In this paper an axisymmetric RANS simulation of a bluff-body stabilized flame has been attempted using
steady and unsteady flamelet models. The unsteady effects are considered in a postprocessing manner through
the Eulerian particle flamelet model (EPFM). In this model the transient history of scalar dissipation rate, conditioned
by stoichiometric mixture fraction, is required to generate unsteady flamelets and is obtained by tracing
Eulerian particles. In this approach unsteady convective–diffusive transport equations are solved to consider the
transport of Eulerian particles in the domain. Comparisons of the results of steady and unsteady calculations show
that transient effects do not have much influence on major species, including OH, and the structure of the flame
therefore can be successfully predicted by steady or unsteady approaches. However, it appears that slow processes
such as NO formation can only be captured accurately if unsteady effects are taken into account, while steady
simulations tend to overpredict NO. In this work turbulence has been modeled using the Reynolds stress model.
Predictions of velocity, velocity rms, mean mixture fraction, and its rms show very good agreement with experiments.
Performance of three detailed chemical mechanisms, the GRI Mech 2.11, the San Diego mechanism, and
the GRI Mech 3.0, has also been evaluated in this study. All three mechanisms performed well with both steady
and unsteady approaches and produced almost identical results for major species and OH. However, the difference
between mechanisms and flamelet models becomes clearly apparent in the NO predictions. The unsteady model
incorporating the GRI Mech 2.11 provided better predictions of NO than steady calculations and showed close
agreement with experiments. The other two mechanisms showed overpredictions of NO with both unsteady and
steady models. The level of overprediction is severe with the steady approach. GRI Mech 3.0 appears to overpredict
NO by a factor of 2 compared to GRI Mech 2.11. The NO predictions by the San Diego mechanism fall
between those of the two GRI mechanisms. The present study demonstrates the success of the EPFM model and
when used with the GRI 2.11 mechanism predicts all flame properties and major and minor species very well, and
most importantly the correct NO levels.
History
School
Mechanical, Electrical and Manufacturing Engineering
Citation
ODEDRA, A. and MALALASEKERA, W., 2007. Eulerian particle flamelet modelling of a bluff-body CH4/H2 flame. Combustion and Flame, 151(3), pp. 512-531