Computation fluid dynamics on drag reduction II
Concentrated research activities are done on drag reduction and one of the main subjects being investigated frequently is the presence of dimple on rigid surfaces. Both the nature of flow and the advantage of drag reduction embedded within have been studied by Isaev et al. (2000) & A.M Cary (...
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sg-ntu-dr.10356-461602023-03-04T18:31:51Z Computation fluid dynamics on drag reduction II Zang, Bin Jorg Uwe Schluter School of Mechanical and Aerospace Engineering DRNTU::Engineering::Aeronautical engineering::Aerodynamics Concentrated research activities are done on drag reduction and one of the main subjects being investigated frequently is the presence of dimple on rigid surfaces. Both the nature of flow and the advantage of drag reduction embedded within have been studied by Isaev et al. (2000) & A.M Cary (1979) [7][11] have been studied with experiments and computational fluid dynamics. In this project, a number of Reynolds-Average Navier-Stokes (RANS) models are verified with benchmark values of Direct Numerical Solutions (DNS) provided by the past research to identify appropriate RANS models which allow the simulation of dimpled flow with specific Reynolds number and initial conditions in a 3D channel. Five RANS turbulence models: Spalart-Allmaras (Vorticity-based production); Spalart-Allmaras (Strain / Vorticity-based production); k-ε Standard (Enhanced Wall Treatment); k-ε Realizable (Enhanced Wall Treatment) and k-ω Standard (Shear Flow Correction), are chosen after comparing with DNS data published by Moser et al (1999). [20] Subsequently, the single and multiple dimpled channel flows are modeled and simulated by the five RANS models chosen in the verification stage with periodic boundary condition, a Reynolds number of 20000, and a three-dimensional channel of L = 1.5 m, B = 0.454 m and H = 1 m. Both the flow pattern in the form of velocity contours and the quantitative drag coefficient are extracted and compared in several ways: single dimple along the wall with depth (h/D = 0.21); multiple (three) dimples along the wall with different separation distances between adjacent dimples; single dimple but with several other h/D ratios (i.e. 0.25, 0.14, 0.10, 0.08). The post-processed results reveal the wide existence of reversal flow as an eddy current that contributes to the reduction of viscous drag on the surface. However, the induced pressure drag exerts great adverse effects on drag reduction capability and efficacy of dimpled surface. Several useful observations and inferences are made through the investigation process, such as smaller separation distance between dimples facilitate the drag reduction mechanisms. Lastly, the grid size and RANS models are subjected to further verification to ensure the observations and calculations are indeed trustworthy and relatively accurate by studying skin friction coefficient and comparing to empirical formula; also by simulating more complex dimpled flow with different Reynolds number regimes. The result establishes agreements in friction coefficient while the simulation of complex flow doe s not. Further work can be done to optimize dimple separation distance or h/D ratio under certain Reynolds number by RANS. Bachelor of Engineering (Aerospace Engineering) 2011-06-29T07:35:35Z 2011-06-29T07:35:35Z 2011 2011 Final Year Project (FYP) http://hdl.handle.net/10356/46160 en Nanyang Technological University 86 p. application/pdf |
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DRNTU::Engineering::Aeronautical engineering::Aerodynamics Zang, Bin Computation fluid dynamics on drag reduction II |
| description |
Concentrated research activities are done on drag reduction and one of the main subjects being
investigated frequently is the presence of dimple on rigid surfaces. Both the nature of flow and
the advantage of drag reduction embedded within have been studied by Isaev et al. (2000) & A.M
Cary (1979) [7][11] have been studied with experiments and computational fluid dynamics.
In this project, a number of Reynolds-Average Navier-Stokes (RANS) models are verified with
benchmark values of Direct Numerical Solutions (DNS) provided by the past research to identify
appropriate RANS models which allow the simulation of dimpled flow with specific Reynolds
number and initial conditions in a 3D channel. Five RANS turbulence models: Spalart-Allmaras
(Vorticity-based production); Spalart-Allmaras (Strain / Vorticity-based production); k-ε Standard
(Enhanced Wall Treatment); k-ε Realizable (Enhanced Wall Treatment) and k-ω Standard (Shear
Flow Correction), are chosen after comparing with DNS data published by Moser et al (1999). [20]
Subsequently, the single and multiple dimpled channel flows are modeled and simulated by the
five RANS models chosen in the verification stage with periodic boundary condition, a Reynolds
number of 20000, and a three-dimensional channel of L = 1.5 m, B = 0.454 m and H = 1 m. Both
the flow pattern in the form of velocity contours and the quantitative drag coefficient are
extracted and compared in several ways: single dimple along the wall with depth (h/D = 0.21);
multiple (three) dimples along the wall with different separation distances between adjacent
dimples; single dimple but with several other h/D ratios (i.e. 0.25, 0.14, 0.10, 0.08). The
post-processed results reveal the wide existence of reversal flow as an eddy current that
contributes to the reduction of viscous drag on the surface. However, the induced pressure drag
exerts great adverse effects on drag reduction capability and efficacy of dimpled surface. Several
useful observations and inferences are made through the investigation process, such as smaller
separation distance between dimples facilitate the drag reduction mechanisms.
Lastly, the grid size and RANS models are subjected to further verification to ensure the
observations and calculations are indeed trustworthy and relatively accurate by studying skin
friction coefficient and comparing to empirical formula; also by simulating more complex
dimpled flow with different Reynolds number regimes. The result establishes agreements in
friction coefficient while the simulation of complex flow doe s not. Further work can be done to
optimize dimple separation distance or h/D ratio under certain Reynolds number by RANS. |
| author2 |
Jorg Uwe Schluter |
| author_facet |
Jorg Uwe Schluter Zang, Bin |
| format |
Final Year Project |
| author |
Zang, Bin |
| author_sort |
Zang, Bin |
| title |
Computation fluid dynamics on drag reduction II |
| title_short |
Computation fluid dynamics on drag reduction II |
| title_full |
Computation fluid dynamics on drag reduction II |
| title_fullStr |
Computation fluid dynamics on drag reduction II |
| title_full_unstemmed |
Computation fluid dynamics on drag reduction II |
| title_sort |
computation fluid dynamics on drag reduction ii |
| publishDate |
2011 |
| url |
http://hdl.handle.net/10356/46160 |
| _version_ |
1759858302396661760 |