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Experiments in Fluids

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01-04-2012 | Research Article

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

Authors: Alan E. Bayley, Yannis Hardalupas, Alex M. K. P. Taylor

Published in: Experiments in Fluids | Issue 4/2012

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Abstract

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 CH₄-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 threshold-based 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 flame-front 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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Anselmo-Filho P, Hochgreb S, Barlow RS, Cant RS (2009) Experimental measurements of geometric properties of turbulent stratified flames. Proc Combust Inst 32(2):1763–1770CrossRef

Ayoola BO, Balachandran R, Frank JH, Mastorakos E, Kaminski CF (2006) Spatially resolved heat release rate measurements in turbulent premixed flames. Combust Flame 144(1–2):1–16CrossRef

Bechtel JH, Teets RE (1979) Hydroxyl and its concentration profile in methane-air flames. Appl Opt 18(24):4138–4144CrossRef

Beér JM, Chigier NA (1972) Combustion aerodynamics, 1st edn. Applied Science Publishers Ltd, London

Bingham DC, Gouldin FC, Knaus DA (1998) Crossed-plane laser tomography: direct measurement of the flamelet surface normal. Proc Combust Inst 27(1):77–84

Bonaldo A, Kelman JB (2009) Experimental annular stratified flames characterisation stabilised by weak swirl. Combust Flame 156(4):750–762CrossRef

Boudier T (2011) Edge detection by Canny-Deriche filtering http://imagejdocu.tudor.lu/doku.php?id=plugin:filter:edge_detection:start. Accessed 9/4/2011

Boxx I, Stöhr M, Carter C, Meier W (2010) Temporally resolved planar measurements of transient phenomena in a partially pre-mixed swirl flame in a gas turbine model combustor. Combust Flame 157(8):1510–1525CrossRef

Bradley D, Gaskell PH, Gu XJ, Lawes M, Scott MJ (1998) Premixed turbulent flame instability and NO formation in a lean-burn swirl burner. Combust Flame 115(4):515–538CrossRef

Bray KNC, Cant RS (1991) Some applications of Kolmogorov’s turbulence research in the field of combustion. Proc R Soc: Math Phys Sci Lond A 434(1890):217–240MATHCrossRef

Bray KNC, Libby PA (1994) Recent developments in the BML model of premixed turbulent combustion. In: Libby PA, Williams FA (eds) Turbulent reacting flows. Academic Press, London, pp 115–152

Candel S (2002) Combustion dynamics and control: progress and challenges. Proc Combust Inst 29(1):1–28CrossRef

Candel SM, Poinsot TJ (1990) Flame stretch and the balance equation for the flame area. Combust Sci Tech 70(1):1–15CrossRef

Canny J (1986) A computational approach to edge detection. IEEE Trans Pattern Anal Mach Intell 8(6):679–698CrossRef

Chakraborty N, Cant S (2004) Unsteady effects of strain rate and curvature on turbulent premixed flames in an inflow-outflow configuration. Combust Flame 137(1–2):129–147CrossRef

Chakraborty N, Cant RS (2005) Influence of Lewis number on curvature effects in turbulent premixed flame propagation in the thin reaction zones regime. Phys Fluids 17(10):105105CrossRef

Chen YC (2007) Measurements of flame-front curvature based on Fourier transformation. Combust Theory Model 11(3):333–349MATHCrossRef

Donbar JM, Driscoll JF, Carter CD (2000) Reaction zone structure in turbulent nonpremixed jet flames-from CH-OH PLIF images. Combust Flame 122(1–2):1–19CrossRef

Drake MC, Pitz RW, Lapp M, Fenimore CP, Lucht RP, Sweeney DW, Laurendeau NM (1984) Measurements of superequilibrium hydroxyl concentrations in turbulent nonpremixed flames using saturated fluorescence. Proc Combust Inst 20(1):327–335

Driscoll JF (2008) Turbulent premixed combustion: flamelet structure and its effect on turbulent burning velocities. Prog Energy Combust Sci 34(1):91–134CrossRef

Gashi S, Hult J, Jenkins KW, Chakraborty N, Cant S, Kaminski CF (2005) Curvature and wrinkling of premixed flame kernels-comparisons of OH PLIF and DNS data. Proc Combust Inst 30(1):809–817CrossRef

Gonzalez RC, Woods RE (2002) Digital image processing, 2nd edn. Prentice-Hall, Upper Saddle River, New Jersey

Gu XJ, Haq MZ, Lawes M, Woolley R (2000) Laminar burning velocity and Markstein lengths of methane-air mixtures. Combust Flame 121(1–2):41–58CrossRef

Gülder OL, Smallwood GJ (2007) Flame surface densities in premixed combustion at medium to high turbulence intensities. Combust Sci Tech 179(1):191–206CrossRef

Halter F, Chauveau C, Djebaïli-Chaumeix N, Gökalp I (2005) Characterization of the effects of pressure and hydrogen concentration on laminar burning velocities of methane-hydrogen-air mixtures. Proc Combust Inst 30(1):201–208CrossRef

Haq MZ, Sheppard CGW, Woolley R, Greenhalgh DA, Lockett RD (2002) Wrinkling and curvature of laminar and turbulent premixed flames. Combust Flame 131(1–2):1–15CrossRef

Hardalupas Y, Panoutsos C, Taylor A (2010) Spatial resolution of a chemiluminescence sensor for local heat-release rate and equivalence ratio measurements in a model gas turbine combustor. Exp Fluids 49(4):883–909CrossRef

Hartung G, Hult J, Kaminski CF, Rogerson JW, Swaminathan N (2008) Effect of heat release on turbulence and scalar-turbulence interaction in premixed combustion. Phys Fluids 20(3):035110CrossRef

Hilbert R, Tap F, El-Rabii H, Thévenin D (2004) Impact of detailed chemistry and transport models on turbulent combustion simulations. Prog Energy Combust Sci 30(1):61–117CrossRef

Jenkins KW, Klein M, Chakraborty N, Cant RS (2006) Effects of strain rate and curvature on the propagation of a spherical flame kernel in the thin-reaction-zones regime. Combust Flame 145(1–2):415–434CrossRef

Karpetis AN, Barlow RS (2004) Laser imaging system for determination of three-dimensional scalar gradients in turbulent flames. Opt Lett 29(4):355–357CrossRef

Karpetis AN, Barlow RS (2005) Measurements of flame orientation and scalar dissipation in turbulent partially premixed methane flames. Proc Combust Inst 30(1):665–672CrossRef

Kiefer J, Li ZS, Zetterberg J, Bai XS, Aldén M (2008) Investigation of local flame structures and statistics in partially premixed turbulent jet flames using simultaneous single-shot CH and OH planar laser-induced fluorescence imaging. Combust Flame 154(4):802–818CrossRef

Knaus DA, Gouldin FC, Bingham DC (2002) Assessment of crossed-plane tomography for flamelet surface normal measurements. Combust Sci Tech 174(1):101–135CrossRef

Kostiuk LW, Shepherd IG, Bray KNC (1999) Experimental study of premixed turbulent combustion in opposed streams. Part III-Spatial structure of flames. Combust Flame 118(1–2):129–139

Law CK (2006) Combustion physics. Cambridge University Press, CambridgeCrossRef

Lee TW, North GL, Santavicca DA (1992) Curvature and orientation statistics of turbulent premixed flame fronts. Combust Sci Tech 84(1):121–132CrossRef

Lee TW, Lee JG, Nye DA, Santavicca DA (1993a) Local response and surface properties of premixed flames during interactions with Kármán vortex streets. Combust Flame 94(1–2):146–160CrossRef

Lee TW, North GL, Santavicca DA (1993b) Surface properties of turbulent premixed propane/air flames at various Lewis numbers. Combust Flame 93(4):445–456CrossRef

Lee GG, Huh KY, Kobayashi H (2000) Measurement and analysis of flame surface density for turbulent premixed combustion on a nozzle-type burner. Combust Flame 122(1–2):43–57CrossRef

Lefebvre AH (1998) Gas turbine combustion, 2nd edn. Taylor & Francis, London

Malm H, Sparr G, Hult J, Kaminski CF (2000) Nonlinear diffusion filtering of images obtained by planar laser-induced fluorescence spectroscopy. J Opt Soc Am A 17(12):2148–2156CrossRef

Matalon M (1983) On flame stretch. Combust Sci Tech 31(3):169–181CrossRef

Mokhtarian F, Mackworth A (1986) Scale-based description and recognition of planar curve and two-dimensional shapes. IEEE Trans Pattern Anal Mach Intell 8(1):34–43CrossRef

Najm HN, Paul PH, Mueller CJ, Wyckoff PS (1998) On the adequacy of certain experimental observables as measurements of flame burning rate. Combustion and Flame 113(3):312–332CrossRef

Nguyen Q-V, Paul PH (1996) The time evolution of a vortex-flame interaction observed via planar imaging of CH and OH. Proc Combust Inst 26(1):357–364

Nye DA, Lee JG, Lee TW, Santavicca DA (1996) Flame stretch measurements during the interaction of premixed flames and Kármán vortex streets using PIV. Combust Flame 105(1–2):167–179CrossRef

Panoutsos CS (2007) Experimental and theoretical study of chemiluminescence in premixed flames. PhD Thesis, Imperial College London, London

Perona P, Malik J (1990) Scale-space and edge detection using anisotropic diffusion. IEEE Trans Pattern Anal Mach Intell 12(7):629–639CrossRef

Peters N (2000) Turbulent combustion, 1st edn. Cambridge University Press, CambridgeCrossRef

Petersson P, Olofsson J, Brackman C, Seyfried H, Zetterberg J, Richter M, Aldén M, Linne MA, Cheng RK, Nauert A, Geyer D, Dreizler A (2007) Simultaneous PIV/OH-PLIF, Rayleigh thermometry/OH-PLIF and stereo PIV measurements in a low-swirl flame. Appl Opt 46(19):3928–3936CrossRef

Pfadler S, Löffler M, Dinkelacker F, Leipertz A (2005) Measurement of the conditioned turbulence and temperature field of a premixed Bunsen burner by planar laser Rayleigh scattering and stereo particle image velocimetry. Exp Fluids 39(2):375–384CrossRef

Pfadler S, Beyrau F, Leipertz A (2007) Flame front detection and characterisation using conditioned particle image velocimetry (CPIV). Opt Express 15(23):15444–15456CrossRef

Pope SB (1988) The evolution of surfaces in turbulence. Int J Eng Sci 26(5):445–469MathSciNetMATHCrossRef

Press WH, Vetterling WT, Teukolsky SA, Flannery BP (2002) Numerical recipes in C++: the art of scientific computing, 2nd edn. Cambridge University Press, Cambridge

Renou B, Boukhalfa A, Puechberty D, Trinité M (2000) Local scalar flame properties of freely propagating premixed turbulent flames at various Lewis numbers. Combust Flame 123(4):507–521CrossRef

Schießl R, Dreizler A, Mass U (1999) Comparison of different ways for image processing: Detection of flame fronts. Soc Auto Eng Int Fuels & Lubricants Meeting & Expo, Toronto, Ontario, CanadaCrossRef

Shepherd IG (1996) Flame surface density and burning rate in premixed turbulent flames. Proc Combust Inst 26(1):373–379MathSciNet

Shepherd IG, Cheng RK (2001) The burning rate of premixed flames in moderate and intense turbulence. Combust Flame 127(3):2066–2075CrossRef

Shepherd IG, Cheng RK, Talbot L (1992) Experimental criteria for the determination of fractal parameters of premixed turbulent flames. Exp Fluids 13(6):386–392CrossRef

Soika A, Dinkelacker F, Leipertz A (2003) Pressure influence on the flame front curvature of turbulent premixed flames: Comparison between experiment and theory. Combust Flame 132(3):451–462CrossRef

Sweeney M, Hochgreb S (2009) Autonomous extraction of optimal flame fronts in OH planar laser-induced fluorescence images. Appl Opt 48(19):3866–3877

Sweeney MS, Hochgreb S, Dunn MJ, Barlow RS (2011) A comparative analysis of flame surface density metrics in premixed and stratified flames. Proc Combust Inst 33(1):1419–1427

Tanahashi M, Murakami S, Choi G-M, Fukuchi Y, Miyauchi T (2005) Simultaneous CH-OH PLIF and stereoscopic PIV measurements of turbulent premixed flames. Proc Combust Inst 30(1):1665–1672CrossRef

Vagelopoulos CM, Frank JH (2006) Transient response of premixed methane flames. Combust Flame 146(3):572–588CrossRef

Veynante D, Duclos JM, Piana J (1994) Experimental analysis of flamelet models for premixed turbulent combustion. Proc Combust Inst 25(1):1249–1256

Weickert J, BMtH R, Viergever MA (1998) Efficient and reliable schemes for nonlinear diffusion filtering. IEEE Trans Image Process 7(3):398–410CrossRef

Title: Local curvature measurements of a lean, partially premixed swirl-stabilised flame
Authors: Alan E. Bayley
Yannis Hardalupas
Alex M. K. P. Taylor
Publication date: 01-04-2012
Publisher: Springer-Verlag
Published in: Experiments in Fluids / Issue 4/2012
Print ISSN: 0723-4864
Electronic ISSN: 1432-1114
DOI: https://doi.org/10.1007/s00348-011-1181-4

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