Boundary layer effects on the vortex shedding in a Donaldson- type hydrofoil
Fluid - Structure Interaction (FSI) phenomena is becoming a relevant study field for the design or revamping of hydropower plants. The generalized trend of increasing flow rates and reducing rotor blades/stay vanes thickness in order to improve the efficiency of the machine together with a major pus...
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| Veröffentlicht in: | IOP conference series. Earth and environmental science 2014-01, Vol.22 (3), p.32045-32050 |
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| creator | Fontanals, A Guardo, A Zobeiri, A Egusquiza, E Farhat, M Avellan, F |
| description | Fluid - Structure Interaction (FSI) phenomena is becoming a relevant study field for the design or revamping of hydropower plants. The generalized trend of increasing flow rates and reducing rotor blades/stay vanes thickness in order to improve the efficiency of the machine together with a major push from plant owners/operators for production flexibility (partial load operation is more common nowadays) make the FSI between the vortex shedding phenomenon and the vanes/blades of the machine an area of interest. From a design point of view, the machine structure has to resist all the hydrodynamic forces generated and maintain tension stresses under the fatigue limit to ensure a machine lifetime of several decades. To accomplish that goal, designers have to assure there is no presence of strong coupling phenomena (lock-in) between the vortex shedding frequency and the eigenfrequencies of the structure. As the vortex street is directly related to the state of the boundary layer along the hydrofoil, in this paper the effect of the boundary layer on the vortex shedding in a Donaldson-type hydrofoil is studied using Computational Fluid Dynamics (CFD). The development of the boundary layer along the Donaldson trailing edge hydrofoil chord is presented under lock-off conditions. The results are validated against previously obtained experimental results. Since the Donaldson trailing edge is non-symmetric, the boundary layer velocity profiles are reported for the suction and pressure side of the hydrofoil. In addition, the effect of the Donaldson trailing edge on laminar-to-turbulent transition on both sides of the hydrofoil is studied. |
| doi_str_mv | 10.1088/1755-1315/22/3/032045 |
| format | Article |
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The generalized trend of increasing flow rates and reducing rotor blades/stay vanes thickness in order to improve the efficiency of the machine together with a major push from plant owners/operators for production flexibility (partial load operation is more common nowadays) make the FSI between the vortex shedding phenomenon and the vanes/blades of the machine an area of interest. From a design point of view, the machine structure has to resist all the hydrodynamic forces generated and maintain tension stresses under the fatigue limit to ensure a machine lifetime of several decades. To accomplish that goal, designers have to assure there is no presence of strong coupling phenomena (lock-in) between the vortex shedding frequency and the eigenfrequencies of the structure. As the vortex street is directly related to the state of the boundary layer along the hydrofoil, in this paper the effect of the boundary layer on the vortex shedding in a Donaldson-type hydrofoil is studied using Computational Fluid Dynamics (CFD). The development of the boundary layer along the Donaldson trailing edge hydrofoil chord is presented under lock-off conditions. The results are validated against previously obtained experimental results. Since the Donaldson trailing edge is non-symmetric, the boundary layer velocity profiles are reported for the suction and pressure side of the hydrofoil. In addition, the effect of the Donaldson trailing edge on laminar-to-turbulent transition on both sides of the hydrofoil is studied.</description><identifier>ISSN: 1755-1307</identifier><identifier>EISSN: 1755-1315</identifier><identifier>DOI: 10.1088/1755-1315/22/3/032045</identifier><language>eng</language><publisher>Bristol: IOP Publishing</publisher><subject>Boundary layer ; Boundary layers ; Computational fluid dynamics ; Computer applications ; Design ; Fatigue limit ; Flow rates ; Flow velocity ; Fluid dynamics ; Fluid flow ; Hydrodynamics ; Hydroelectric plants ; Hydroelectric power ; Hydrofoils ; Loads (forces) ; Resonant frequencies ; Rotor blades ; Suction ; Trailing edges ; Vanes ; Velocity distribution ; Vortex shedding ; Vortices</subject><ispartof>IOP conference series. Earth and environmental science, 2014-01, Vol.22 (3), p.32045-32050</ispartof><rights>2014. This work is published under http://creativecommons.org/licenses/by/3.0/ (the “License”). 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Earth and environmental science</title><description>Fluid - Structure Interaction (FSI) phenomena is becoming a relevant study field for the design or revamping of hydropower plants. The generalized trend of increasing flow rates and reducing rotor blades/stay vanes thickness in order to improve the efficiency of the machine together with a major push from plant owners/operators for production flexibility (partial load operation is more common nowadays) make the FSI between the vortex shedding phenomenon and the vanes/blades of the machine an area of interest. From a design point of view, the machine structure has to resist all the hydrodynamic forces generated and maintain tension stresses under the fatigue limit to ensure a machine lifetime of several decades. To accomplish that goal, designers have to assure there is no presence of strong coupling phenomena (lock-in) between the vortex shedding frequency and the eigenfrequencies of the structure. As the vortex street is directly related to the state of the boundary layer along the hydrofoil, in this paper the effect of the boundary layer on the vortex shedding in a Donaldson-type hydrofoil is studied using Computational Fluid Dynamics (CFD). The development of the boundary layer along the Donaldson trailing edge hydrofoil chord is presented under lock-off conditions. The results are validated against previously obtained experimental results. Since the Donaldson trailing edge is non-symmetric, the boundary layer velocity profiles are reported for the suction and pressure side of the hydrofoil. 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Earth and environmental science</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Fontanals, A</au><au>Guardo, A</au><au>Zobeiri, A</au><au>Egusquiza, E</au><au>Farhat, M</au><au>Avellan, F</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Boundary layer effects on the vortex shedding in a Donaldson- type hydrofoil</atitle><jtitle>IOP conference series. Earth and environmental science</jtitle><date>2014-01-01</date><risdate>2014</risdate><volume>22</volume><issue>3</issue><spage>32045</spage><epage>32050</epage><pages>32045-32050</pages><issn>1755-1307</issn><eissn>1755-1315</eissn><abstract>Fluid - Structure Interaction (FSI) phenomena is becoming a relevant study field for the design or revamping of hydropower plants. 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| subjects | Boundary layer Boundary layers Computational fluid dynamics Computer applications Design Fatigue limit Flow rates Flow velocity Fluid dynamics Fluid flow Hydrodynamics Hydroelectric plants Hydroelectric power Hydrofoils Loads (forces) Resonant frequencies Rotor blades Suction Trailing edges Vanes Velocity distribution Vortex shedding Vortices |
| title | Boundary layer effects on the vortex shedding in a Donaldson- type hydrofoil |
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