2008
DOI: 10.1063/1.2896285
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Effect of heat release on turbulence and scalar-turbulence interaction in premixed combustion

Abstract: Stereoscopic particle image velocimetry and planar laser induced fluorescence measurements of hydroxyl radical are simultaneously applied to measure, respectively, local turbulence intensities and flame front position in premixed ethylene-air flames stabilized on a bluff body. Three different equivalence ratios, 0.55, 0.63, and 0.7, and three different Reynolds numbers, 14 000, 17 000, and 21 000, are considered. Laser measurements were made for five different flame configurations within the ranges above and i… Show more

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Cited by 110 publications
(100 citation statements)
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“…negative) principal strain rate respectively and θ α , θ β and θ γ are angles between ∇c and the eigenvectors associated with e α ,e β and e γ respectively. It was demonstrated earlier [50][51][52] that ∇c aligns collinearly with the eigenvector direction corresponding to e γ in the region with weak heat release, but this alignment changes to the direction corresponding to e α in the region with strong heat release, in which case the strain rate induced by flame normal acceleration overcomes background turbulent straining [50,51]. According to Eq.…”
Section: Resultsmentioning
confidence: 99%
“…negative) principal strain rate respectively and θ α , θ β and θ γ are angles between ∇c and the eigenvectors associated with e α ,e β and e γ respectively. It was demonstrated earlier [50][51][52] that ∇c aligns collinearly with the eigenvector direction corresponding to e γ in the region with weak heat release, but this alignment changes to the direction corresponding to e α in the region with strong heat release, in which case the strain rate induced by flame normal acceleration overcomes background turbulent straining [50,51]. According to Eq.…”
Section: Resultsmentioning
confidence: 99%
“…1. This is described in detail by Balachandran et al [5,6], and has featured in other studies of turbulent flames [41,42,43,44]. A long tube emerges from a plenum chamber, within which is a conical bluff body with diameter d = 25mm.…”
Section: Experimental Test Casementioning
confidence: 99%
“…At the inlet, the velocity is imposed in the form of Eq.(11). In the experiments, the time-averaged bulk velocity entering the combustor was V b = 9.9m/s, giving a Reynolds number Re = dV b /ν = 17000 [44]. Forcing was via pulsing of the flow upstream of the combustor by loudspeakers, such that a single frequency harmonic velocity is superimposed on the mean flow.…”
Section: Methodsmentioning
confidence: 99%
“…These situations are schematically shown in Figure 1, and this change is because of the fact that the dilatation due to heat release is strong compared to the turbulent strain rate. Evidence for such a behaviour has been found in direct numerical simulation (DNS) studies of statistically planar [16][17][18][19][20]22], spherically symmetric [25], and Bunsen [26] flames and also experimental bluff body stabilised flames [27]. As a consequence, the isoscalar surfaces are brought together by the compressive strain resulting in an increase of scalar gradient when the reaction is passive.…”
Section: Physics Of Reactive Scalar Mixingmentioning
confidence: 85%