A Control Forced Concurrent Precursor Method for LES Inflow

With the increased application of large eddy simulation techniques, the generation of realistic turbulence at inflow boundaries is crucial for the accuracy of a simulation. The Control Forced Concurrent Precursor Method (CFCPM) proposed in this work combines an existing concurrent precursor method a...

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Bibliographic Details
Published inFlow, turbulence and combustion Vol. 102; no. 4; pp. 849 - 864
Main Authors Haywood, John S., Sescu, Adrian
Format Journal Article
LanguageEnglish
Published Dordrecht Springer Netherlands 15.04.2019
Springer Nature B.V
Subjects
Automotive Engineering
Boundary conditions
Boundary layer flow
Control methods
Domains
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Fluid dynamics
Fluid flow
Fluid- and Aerodynamics
Heat and Mass Transfer
High Reynolds number
Inflow
Large eddy simulation
Mathematical analysis
Momentum
Planes
Precursors
Reynolds number
Reynolds stress
Simulation
Stress tensors
Tensors
Turbulence
Turbulent boundary layer
Turbulent flow
Variations
Velocity distribution
Turbulent inflow
Concurrent precursor method
Controlled forcing
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Summary:With the increased application of large eddy simulation techniques, the generation of realistic turbulence at inflow boundaries is crucial for the accuracy of a simulation. The Control Forced Concurrent Precursor Method (CFCPM) proposed in this work combines an existing concurrent precursor method and a mean flow forcing method with a new extension of the controlled forcing method to impose turbulent inflow boundary conditions primarily, although not exclusively, for domains that require periodic boundary conditions. Turbulent inflow boundary conditions are imposed through a region of body forces added to the momentum equations of the main simulation that transfers the precursor simulation into the main domain. Controlled forcing planes, which come into play as body forces added to the momentum equations on planes perpendicular to the flow, located in the precursor simulation, allow for specific Reynolds stress tensors and mean velocities to be imposed. The mean flow controlled forcing method only modifies the mean velocity profiles, leaving the fluctuating velocity field untouched. The proposed fluctuating flow controlled forcing methods extends the application of the original controlled forcing method to multiple fluctuating velocity components and couples their calculation in order to amplify the existing fluctuations present in the precursor flow field so that prescribed anisotropic Reynolds stress tensors can be reproduced. The new method was tested on high Reynolds number turbulent boundary layer flow over a wall-mounted cube and low Reynolds number turbulent boundary layer flow over a backward-facing step. It was found that the new extension of the controlled forcing method reduced the development time for both test cases considered here when compared to not using controlled forcing and only using the original controlled forcing method.
ISSN:1386-6184
1573-1987
DOI:10.1007/s10494-018-9986-3