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Keywords
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Channel Flow
Dynamic Model
Large Eddy Simulation
Objective Function
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Turbulent Channel Flow
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Reduction of the Germano-identity error in the dynamic Smagorinsky model
Reduction of the Germano-identity error in the dynamic Smagorinsky model,Noma Park,Krishnan Mahesh
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Reduction of the Germano-identity error in the dynamic Smagorinsky model
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Noma Park
,
Krishnan Mahesh
We revisit the Germano-identity error in the dynamic modeling procedure in the sense that the current modeling procedure to obtain the dynamic coefficient may not truly minimize the error in the mean and global sense. A "corrector step" to the conventional dynamic Smagorinsky model is proposed to obtain a corrected eddy viscosity which further reduces the error. The change in resolved velocity due to the coefficient variation as well as nonlocal nature of the filter and flow unsteadiness is accounted for by a simplified suboptimal control formalism without resorting to the adjoint equations. The
objective function
chosen is the Germano-identity error integrated over the entire computational volume and pathline. In order to determine corrected eddy viscosity, the Fréchet derivative of the
objective function
is directly evaluated by a finite-differencing formula in an efficient predictor-corrector-type framework. The proposed model is applied to decaying isotropic turbulence and
turbulent channel flow
at various Reynolds numbers and resolutions to obtain noticeable reduction in the Germano-identity error and significantly improved flow statistics. From
channel flow
large-eddy simulation, it is shown that conventional
dynamic model
underestimates subgrid scale eddy viscosity when the resolution gets coarse, and this underestimation is responsible for increased anisotropy of predicted Reynolds stress. The proposed model raises both the overall and near-wall subgrid scale eddy viscosity to reduce exaggerated Reynolds stress anisotropy and yield significantly improved flow statistics. © 2009 American Institute of Physics. DOI: 10.1063/1.3140033
Published in 2010.
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References
(21)
DNS-based predictive control of turbulence: an optimal benchmark for feedback algorithms
(
Citations: 123
)
Thomas R. Bewley
,
Parviz Moin
,
Roger Temam
Journal:
Journal of Fluid Mechanics - J FLUID MECH
, vol. 447, pp. 179-225, 2001
A dynamic subgrid-scale eddy viscosity model
(
Citations: 1551
)
Massimo Germano
,
Ugo Piomelli
,
Parviz Moin
,
William H. Cabot
Journal:
Physics of Fluids - PHYS FLUIDS
, vol. 3, pp. 1760-1765, 1991
Turbulence statistics in fully developed channel flow at low Reynolds number
(
Citations: 1241
)
John Kim
,
Parviz Moin
,
Robert Moser
Journal:
Journal of Fluid Mechanics - J FLUID MECH
, vol. 177, no. -1, pp. 133-166, 1987
A proposed modification of the Germano subgrid-scale closure method
(
Citations: 752
)
D. K. Lilly
Published in 1992.
Direct numerical simulation of turbulent channel flow up to Retau=590
(
Citations: 498
)
Robert D. Moser
,
John Kim
,
Nagi N. Mansour
Journal:
Physics of Fluids - PHYS FLUIDS
, vol. 11, pp. 943-945, 1999