Best Practice Advice AC2-09: Difference between revisions

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==Application Uncertainties==
==Application Uncertainties==
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The flow field in the near field  is  certainly  influenced  by  inlet
conditions. The mean velocity profile  and  fluctuating  component  were
chosen according to the experimental data. However, in the unsteady  LES
calculations the fluctuations were simulated by white noise. This  means
that the fluctuations characteristic for developed turbulent  flow  were
not reproduced at the inlet and this could influence the mixing features
in the near field.  It  is  well  known  that  white  noise  provides  a
fluctuating signal with a very short time scale which is  then  smoothed
at a short distance from the inlet plane. However,  it seems that due to
very low inlet turbulence level the further results in the flame  region
are only weakly influenced by these near field results  as  both  models
analyzed led to reasonable results.
 
==Computational Domain and Boundary Conditions==
==Computational Domain and Boundary Conditions==
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<!--{{Demo_AC_BPA3}}-->

Revision as of 09:39, 30 April 2011


Front Page

Description

Test Data

CFD Simulations

Evaluation

Best Practice Advice

SANDIA Flame D

Application Challenge AC2-09   © copyright ERCOFTAC 2024

Best Practice Advice

Key Fluid Physics

The non-premixed Sandia D flame is an example of a flame in the flamelet regime in which the Kolmogorov scale is significantly larger than the scales characteristic for the combustion process. In this not demanding test case the models based on flamelet assumption should lead to good agreement with experimental data as was shown in the Evaluation section, especially in the region of developed flame. However, more discrepancies were observed in the near field were only mixing of fuel and oxidizer is considered.

Application Uncertainties

The flow field in the near field is certainly influenced by inlet conditions. The mean velocity profile and fluctuating component were chosen according to the experimental data. However, in the unsteady LES calculations the fluctuations were simulated by white noise. This means that the fluctuations characteristic for developed turbulent flow were not reproduced at the inlet and this could influence the mixing features in the near field. It is well known that white noise provides a fluctuating signal with a very short time scale which is then smoothed at a short distance from the inlet plane. However, it seems that due to very low inlet turbulence level the further results in the flame region are only weakly influenced by these near field results as both models analyzed led to reasonable results.

Computational Domain and Boundary Conditions

Discretisation and Grid Resolution

Physical Modelling

Recommendations for Future Work




Contributed by: Andrzej Boguslawski — Technical University of Częstochowa

Front Page

Description

Test Data

CFD Simulations

Evaluation

Best Practice Advice


© copyright ERCOFTAC 2024