work/wave-power-animation Animation showing OWC wave power plant"]
* [http://www.archipelago.co.uk/our-work/wave-power-animation Animation showing OWC wave power plant"]
* [http://www.overunity.com/13578/oscillating-water-column/msg363717/#msg363717]


[[Category:Queen's University Belfast]]
[[Category:Queen's University Belfast]]
Line 25: Line 30:
[[Category:Power station technology]]
[[Category:Power station technology]]
[[Category:Renewable energy technology]]
[[Category:Renewable energy technology]]
[[Category:Energy from oceans and water]]
[[Category:Water power]]
[[Category:Electrical generators]]
[[Category:Electrical generators]]

[[de:Wells-Turbine]]
[[fr:Turbine Wells]]
[[it:Turbina Wells]]
[[nl:Wellsturbine]]

Latest revision as of 19:57, 14 April 2022

Wells-Turbine
1 pipe wall
2 Axis
3 Hub
4 Turbine blade
5 Resulting force vector
6 direction of rotation
7 air flow (can also be in the other direction)

The Wells turbine is a low-pressure air turbine that rotates continuously in one direction independent of the direction of the air flow. Its blades feature a symmetrical airfoil with its plane of symmetry in the plane of rotation and perpendicular to the air stream.

It was developed for use in Oscillating Water Column wave power plants, in which a rising and falling water surface moving in an air compression chamber produces an oscillating air current. The use of this bidirectional turbine avoids the need to rectify the air stream by delicate and expensive check valve systems.

Its efficiency is lower than that of a turbine with constant air stream direction and asymmetric airfoil. One reason for the lower efficiency is that symmetric airfoils have a higher drag coefficient than asymmetric ones, even under optimal conditions. Also, in the Wells turbine, the symmetric airfoil runs partly under high angle of attack (i.e., low blade speed / air speed ratio), which occurs during the air velocity maxima of the oscillating flow. A high angle of attack causes a condition known as "stall" in which the airfoil loses lift. The efficiency of the Wells turbine in oscillating flow reaches values between 0.4 and 0.7.

The Wells turbine was developed by Prof. Alan Arthur Wells of Queen's University Belfast in the late 1970s.

Annotation

[edit]

Another solution of the problem of stream direction independent turbine is the Darrieus wind turbine (Darrieus rotor).

See also

[edit]
[edit]