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LES of Turbulent Flows : Lecture 5 (ME EN 7960-003)

LES of Turbulent Flows : Lecture 5 (ME EN 7960-003). Prof. Rob Stoll Department of Mechanical Engineering University of Utah Fall 2014. Decomposition of Turbulence for real filters.

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LES of Turbulent Flows : Lecture 5 (ME EN 7960-003)

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  1. LES of Turbulent Flows: Lecture 5(ME EN 7960-003) Prof. Rob Stoll Department of Mechanical Engineering University of Utah Fall 2014

  2. Decomposition of Turbulence for real filters The LES filter can be used to decompose the velocity field into resolved and subfilter scale (SFS) components We can use our filtered DNS fields to look at how the choice of our filter kernel affects this separation in wavespace The Gaussian filter (or box filter) does not have as compact of support in wavespace as the cutoff filter. This results in attenuation of energy at scales larger than the filter scale. The scales affected by this attenuation are referred to as Resolved SFSs. Resolved SFS π/Δ π/Δ SGS scales Resolved scales SGS scales Resolved scales

  3. Equations of Motion • We want to apply our filters to the N-S equations, for incompressible flow (lecture 3): • Conservation of Mass: • -Conservation of Momentum: • -Conservation of Scalar:

  4. Filtering the incompressible N-S equations • What happens when we apply one of the above filters to the N-S equations? • Conservation of Mass: • filtering both sides of the conservation of mass: • where we have used the property of LES filters => and (~) denotes the filtering operation. • -Conservation of Momentum: • Using the filter properties , and we can write the momentum equation as: • The 2nd term on the LHS (convective term) now contains the unknown we can rewrite this term to obtain the standard LES equations for incompressible flow

  5. Filtering the incompressible N-S equations • We can add and subtract from the convective term: • Putting this back in the momentum equation and rearranging we have • where is the subfilter scale (SFS) stress tensor • For the scalar concentration equation we can go through a similar process to obtain: • Where is the SFS flux SFS force vector

  6. LES filtered Equations for incompressible flow • Mass: • Momentum: • Scalar: • SFS stress: • SFS flux: b a • we’ve talked about variance (or energy) when discussing turbulence and filtering • when we examined application of the LES filter at scale Δ we looked at the effect of the filter on the distribution of energy with scale. • A natural way to extend our examination of scale separation and energy is to look at the evolution of the filtered variance or kinetic energy

  7. The filtered kinetic energy equation • filtered kinetic energy equation for incompressible flow • We can define the total filtered kinetic energy by: • -We can decompose this in the standard way by: • The SFS kinetic energy (or residual kinetic energy) can be defined as: • (see Pope pg. 585 or Piomelli et al., Phys Fluids A, 1991) • -The resolved (filtered) kinetic energy is then given by: SFS Kinetic energy Resolved Kinetic energy

  8. The filtered kinetic energy equation • We can develop an equation for by multiplying equation on page 6 by : • Applying the product rule to the terms in the squares: • Using our definition of : b 0 (eqna)

  9. The filtered kinetic energy equation • term : • using squared equation and divide by 2 and multiplying by ν: • term : • Combining everything back together: Product rule Product rule Looks just like (without ν) Uses symmetry of and tensor contraction advection of transport of SFS stress “storage” of pressure transport transport of viscous stress dissipation by viscous stress SFS dissipation

  10. Transfer of energy between resolved and SFSs • The SFS dissipation in the resolved kinetic energy equation is a sink of resolved kinetic energy (it is a source in the equation) and represents the transfer of energy from resolved SFSs. It is equal to: • It is referred to as the SFS dissipation as an analogy to viscous dissipation (and in the inertial subrange = viscous dissipation). • On averagedrains energy (transfers energy • down to smaller scale) from the resolved scales. • Instantaneously (locally) can be positive • or negative. • When is negative (transfer from • SFSResolved scales) it is typically • termed backscatter • -When is positive it is sometimes • referred to as forward scatter. Forward scatter backscatter SGS scales Resolved scales π/Δ

  11. Transfer of energy between resolved and SFSs • Its informative to compare our resolved kinetic energy equation to the mean kinetic energy equation (derived in a similar manner, see Pope pg. 124; Stull 1988 ch. 5) • For high-Re flow, with our filter in the inertial subrange: • - The dominant sink for is Π while for it is (rate of dissipation of energy). • For high-Re flow we therefore have: • Recall from K41, is proportional to the transfer of energy in the inertial subrange • Π will have a strong impact on energy transfer and the shape of the energy spectrum in LES. • - Calculating the correct average Π is another necessary (but not sufficient) condition for an LES SFS model (to go with our N-S invariance properties from Lecture 7).

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