Flame Surface Densities in Premixed Combustion at Medium to High Turbulence Intensities

Gülder, Ömer L.; Smallwood, Gregory J.

doi:10.1080/00102200600808722

Cited by 39 publications

(24 citation statements)

References 41 publications

(60 reference statements)

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“…In addition, it can be seen from the Fig.7 the maximum flame area density does not change with the increase in turbulence intensity. This result is consistent with those found by (Gülder and Smallwood 2007), who studied the flame area density in a premixed turbulent flame at a vast level of turbulence intensity in a Bunsen burner and concluded that the maximum flame surface density does not vary with turbulence intensity.…”

Section: Flame Area Densitysupporting

confidence: 82%

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Effects of turbulence intensity and length scale on the flame location of premixed turbulent combustion in a diffuser combustor

Nazzal

Ertunç

2017

JTST

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This study focused on the dependency of the flame location of a premixed propane-air flame on turbulence intensity and length scale. The flame location was investigated using a diffuser-type combustor to show the response of the flame location to varying turbulence intensities and length scales without changing the mixture velocity, i.e., the thermal power. Combustion simulations were conducted using a coherent flame model within the framework of Reynolds-averaged Navier-Stokes equations under unsteady state conditions. The flame generally moved toward the combustor inlet with increases in turbulence intensity and length scale. The combustion and inlet turbulence caused a flow separation mainly downstream of the flame front. Consequently, the secondary flow structures influenced the flame topology and location.

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Section: Flame Area Densitysupporting

confidence: 82%

“…(Gülder and Smallwood 2007) studied the flame area density in a premixed turbulent flame at the vast level of turbulence intensities and found that turbulence affects the flame area density. In addition, the maximum flame surface density does not vary with the turbulence intensity.…”

Section: Introductionmentioning

confidence: 99%

Effects of turbulence intensity and length scale on the flame location of premixed turbulent combustion in a diffuser combustor

Nazzal

Ertunç

2017

JTST

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“…This may result in an increase in the turbulent burning velocity due to an increase in flame surface wrinkling. This hypothesis is supported by the experimental data showing that the turbulent burning velocity increases with increasing bulk flow velocity, see, e.g., [4,13,14]. However, the observed trend may not be solely due to the effect of bulk flow velocity since the total turbulence intensity increases simultaneously with the bulk flow velocity in these experiments.…”

Section: Introductionmentioning

confidence: 50%

Flame brush characteristics and burning velocities of premixed turbulent methane/air Bunsen flames

Tamadonfar

Gülder

2014

Combustion and Flame

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“…12 Flame-front segments (white) of sample image in Fig. 6 Shepherd and Cheng 2001;Haq et al 2002;Gülder and Smallwood 2007;Petersson et al 2007;Kiefer et al 2008). This technique has also been applied to flows seeded with either oil droplets (Shepherd et al 1992;Veynante et al 1994;Shepherd 1996) or solid particles (Pfadler et al 2005;Pfadler et al 2007) where planar imaging is used to determine the reactant region and hence the flame-front.…”

Section: Filter Comparisonmentioning

confidence: 98%

Local curvature measurements of a lean, partially premixed swirl-stabilised flame

2011

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A swirl-stabilised, lean, partially premixed combustor operating at atmospheric conditions has been used to investigate the local curvature distributions in lifted, stable and thermoacoustically oscillating CH 4 -air partially premixed flames for bulk cold-flow Reynolds numbers of 15,000 and 23,000. Single-shot OH planar laser-induced fluorescence has been used to capture instantaneous images of these three different flame types. Use of binary thresholding to identify the reactant and product regions in the OH planar laser-induced fluorescence images, in order to extract accurate flame-front locations, is shown to be unsatisfactory for the examined flames. The Canny-Deriche edge detection filter has also been examined and is seen to still leave an unacceptable quantity of artificial flame-fronts. A novel approach has been developed for image analysis where a combination of a non-linear diffusion filter, Sobel gradient and thresholdbased curve elimination routines have been used to extract traces of the flame-front to obtain local curvature distributions. A visual comparison of the effectiveness of flamefront identification is made between the novel approach, the threshold binarisation filter and the Canny-Deriche filter. The novel approach appears to most accurately identify the flame-fronts. Example histograms of the curvature for six flame conditions and of the total image area are presented and are found to have a broader range of local flame curvatures for increasing bulk Reynolds numbers. Significantly positive values of mean curvature and marginally positive values of skewness of the histogram have been measured for one lifted flame case, but this is generally accounted for by the effect of flame brush curvature. The mean local flame-front curvature reduces with increasing axial distance from the burner exit plane for all flame types. These changes are more pronounced in the lifted flames but are marginal for the thermoacoustically oscillating flames. It is concluded that additional fuel mixture fraction and velocimetry studies are required to examine whether processes such as the degree of partial-premixedness close to the burner exit plane, the velocity field and the turbulence field have a strong correlation with the curvature characteristics of the investigated flames.

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Flame Surface Densities in Premixed Combustion at Medium to High Turbulence Intensities

Cited by 39 publications

References 41 publications

Effects of turbulence intensity and length scale on the flame location of premixed turbulent combustion in a diffuser combustor

Effects of turbulence intensity and length scale on the flame location of premixed turbulent combustion in a diffuser combustor

Flame brush characteristics and burning velocities of premixed turbulent methane/air Bunsen flames

Local curvature measurements of a lean, partially premixed swirl-stabilised flame

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