On the design of optimal compliant walls for turbulence control
On the design of optimal compliant walls for turbulence control
This paper employs the resolvent framework to consider the design of compliant walls for turbulent skin friction reduction. Specifically, the effects of simple spring–damper walls are contrasted with the effects of more complex walls incorporating tension, stiffness and anisotropy. In addition, varying mass ratios are tested to provide insight into differences between aerodynamic and hydrodynamic applications. Despite the differing physical responses, all the walls tested exhibit some important common features. First, the effect of the walls (positive or negative) is the greatest at conditions close to resonance, with sharp transitions in performance across the resonant frequency or phase speed. Second, compliant walls are predicted to have a more pronounced effect on slower moving structures because such structures generally have larger wall-pressure signatures. Third, two-dimensional (spanwise constant) structures are particularly susceptible to further amplification. These features are consistent with many previous experiments and simulations, suggesting that mitigating the rise of such two-dimensional structures is essential to designing performance-improving walls. For instance, it is shown that further amplification of such large-scale two-dimensional structures explains why the optimal anisotropic walls identified in previous direct numerical simulations only led to drag reduction in very small domains. The above observations are used to develop design and methodology guidelines for future research on compliant walls.
787-806
Luhar, M.
7972fd0e-2eb8-4c6d-aac0-8ef9b0540cff
Sharma, A.S.
cdd9deae-6f3a-40d9-864c-76baf85d8718
McKeon, B.J.
2e685015-292a-42a7-8c9e-7cc27cf2da67
Luhar, M.
7972fd0e-2eb8-4c6d-aac0-8ef9b0540cff
Sharma, A.S.
cdd9deae-6f3a-40d9-864c-76baf85d8718
McKeon, B.J.
2e685015-292a-42a7-8c9e-7cc27cf2da67
Luhar, M., Sharma, A.S. and McKeon, B.J.
(2016)
On the design of optimal compliant walls for turbulence control.
Journal of Turbulence, 17 (8), .
(doi:10.1080/14685248.2016.1181267).
Abstract
This paper employs the resolvent framework to consider the design of compliant walls for turbulent skin friction reduction. Specifically, the effects of simple spring–damper walls are contrasted with the effects of more complex walls incorporating tension, stiffness and anisotropy. In addition, varying mass ratios are tested to provide insight into differences between aerodynamic and hydrodynamic applications. Despite the differing physical responses, all the walls tested exhibit some important common features. First, the effect of the walls (positive or negative) is the greatest at conditions close to resonance, with sharp transitions in performance across the resonant frequency or phase speed. Second, compliant walls are predicted to have a more pronounced effect on slower moving structures because such structures generally have larger wall-pressure signatures. Third, two-dimensional (spanwise constant) structures are particularly susceptible to further amplification. These features are consistent with many previous experiments and simulations, suggesting that mitigating the rise of such two-dimensional structures is essential to designing performance-improving walls. For instance, it is shown that further amplification of such large-scale two-dimensional structures explains why the optimal anisotropic walls identified in previous direct numerical simulations only led to drag reduction in very small domains. The above observations are used to develop design and methodology guidelines for future research on compliant walls.
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On the design of optimal compliant walls for turbulence.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 10 April 2016
e-pub ahead of print date: 9 June 2016
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 396790
URI: http://eprints.soton.ac.uk/id/eprint/396790
ISSN: 1468-5248
PURE UUID: 0220cd22-36a8-4f8e-9271-dcfc0d30b96a
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Date deposited: 14 Jun 2016 11:29
Last modified: 15 Mar 2024 05:39
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Contributors
Author:
M. Luhar
Author:
A.S. Sharma
Author:
B.J. McKeon
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