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[[Image:Vortex-street-animation.gif|frame|right|Vortex shedding behind a circular cylinder. In this animation, the flow on the two sides of the cylinder are shown in different colors, to show that the vortices from the two sides alternate. Courtesy, Cesareo de La Rosa Siqueira.]] | |||
In [[fluid dynamics]], '''vortex shedding''' is an oscillating [[Fluid dynamics|flow]] that takes place when a fluid such as air or water flows past a cylindrical body at certain velocities, depending on the size and shape of the body. In this flow, [[Vortex|vortices]] are created at the back of the body and detach periodically from either side of the body. See [[Von Kármán vortex street]]. The fluid flow past the object creates alternating low-pressure [[Vortex|vortices]] on the downstream side of the object. The object will tend to move toward the low-pressure zone. | |||
If the cylindrical structure is not mounted rigidly and the frequency of vortex shedding matches the [[Resonance|resonance frequency]] of the structure, the structure can begin to [[resonate]], vibrating with [[Harmonic oscillator|harmonic oscillations]] driven by the energy of the flow. This vibration is the cause of the "singing" of overhead power line wires in a wind, and the fluttering of automobile [[Whip antenna|whip radio antennas]] at some speeds. Tall [[chimneys]] constructed of thin-walled steel tube can be sufficiently flexible that, in air flow with a speed in the critical range, vortex shedding can drive the chimney into violent oscillations that can damage or destroy the chimney. These chimneys can be protected from this phenomenon by installing a series of fences (sometimes called strakes or spoilers) at the top and running down the exterior of the chimney for approximately 20% of its length. The fences are usually located in a helical pattern. The fences prevent strong vortex shedding with low separation frequencies. The optimal pitch for vortex shedding is a 5D pitch (5 x the diameter of the stack). | |||
Vortex shedding was one of the causes proposed for the failure of the original [[Tacoma Narrows Bridge (1940)|Tacoma Narrows Bridge]] (Galloping Gertie) in 1940, but was rejected because the frequency of the vortex shedding did not match that of the bridge. The bridge actually failed by [[aeroelasticity#Flutter|aeroelastic flutter]].<ref>K. Billah and R. Scanlan (1991), ''Resonance, Tacoma Narrows Bridge Failure, and Undergraduate Physics Textbooks'', [[American Journal of Physics]], 59(2), 118--124 [http://www.ketchum.org/billah/Billah-Scanlan.pdf (PDF)]</ref> | |||
A thrill ride, "[[VertiGo (ride)|VertiGo]]" at [[Cedar Point]] in [[Sandusky, Ohio]] suffered vortex shedding during the winter of 2001, causing one of the three towers to collapse. The ride was closed for the winter at the time.<ref>{{cite web | url=http://www.tms.org/pubs/journals/JOM/0205/Byko-0205.html | title=Materials Give Roller Coaster Enthusiasts a Reason to Scream | author=Maureen Byko | publisher=The Minerals, Metals & Materials Society | date=May 2002 | accessdate=2009-02-22 }}</ref> | |||
== Governing equation == | |||
The frequency at which vortex shedding takes place for a cylinder is related to the Strouhal number by the following equation: | |||
:<math>\mathrm{St} = \frac{fD}{V}</math> | |||
Where <math>\mathrm{St}</math> is the [[Strouhal number]], <math>f</math> is the vortex shedding frequency, <math>D</math> is the diameter of the cylinder, and <math>V</math> is the flow velocity. | |||
The Strouhal number depends on the body shape and on the [[Reynolds number]]. | |||
== Mitigation of vortex shedding effects == | |||
Modern tall smokestacks usually have a corkscrew fin (a [[strake (aviation)|strake]]) to deliberately introduce turbulence, so that the load is less variable and resonant load frequencies have negligible amplitudes.<ref>{{cite web | url=http://www.mms.gov/tarprojects/485/Session3aVIVApplicationstoDeepwaterPipelines-BrownFile1%20.pdf | title= VIV Lecture | author = R. J. Brown }}</ref> | |||
A [[Stockbridge damper]] is used to mitigate [[aeolian vibration]]s caused by vortex shedding on [[overhead power line]]s. | |||
== See also == | |||
* [[Aeroelasticity#Flutter|Aeroelastic Flutter]] - vibration-induced vortices - by way of contrast | |||
* [[Vortex]] | |||
* [[Vortex induced vibration]] | |||
* [[Von Kármán vortex street]] | |||
==References== | |||
{{Reflist}} | |||
== External links == | |||
* [http://www.tech.plym.ac.uk/sme/Interactive_Resources/tutorials/FailureCases/sf1.html Failure of the Tacoma Narrows Bridge] | |||
* [http://mecaenterprises.com/stack_vibration/vortex_shedding Another explanation of vortex shedding] (includes a helpful diagram) | |||
* [http://www.civeng.carleton.ca/Exhibits/Tacoma_Narrows/ A movie of the Tacoma Narrows Bridge failure] | |||
* [http://www.youtube.com/watch?v=_AJgEa2dbJU Flow visualisation of the vortex shedding mechanism on circular cylinder using hydrogen bubbles illuminated by a laser sheet in a water channel. Courtesy of G.R.S. Assi.] | |||
[[Category:Vortices]] | |||
[[Category:Fluid dynamics]] |
Revision as of 17:41, 28 January 2014
In fluid dynamics, vortex shedding is an oscillating flow that takes place when a fluid such as air or water flows past a cylindrical body at certain velocities, depending on the size and shape of the body. In this flow, vortices are created at the back of the body and detach periodically from either side of the body. See Von Kármán vortex street. The fluid flow past the object creates alternating low-pressure vortices on the downstream side of the object. The object will tend to move toward the low-pressure zone.
If the cylindrical structure is not mounted rigidly and the frequency of vortex shedding matches the resonance frequency of the structure, the structure can begin to resonate, vibrating with harmonic oscillations driven by the energy of the flow. This vibration is the cause of the "singing" of overhead power line wires in a wind, and the fluttering of automobile whip radio antennas at some speeds. Tall chimneys constructed of thin-walled steel tube can be sufficiently flexible that, in air flow with a speed in the critical range, vortex shedding can drive the chimney into violent oscillations that can damage or destroy the chimney. These chimneys can be protected from this phenomenon by installing a series of fences (sometimes called strakes or spoilers) at the top and running down the exterior of the chimney for approximately 20% of its length. The fences are usually located in a helical pattern. The fences prevent strong vortex shedding with low separation frequencies. The optimal pitch for vortex shedding is a 5D pitch (5 x the diameter of the stack).
Vortex shedding was one of the causes proposed for the failure of the original Tacoma Narrows Bridge (Galloping Gertie) in 1940, but was rejected because the frequency of the vortex shedding did not match that of the bridge. The bridge actually failed by aeroelastic flutter.[1]
A thrill ride, "VertiGo" at Cedar Point in Sandusky, Ohio suffered vortex shedding during the winter of 2001, causing one of the three towers to collapse. The ride was closed for the winter at the time.[2]
Governing equation
The frequency at which vortex shedding takes place for a cylinder is related to the Strouhal number by the following equation:
Where is the Strouhal number, is the vortex shedding frequency, is the diameter of the cylinder, and is the flow velocity.
The Strouhal number depends on the body shape and on the Reynolds number.
Mitigation of vortex shedding effects
Modern tall smokestacks usually have a corkscrew fin (a strake) to deliberately introduce turbulence, so that the load is less variable and resonant load frequencies have negligible amplitudes.[3]
A Stockbridge damper is used to mitigate aeolian vibrations caused by vortex shedding on overhead power lines.
See also
- Aeroelastic Flutter - vibration-induced vortices - by way of contrast
- Vortex
- Vortex induced vibration
- Von Kármán vortex street
References
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External links
- Failure of the Tacoma Narrows Bridge
- Another explanation of vortex shedding (includes a helpful diagram)
- A movie of the Tacoma Narrows Bridge failure
- Flow visualisation of the vortex shedding mechanism on circular cylinder using hydrogen bubbles illuminated by a laser sheet in a water channel. Courtesy of G.R.S. Assi.
- ↑ K. Billah and R. Scanlan (1991), Resonance, Tacoma Narrows Bridge Failure, and Undergraduate Physics Textbooks, American Journal of Physics, 59(2), 118--124 (PDF)
- ↑ Template:Cite web
- ↑ Template:Cite web