2006
DOI: 10.2140/camcos.2006.1.29
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Active control for statistically stationary turbulent premixed flame simulations

Abstract: The speed of propagation of a premixed turbulent flame correlates with the intensity of the turbulence encountered by the flame. One consequence of this property is that premixed flames in both laboratory experiments and practical combustors require some type of stabilization mechanism to prevent blow-off and flashback. The stabilization devices often introduce a level of geometric complexity that is prohibitive for detailed computational studies of turbulent flame dynamics. Furthermore, the stabilization intr… Show more

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Cited by 46 publications
(24 citation statements)
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“…Defining the local speed in this way has the property that the global burning speed is the integral of s l T over the isosurface. For additional details about construction of the elements , see Bell et al (2006) and Day et al (2008). Figure 8 compares instantaneous temperature and carbon isosurfaces for case (b) and is colored by the integrated fuel consumption rate, s l T .…”
Section: Resultsmentioning
confidence: 99%
“…Defining the local speed in this way has the property that the global burning speed is the integral of s l T over the isosurface. For additional details about construction of the elements , see Bell et al (2006) and Day et al (2008). Figure 8 compares instantaneous temperature and carbon isosurfaces for case (b) and is colored by the integrated fuel consumption rate, s l T .…”
Section: Resultsmentioning
confidence: 99%
“…Diffusion and chemical kinetics, which occur on time scales faster than advection, are treated time-implicitly. An automatic feedback control algorithm [25,34] adjusts the inflow velocity to stabilize the flame in the computational domain. This integration scheme is embedded in a parallel adaptive mesh refinement framework based on a hierarchical system of rectangular grid patches [35].…”
Section: Computational Methodologymentioning
confidence: 99%
“…Example laminar fluid-flame interaction studies include experimental validation and analyses of the interaction of single vortical structures with a rich methane-air flame [37]. In [25,38], the control algorithm discussed above was presented and used to explore the response of methaneair flames in the presence of turbulence, based on the detailed chemistry and transport models in the GRI-Mech 3.0 mechanism [39]. A two-dimensional controlled hydrogen flame in the turbulence/chemistry regime of the present work was analyzed extensively in [26].…”
Section: Computational Methodologymentioning
confidence: 99%
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“…The fine grid resolution is therefore 78.125 (micron). The flame evolves over 0.05 (sec) during which it is steadied at y = 2.0 (cm) using the control algorithm discussed in [1]. Figure 1 displays the mole fractions of the species with respect to distance along the y axis.…”
Section: D Problemmentioning
confidence: 99%