Your search keyword '"Edge flames"' showing total 25 results

1. Anchored and Lifted Diffusion Flames Supported by Symmetric and Asymmetric Edge Flames.

Author

Lu, Zhanbin and Matalon, Moshe

Subjects

*FLAME, *HEAT losses, *STRAIN rate, *COMBUSTION, *STOICHIOMETRY

Abstract

Numerous combustion applications are concerned with the stabilization of diffusion flames formed by injecting gaseous fuels into a co-flowing stream containing an oxidizer. The smooth operation of these devices depends on the attachment and lift-off characteristics of the edge flame at the base of the diffusion flame. In this paper, we address fundamental issues pertinent to the structure and dynamics of edge flames, which have attributes of both premixed and diffusion flames. The adopted configuration is the mixing layer established in the wake of a splitter plate where two streams, one containing fuel and the other oxidizer, merge. The analysis employs a diffusive-thermal model which, although it excludes effects of gas expansion, systematically includes the influences of the overall flow rate, unequal strain rates in the incoming streams, stoichiometry, differential and preferential diffusion, heat loss and gas–solid thermal interaction, and their effect on the edge structure, speed, and temperature. Conditions when the edge flame is anchored to the plate, lifted-off and stabilized in the flow, or blown-off, are identified. Two stable modes of stabilization are observed for lifted flames; the edge flame either remains stationary at a specified location or undergoes spontaneous oscillations along a direction that coincides with the trailing diffusion flame. [ABSTRACT FROM AUTHOR]

Published

2023

2. Lifted jet edge flames: symmetric and non-symmetric configurations.

Author

Kurdyumov, Vadim N. and Jiménez, Carmen

Subjects

*FLAME, *JET fuel

Abstract

The purpose of this work is to demonstrate that there are different stable configurations of lifted edge flames for the same set of parameters. It is shown that when a fuel jet is injected surrounded by oxidiser streams of equal velocity, there are configurations with symmetric and non-symmetric flame structures with respect to the symmetry line of the problem. These two kinds of solutions are both stable and the actual realisation of one or another solution depends on the initial conditions, in particular on the flame ignition parameters. It is shown that this multiple solution phenomenon takes place when the fuel Lewis number is less than unity. The influence of the Zel'dovich number and the injection flow rate is also investigated. [ABSTRACT FROM AUTHOR]

Published

2022

3. Anchored and Lifted Diffusion Flames Supported by Symmetric and Asymmetric Edge Flames

Author

Zhanbin Lu and Moshe Matalon

Subjects

edge flames, lifted diffusion flames, tribrachial flames, triple flames, edge speed, oscillating flames, Mathematics, QA1-939

Abstract

Numerous combustion applications are concerned with the stabilization of diffusion flames formed by injecting gaseous fuels into a co-flowing stream containing an oxidizer. The smooth operation of these devices depends on the attachment and lift-off characteristics of the edge flame at the base of the diffusion flame. In this paper, we address fundamental issues pertinent to the structure and dynamics of edge flames, which have attributes of both premixed and diffusion flames. The adopted configuration is the mixing layer established in the wake of a splitter plate where two streams, one containing fuel and the other oxidizer, merge. The analysis employs a diffusive-thermal model which, although it excludes effects of gas expansion, systematically includes the influences of the overall flow rate, unequal strain rates in the incoming streams, stoichiometry, differential and preferential diffusion, heat loss and gas–solid thermal interaction, and their effect on the edge structure, speed, and temperature. Conditions when the edge flame is anchored to the plate, lifted-off and stabilized in the flow, or blown-off, are identified. Two stable modes of stabilization are observed for lifted flames; the edge flame either remains stationary at a specified location or undergoes spontaneous oscillations along a direction that coincides with the trailing diffusion flame.

Published

2023

4. The Speed and Temperature of an Edge Flame Stabilized in a Mixing Layer: Dependence on Fuel Properties and Local Mixture Fraction Gradient.

Author

Lu, Zhanbin and Matalon, Moshe

Subjects

FLAME temperature, ENTHALPY, HEAT losses, MIXTURES, FUEL, COMBUSTION kinetics, FLAME, BINARY mixtures

Abstract

Edge flames are of fundamental importance to the attachment and stabilization of diffusion flames in many practical devices, and serve as transient structures for establishing combustion in locally-quenched regions of turbulent diffusion flames. In this study, we consider an edge flame sustained in the mixing layer of two streams, one containing fuel and the other oxidizer, and examine its structure and its thermal and dynamic properties over a wide range of flow conditions, using a diffusive-thermal (constant-density) model. In addition, we allow for the fuel Lewis number to vary from sub- to super-unity values, corresponding to light and moderately heavy fuels, or fuels suitably diluted by inert species, with unity oxidizer Lewis number as appropriate for combustion in air. Two regimes have been identified and examined; a thermal-interaction regime where there is appreciable heat loss from the edge flame to the splitter plate, and a freely-standing regime where the edge flame lifts off considerably and the plate plays no role on its stabilization. The objective is to correlate important edge-flame properties, including standoff distance and edge speed and temperature, with global parameters such as overall flow rate and total heat conducted from the flame to the plate, and local parameters such as local mixture fraction gradient at the edge of the flame. [ABSTRACT FROM AUTHOR]

Published

2020

5. Autoignition-controlled flame initiation and flame stabilization in a reacting jet in crossflow.

Author

Yi, T., Halls, B.R., Jiang, N., Felver, J., Sirignano, M., Emerson, B.L., Lieuwen, T.C., Gord, J.R., and Roy, S.

Abstract

Abstract This paper describes an analysis of the mechanisms of autoignition-controlled flame initiation and flame stabilization in a nonpremixed jet in crossflows, using simultaneous high-speed (10 kHz) tomographic particle image velocimetry, OH-PLIF and line-of-sight flame emissions. Measurements are conducted on a turbulent, transverse, reacting propane jet issued into a crossflow generated by combustion of natural gas at an equivalence ratio of 0.4 with the crossflow velocity of 10 m/s, the crossflow temperature of 1350 K and the jet momentum flux ratio of 41. While several prior studies have analyzed the lifted character of the flame in similar configurations, we show that several dynamic processes precede the leading edge of the lifted diffusion flame, including formation and evolution of "autoignition kernels", "flame kernels" and "flame fragments". "Autoignition kernels", i.e., discrete compact reaction zones with the peak hydroxyl (OH) fluorescence intensity below that of the diffusion flame, initiate preferably at bulges along the jet periphery where the strain rates and the scalar dissipation rates are lower. The autoignition kernel grows in both size and the OH-fluorescence intensity as it convects downstream. An autoignition kernel transitions into a propagating flame kernel, which quickly gets distorted and elongated in the direction of the principal expansion strain rate to form a flame fragment. Neighboring flame fragments merge with each other and with the downstream diffusion flame via edge-flame propagation. Merging of upstream flame fragments with the downstream diffusion flame results in an upstream advancement of the diffusion-flame front. The diffusion flame front is intrinsically unsteady because of the rather random formation and evolution of autoignition kernels, flame kernels and flame fragments, presumably due to the stochastic velocity, the strain rate and mixture-fraction oscillations. [ABSTRACT FROM AUTHOR]

Published

2019

6. Influences of stoichiometry on steadily propagating triple flames in counterflows.

Author

Rajamanickam, Prabakaran, Coenen, Wilfried, Sánchez, Antonio L., and Williams, Forman A.

Abstract

Abstract Most studies of triple flames in counterflowing streams of fuel and oxidizer have been focused on the symmetric problem in which the stoichiometric mixture fraction is 1/2. There then exist lean and rich premixed flames of roughly equal strengths, with a diffusion flame trailing behind from the stoichiometric point at which they meet. In the majority of realistic situations, however, the stoichiometric mixture fraction departs appreciably from unity, typically being quite small. With the objective of clarifying the influences of stoichiometry, attention is focused on one of the simplest possible models, addressed here mainly by numerical integration. When the stoichiometric mixture fraction departs appreciably from 1/2, one of the premixed wings is found to be dominant to such an extent that the diffusion flame and the other premixed flame are very weak by comparison. These curved, partially premixed flames are expected to be relevant in realistic configurations. In addition, a simple kinematic balance is shown to predict the shape of the front and the propagation velocity reasonably well in the limit of low stretch and low curvature. [ABSTRACT FROM AUTHOR]

Published

2019

7. Two dimensional advective heat flux estimation from velocity measurements.

Author

Grib, Stephen W. and Renfro, Michael W.

Subjects

*HEAT flux, *VELOCITY measurements, *PARAMETER estimation, *UNSTEADY flow, *STRENGTH of materials, *TEMPERATURE measurements

Abstract

The advective heat flux, ρc p v · ∇ T , is an important quantity in edge flames because the sign of v · ∇ T characterizes relative propagation direction of the edge flame, and its magnitude gives information regarding strength of the resulting propagation or extinction front. Modern laser techniques can measure the velocity and temperature fields simultaneously within a flame, but accurate measurements of temperature simultaneous with velocity outside the high temperature region of the flame are more difficult and time-resolved measurements of velocity and temperature simultaneously for unsteady flows require complex measurement systems. In this paper, the theoretical framework to show that the flow dilatation can be used to directly estimate a scaled advective heat flux is presented. Numerical simulations of both a positive (propagating) and negative (extinguishing) edge flame were studied to assess the relationship between dilatation and advective heat flux. Experimental measurements of the two-dimensional component of dilatation in positive and negative edge flames were also made and compared to the simulations. The full advective heat flux was well represented by the dilatation in the simulations, and the experimental data demonstrates that the measured dilatation is useful for estimating advective heat flux. Flames with varying positive and negative flame speeds are examined with the technique. [ABSTRACT FROM AUTHOR]

Published

2017

8. Theory of the propagation dynamics of spiral edges of diffusion flames in von Karman swirling flows

Author

Nayagam, Vedha [National Center for Space Exploration Research, NASA Glenn Research Center, Cleveland, OH 44135 (United States)]

Published

2011

9. Experimental study on tribrachial flames in narrow channels with small fuel concentration gradients

Author

Kim, Nam [School of Mechanical Engineering, Chung-Ang University, Heukseok-dong, Dongjak-gu, Seoul 156-756 (Korea)]

Published

2010

10. Flame speed and tangential strain measurements in widely stratified partially premixed flames interacting with grid turbulence.

Author

Mulla, Irfan A. and Chakravarthy, Satyanarayanan R.

Subjects

*FLAME, *TANGENTIAL force, *STRAINS & stresses (Mechanics), *TURBULENCE, *PLANAR laser-induced fluorescence, *BURNERS (Technology)

Abstract

Methane-air partially premixed flames subjected to grid-generated turbulence are stabilized in a two-slot burner with initial fuel concentration differences leading to stratification across the stoichiometric concentration. The fuel concentration gradient at the location corresponding to the flame base is measured using planar laser induced fluorescence (PLIF) of acetone in the non-reacting mixing field. Simultaneous PLIF of the OH radical and particle image velocimetry (PIV) measurements are performed to deduce the flow velocity and the flame front. These flames exhibit a convex premixed flame front and a trailing diffusion flame, with flow divergence upstream of the flame, as indicated by the instantaneous OH-PLIF, Mie scattering images, and PIV data. The mean streamwise velocity profile attains a global minimum just upstream of the flame front due to expansion of a gases caused by heat release. The flame speed measured just upstream of the flame leading edge is normalized with respect to the turbulent stoichiometric flame speed that takes into account variations in turbulent intensity and integral length scale. The turbulent edge flame speed exceeds the corresponding stoichiometric premixed flame speed and reaches a peak at a certain concentration gradient. The mean tangential strain at the flame leading edge locally peaks at the concentration gradient corresponding to the peak flame speed. The strain varies non-monotonically with the flame curvature unlike in a non-stratified curved premixed flame. The mechanism of peak flame speed is explained as the competition between availability of hot excess reactants from the premixed flame branches to the flame stretch induced due to flame curvature. The results suggest that the stabilization of lifted turbulent partially premixed flames occurs through an edge flame even at a relatively gentle concentration gradient. The strain is also evaluated along the flame front; it peaks at the flame leading edge and decreases gradually on either side of the leading edge. The present results also show qualitatively similar trends as those of laminar triple flames. [ABSTRACT FROM AUTHOR]

Published

2014

11. Structure of n-heptane/air triple flames in partially-premixed mixing layers

Author

Prager, J., Najm, H.N., Valorani, M., and Goussis, D.A.

Subjects

*CHEMICAL structure, *HEPTANE, *FLAME, *AIR flow, *CHEMICAL reactions, *CHEMICAL models, *DIFFUSION

Abstract

Abstract: Results of a detailed numerical analysis of an n-heptane/air edge flame are presented. The equations of a low-Mach number reacting flow are solved in a two-dimensional domain using detailed models for species transport and chemical reactions. The reaction mechanism involves 560 species and 2538 reversible reactions. We consider an edge flame that is established in a mixing layer with a uniform velocity field. The mixing layer spans the equivalence ratios between pure air and 3.5. The detailed model enables us to analyze the chemical structure of the n-heptane edge flame. We identify major species profiles, discuss reactions causing the heat-release, and exploit Computational Singular Perturbation (CSP) to discuss the main fuel-consumption pathways and the structure of explosive modes in the edge flame. This analysis is performed for several regions in the edge flame to discuss the different processes at work in the premixed branches and the trailing diffusion flame. We compare different cuts through the 2D edge flame to canonical 1D premixed and diffusion flames. We also analyze the accuracy of a skeletal mechanism which was previously developed using CSP from homogeneous ignition calculations of n-heptane and show that a significant reduction in size of the mechanism can be achieved without a significant decrease in accuracy of the edge flame computation. This skeletal mechanism is then used to study the effects of increasing the equivalence ratio in the partially-premixed fuel stream. [Copyright &y& Elsevier]

Published

2011

12. Theory of the propagation dynamics of spiral edges of diffusion flames in von Kármán swirling flows

Author

Urzay, Javier, Nayagam, Vedha, and Williams, Forman A.

Subjects

*DIFFUSION, *POROUS materials, *FLAME, *FUEL, *COMBUSTION, *FIREFIGHTING, *CURVATURE

Abstract

Abstract: This analysis addresses the propagation of spiral edge flames found in von Kármán swirling flows induced in rotating porous-disk burners. In this configuration, a porous disk is spun at a constant angular velocity in an otherwise quiescent oxidizing atmosphere. Gaseous methane is injected through the disk pores and burns in a flat diffusion flame adjacent to the disk. Among other flame patterns experimentally found, a stable, rotating spiral flame is observed for sufficiently large rotation velocities and small fuel flow rates as a result of partial extinction of the underlying diffusion flame. The tip of the spiral can undergo a steady rotation for sufficiently large rotational velocities or small fuel flow rates, whereas a meandering tip in an epicycloidal trajectory is observed for smaller rotational velocities and larger fuel flow rates. A formulation of this problem is presented in the equidiffusional and thermodiffusive limits within the framework of one-step chemistry with large activation energies. Edge-flame propagation regimes are obtained by scaling analyses of the conservation equations and exemplified by numerical simulations of straight two-dimensional edge flames near a cold porous wall, for which lateral heat losses to the disk and large strains induce extinction of the trailing diffusion flame but are relatively unimportant in the front region, consistent with the existence of the cooling tail found in the experiments. The propagation dynamics of a steadily rotating spiral edge is studied in the large-core limit, for which the characteristic Markstein length is much smaller than the distance from the center at which the spiral tip is anchored. An asymptotic description of the edge tangential structure is obtained, spiral edge shapes are calculated, and an expression is found that relates the spiral rotational velocity to the rest of the parameters. A quasiestatic stability analysis of the edge shows that the edge curvature at extinction in the tip region is responsible for the stable tip anchoring at the core radius. Finally, experimental results are analyzed, and theoretical predictions are tested. [Copyright &y& Elsevier]

Published

2011

13. Lean blowoff of bluff body stabilized flames: Scaling and dynamics

Author

Shanbhogue, Santosh J., Husain, Sajjad, and Lieuwen, Tim

Subjects

*FLAME, *COMBUSTION, *FUEL, *POWER resources

Abstract

Abstract: This paper overviews the dynamics of bluff body stabilized flames and describes the phenomenology of the blowoff process. The first section of the paper provides an overview of the fluid mechanics of the non-reacting and reacting bluff body wake flow. It highlights the key features of the flow (the boundary layer, separated shear layer, and wake), the flow instabilities that influence each of these features, and the influences of the flame on these instabilities. A key point from these studies is the large differences between the non-reacting wake (dominated by an absolutely unstable, sinuous instability associated with vortex shedding from the bluff body) and the reacting wake of high dilatation ratio flames. The latter are dominated by the lower intensity, convective instability of the shear layer. Very low dilatation ratio flames begin to approach the behavior of the non-reacting wake, as might be expected. Next, the paper presents a compilation of bluff body blowoff data from the literature and shows that the basic Damköhler correlations developed from prior studies are recovered, but without the need for semi-empirical fits or adjustable constants for chemical time estimation. The third section considers in detail the dynamics and phenomenology of near blowoff flames. It is shown that spatio/temporally localized extinction occurs sporadically on near blowoff flames, manifested as “holes” in the flame sheet that form and convect downstream. However, these extinction events are distinct from blowoff – in fact, under certain conditions the flame can persist indefinitely with certain levels of local extinction. The number of these events per unit time increase as blowoff is approached, eventually leading to large scale alteration of the wake. We hypothesize that simple Damköhler number correlations contain the essential physics describing the intial stage of blowoff; i.e., they are correlations for the conditions where local extinction on the flame begins, but do not fundamentally describe the ultimate blowoff condition itself. However, such correlations are reasonably successful in correlating blowoff limits because the ultimate blowoff event is related to the onset of this first stage. Key conclusions from this review are that blowoff occurs in multiple steps – local extinction along the flame sheet, large scale wake disruption, and a final blowoff whose ultimate “trigger” is associated with wake cooling and shrinking. A key challenge for future workers is understanding these latter processes that lead to ultimate blowoff of the flame. [Copyright &y& Elsevier]

Published

2009

14. UPSTREAM ISLANDS OF FLAME IN LIFTED-JET PARTIALLY PREMIXED COMBUSTION.

Author

Lyons, K. M., Watson, K. A., Carter, C. D., and Donbar, J. M.

Subjects

FLAME, TURBULENCE, LASERS, RAYLEIGH scattering, COMBUSTION

Abstract

Contemporary interest exists in understanding the roles of leading edge flow deflection, secondary jet instabilities and islands of ignited gases in permitting lifted flames to stabilize. To assess these issues, elements of the leading-edge of a lifted turbulent jet flame have been investigated using laser-imaging techniques. Images of flame position, morphology and dynamics are presented primarily from CH planar laser-induced fluorescence (CH-PLIF) measurements. In particular, evidence of flame islands, or flame fragments, upstream of the bulk-flame leading edge are reported and discussed. This evidence is presented in the form of sequential CH-PLIF images and well as CH-PLIF/Rayleigh scattering images. Images showing thermal characteristics of the regions surrounding the edge flame are also described. [ABSTRACT FROM AUTHOR]

Published

2007

15. Experimental measurements of two-dimensional planar propagating edge flames.

Author

Villa-Gonzalez, Marcos, Marchese, Anthony J., Easton, John W., and Miller, Fletcher J.

Subjects

FLAME, FLAMMABLE materials, REDUCED gravity environments, FUEL

Abstract

Abstract: The study of edge flames has received increased attention in recent years. This work reports the results of a recent study into two-dimensional, planar, propagating edge flames that are remote from solid surfaces (called here, “free-layer” flames, as opposed to layered flames along floors or ceilings). They represent an ideal case of a flame propagating down a flammable plume, or through a flammable layer in microgravity. The results were generated using a new apparatus in which a thin stream of gaseous fuel is injected into a low-speed laminar wind tunnel thereby forming a flammable layer along the centerline. An airfoil-shaped fuel dispenser downstream of the duct inlet issues ethane from a slot in the trailing edge. The air and ethane mix due to mass diffusion while flowing up towards the duct exit, forming a flammable layer with a steep lateral fuel concentration gradient and smaller axial fuel concentration gradient. We characterized the flow and fuel concentration fields in the duct using hot wire anemometer scans, flow visualization using smoke traces, and non-reacting, numerical modeling using COSMOSFloWorks. In the experiment, a hot wire near the exit ignites the ethane–air layer, with the flame propagating downwards towards the fuel source. Reported here are tests with the air inlet velocity of 25cm/s and ethane flows of 967–1299sccm, which gave conditions ranging from lean to rich along the centerline. In these conditions the flame spreads at a constant rate faster than the laminar burning rate for a premixed ethane–air mixture. The flame spread rate increases with increasing transverse fuel gradient (obtained by increasing the fuel flow rate), but appears to reach a maximum. The flow field shows little effect due to the flame approach near the igniter, but shows significant effect, including flow reversal, well ahead of the flame as it approaches the airfoil fuel source. [Copyright &y& Elsevier]

Published

2007

16. Liftoff and blowoff of a diffusion flame between parallel streams of fuel and air

Author

Fernández-Tarrazo, Eduardo, Vera, Marcos, and Liñán, Amable

Subjects

*NUMERICAL analysis, *THERMAL expansion, *ARRHENIUS equation, *FUEL

Abstract

Abstract: A numerical analysis is presented to describe the liftoff and blowoff of a diffusion flame in the mixing layer between two parallel streams of fuel (mainly methane diluted with nitrogen) and air emerging from porous walls. The analysis, which takes into account the effects of thermal expansion, assumes a one-step overall Arrhenius reaction, where the activation energy E is allowed to vary to reproduce the variations of the planar flame propagation velocity with the equivalence ratio. First, we describe the steady flame-front structure when stabilized close to the porous wall (attached flame regime). Then, we analyze the case where the flame front is located far away from the porous wall, at a distance such that, upstream of the flame front, the mixing layer has a self-similar structure (lifted flame regime). For steady lifted flames, the results, given here in the case when the fuel and air streams are injected with the same velocity, relate , the front velocity (relative to the upstream flow) measured with the planar stoichiometric flame velocity, with the Damköhler number , based on the thickness, , of the nonreacting mixing layer at the flame-front position and the laminar flame thickness, . For large values of , the results, presented here for a wide range of dilutions of the fuel stream, provide values of the front propagation velocity that are in good agreement with previous experimental results, yielding well-defined conditions for blowoff. The calculated flame-front velocity can also be used to describe the transient flame-front dynamics after ignition by an external energy source. [Copyright &y& Elsevier]

Published

2006

17. Modélisation hybride de la chimie pour la simulation numérique de la combustion

Author

Duboc, Bastien, Complexe de recherche interprofessionnel en aérothermochimie (CORIA), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences appliquées Rouen Normandie (INSA Rouen Normandie), Institut National des Sciences Appliquées (INSA)-Normandie Université (NU)-Institut National des Sciences Appliquées (INSA)-Normandie Université (NU)-Université de Rouen Normandie (UNIROUEN), Normandie Université (NU), Normandie Université, Pascale Domingo, and Guillaume Ribert

Subjects

Edge flames, Detailed chemistry, Numerical simulation of combustion, Flammes triples, Modélisation hybride de la chimie, Chimie tabulée, [PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph], Hybrid modeling of chemistry, Chimie détaillée, Tabulated chemistry

Abstract

Even if significant progress is being made to improve the power of high-performance computers, the numerical simulation of reactive flows involving complex chemistry is still a challenging task. The objective of this work is the development of the Hybrid Transported-Tabulated Chemistry method (HTTC), designed for the DNS/LES simulations of flames with detailed kinetic mechanisms, with an acceptable cost. This novel approach combines the transport of the main species in the flow with the tabulation of the radical species. It has been implemented in a DNS/LES code and validated on 1D methane and kerosene flames. The cost of the simulations has been considerably decreased, compared to classic detailed chemistry solvers. Then, simulations of methane edge flames, featuring large gradients of mixture fraction, have been performed with HTTC. In particular, the impact of the methods used to extend the chemical tables and to compute the control variables have been analyzed in details. A very good agreement has been found by comparison with detailed chemistry.; Malgré l'augmentation constante des ressources informatiques dédiées au calcul scientifique, simuler des écoulements réactifs mettant en jeu une chimie complexe reste aujourd'hui encore un véritable challenge. L'objectif de cette thèse est le développement de la méthode Hybrid Transported-Tabulated Chemistry (HTTC), destinée aux simulations DNS/LES de flammes avec des mécanismes cinétiques détaillés, en offrant un temps de calcul acceptable. Cette nouvelle approche consiste à transporter les espèces majoritaires de l'écoulement, tandis que les espèces minoritaires sont extraites d'une table chimique. La méthode HTTC a été implémentée dans un code DNS/LES et validée sur des flammes 1D de méthane et de kérosène, mettant en évidence une réduction extrêmement importante du temps de calcul, comparé aux solveurs classiques de chimie détaillée. HTTC a ensuite été mis en œuvre avec succès sur des flammes triples de méthane en présence de forts gradients de fraction de mélange. L'impact des méthodes choisies pour prolonger la table chimique et pour calculer les variables de contrôle, utilisées pour paramétrer la table, a été étudiée avec une attention particulière. Un très bon accord a été trouvé avec les résultats de référence, obtenus avec un solveur de chimie détaillée.

Published

2017

18. Hybrid transported-tabulated chemistry for numerical simulation of combustion

Author

Duboc, Bastien, STAR, ABES, Complexe de recherche interprofessionnel en aérothermochimie (CORIA), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences appliquées Rouen Normandie (INSA Rouen Normandie), Institut National des Sciences Appliquées (INSA)-Normandie Université (NU)-Institut National des Sciences Appliquées (INSA)-Normandie Université (NU)-Université de Rouen Normandie (UNIROUEN), Normandie Université (NU), Normandie Université, Pascale Domingo, and Guillaume Ribert

Subjects

Numerical simulation of combustion, Detailed chemistry, Edge flames, Modélisation hybride de la chimie, Flammes triples, Chimie tabulée, [PHYS.MECA.MEFL] Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph], [PHYS.MECA.MEFL]Physics [physics]/Mechanics [physics]/Fluid mechanics [physics.class-ph], Hybrid modeling of chemistry, Chimie détaillée, Tabulated chemistry

Abstract

Even if significant progress is being made to improve the power of high-performance computers, the numerical simulation of reactive flows involving complex chemistry is still a challenging task. The objective of this work is the development of the Hybrid Transported-Tabulated Chemistry method (HTTC), designed for the DNS/LES simulations of flames with detailed kinetic mechanisms, with an acceptable cost. This novel approach combines the transport of the main species in the flow with the tabulation of the radical species. It has been implemented in a DNS/LES code and validated on 1D methane and kerosene flames. The cost of the simulations has been considerably decreased, compared to classic detailed chemistry solvers. Then, simulations of methane edge flames, featuring large gradients of mixture fraction, have been performed with HTTC. In particular, the impact of the methods used to extend the chemical tables and to compute the control variables have been analyzed in details. A very good agreement has been found by comparison with detailed chemistry., Malgré l'augmentation constante des ressources informatiques dédiées au calcul scientifique, simuler des écoulements réactifs mettant en jeu une chimie complexe reste aujourd'hui encore un véritable challenge. L'objectif de cette thèse est le développement de la méthode Hybrid Transported-Tabulated Chemistry (HTTC), destinée aux simulations DNS/LES de flammes avec des mécanismes cinétiques détaillés, en offrant un temps de calcul acceptable. Cette nouvelle approche consiste à transporter les espèces majoritaires de l'écoulement, tandis que les espèces minoritaires sont extraites d'une table chimique. La méthode HTTC a été implémentée dans un code DNS/LES et validée sur des flammes 1D de méthane et de kérosène, mettant en évidence une réduction extrêmement importante du temps de calcul, comparé aux solveurs classiques de chimie détaillée. HTTC a ensuite été mis en œuvre avec succès sur des flammes triples de méthane en présence de forts gradients de fraction de mélange. L'impact des méthodes choisies pour prolonger la table chimique et pour calculer les variables de contrôle, utilisées pour paramétrer la table, a été étudiée avec une attention particulière. Un très bon accord a été trouvé avec les résultats de référence, obtenus avec un solveur de chimie détaillée.

Published

2017

19. Flame speed and tangential strain measurements in widely stratified partially premixed flames interacting with grid turbulence

Author

Irfan A. Mulla and Satyanarayanan R. Chakravarthy

Subjects

Premixed flame, Leading edge, Acetone, Free radicals, Methane, Turbulence, Edge flames, Flame speed, Flame stretch, Partially premixed flames, Triple flame, Speed, acetone, hydroxyl radical, methane, nitrogen, anisotropy, article, combustion, competition, diffusion, flame, flow rate, gas, particle image velocimetry, priority journal, stratification, turbulent flow, velocity, Laminar flame speed, Chemistry, General Chemical Engineering, Diffusion flame, Analytical chemistry, General Physics and Astronomy, Energy Engineering and Power Technology, General Chemistry, Mechanics, Fuel Technology, Particle image velocimetry, Planar laser-induced fluorescence

Abstract

Methane-air partially premixed flames subjected to grid-generated turbulence are stabilized in a two-slot burner with initial fuel concentration differences leading to stratification across the stoichiometric concentration. The fuel concentration gradient at the location corresponding to the flame base is measured using planar laser induced fluorescence (PLIF) of acetone in the non-reacting mixing field. Simultaneous PLIF of the OH radical and particle image velocimetry (PIV) measurements are performed to deduce the flow velocity and the flame front. These flames exhibit a convex premixed flame front and a trailing diffusion flame, with flow divergence upstream of the flame, as indicated by the instantaneous OH-PLIF, Mie scattering images, and PIV data. The mean streamwise velocity profile attains a global minimum just upstream of the flame front due to expansion of a gases caused by heat release. The flame speed measured just upstream of the flame leading edge is normalized with respect to the turbulent stoichiometric flame speed that takes into account variations in turbulent intensity and integral length scale. The turbulent edge flame speed exceeds the corresponding stoichiometric premixed flame speed and reaches a peak at a certain concentration gradient. The mean tangential strain at the flame leading edge locally peaks at the concentration gradient corresponding to the peak flame speed. The strain varies non-monotonically with the flame curvature unlike in a non-stratified curved premixed flame. The mechanism of peak flame speed is explained as the competition between availability of hot excess reactants from the premixed flame branches to the flame stretch induced due to flame curvature. The results suggest that the stabilization of lifted turbulent partially premixed flames occurs through an edge flame even at a relatively gentle concentration gradient. The strain is also evaluated along the flame front; it peaks at the flame leading edge and decreases gradually on either side of the leading edge. The present results also show qualitatively similar trends as those of laminar triple flames. � 2014 The Combustion Institute.

Published

2014

20. Nonlinear dynamical behaviour of intrinsic thermal-diffusive oscillations of laminar flames with varying premixedness

Author

David S. Bhatt and Satyanarayanan R. Chakravarthy

Subjects

Co-flow, Premixed, Splitter plate, General Chemical Engineering, General Physics and Astronomy, nonlinear system, Parameter space, Total heat release, Physics::Fluid Dynamics, Full spectrum, Parameter spaces, Initial value problems, Physics::Chemical Physics, Higher order, Chemistry, Non-premixed, Mechanics, oscillation, Compact schemes, Partially premixed flames, Damköhler numbers, Fuel Technology, priority journal, Parametric spaces, Subcritical Hopf bifurcation, symbols, Splitter plates, fire, chemical reaction, Edge flames, Premixed Flame, Energy Engineering and Power Technology, Thermodynamics, Diffusive flux, Instability, Single-step, Dynamical behaviours, symbols.namesake, Limit cycle, Dirichlet data, Phase spaces, Premixedness, Limit Cycle Oscillation (LCO), Hopf bifurcation, thermal diffusion, Inlet concentration, Laminar flame, Lewis numbers, Phase space methods, Laminar flow, Pulsating instability, General Chemistry, Finite rate, Lewis number, hysteresis

Abstract

This study focuses on the thermal-diffusive oscillations of the full spectrum of co-flow laminar flames-from premixed to non-premixed through partially premixed flames for Lewis numbers sufficiently greater than unity. A premixedness parameter is identified using the analytical solution to the mixing field downstream of a splitter plate. Different premixedness levels ranging from zero (fully non-premixed) to unity (fully premixed) are then used as Dirichlet data for inlet concentrations of the reactants to the flame. The initial value problem is numerically solved by adopting a thermo-diffusive model and single-step finite rate chemical reaction and using higher-order compact schemes. A thumb-shaped region in the Damk�hler number - premixedness parameter space is identified as corresponding to limit cycle oscillations of the flame. This fills the gap between what is reported for the pulsating instability of non-premixed edge flames recently and fully premixed flames earlier. The thumb-shaped region enlarges with increase in the Lewis number in the range of 1.5-1.7, with marked increase in the oscillatory amplitude of the total heat release. A subcritical Hopf bifurcation is seen to occur at the boundary of this region in the above parametric space. The mechanism of oscillations is studied: hysteresis is found between the upstream and downstream propagation of the flame due to the thermal-diffusive imbalance. The oscillations are plotted in the phase space of the domain-integrated mass and heat diffusive fluxes of and to the reactants. The area of the limit cycle peaks at a particular Damk�hler number and premixedness parameter and drops to zero on both sides in this parametric space. � 2012 The Combustion Institute.

Published

2012

21. LAMINAR AND TURBULENT STUDY OF COMBUSTION IN STRATIFIED ENVIRONMENTS USING LASER BASED MEASUREMENTS

Author

Grib, Stephen William

Subjects

Laser Diagnostics, Edge Flames, Autoignition, Flame Stabilization, Extinction, Heat Transfer, Combustion, Propulsion and Power

Abstract

Practical gas turbine engine combustors create extremely non-uniform flowfields, which are highly stratified making it imperative that similar environments are well understood. Laser diagnostics were utilized in a variety of stratified environments, which led to temperature or chemical composition gradients, to better understand autoignition, extinction, and flame stability behavior. This work ranged from laminar and steady flames to turbulent flame studies in which time resolved measurements were used. Edge flames, formed in the presence of species stratification, were studied by first developing a simple measurement technique which is capable of estimating an important quantity for edge flames, the advective heat flux, using only velocity measurements. Both hydroxyl planar laser induced fluorescence (OH PLIF) and particle image velocimetry (PIV) were used along with numerical simulations in the development of this technique. Interacting triple flames were also created in a laboratory scale burner producing a laminar and steady flowfield with symmetric equivalence ratio gradients. Studies were conducted in order to characterize and model the propagation speed as a function of the flame base curvature and separation distance between the neighboring flames. OH PLIF, PIV and Rayleigh scattering measurements were used in order to characterize the propagation speed. A model was developed which is capable of accurately representing the propagation speed for three different fuels. Negative edge flames were first studied by developing a one-dimensional model capable of reproducing the energy equation along the stoichiometric line, which was dependent on different boundary conditions. Unsteady and laminar negative edge flames were also simulated with periodic boundary conditions in order to assess the difference between the steady and unsteady cases. The diffusive heat loss was unbalanced with the chemical heat release and advective heat flux energy gain terms which led to the flame proceeding and receding. The temporal derivative balanced the energy equation, but also aided in the understanding of negative edge flame speeds. Turbulent negative edge flame velocities were measured for extinguishing flames in a separate experiment as a function of the bulk advective heat flux through the edge and turbulence level. A burner was designed and built for this study which created statistically stationary negative edge flames. The edge velocity was dependent on both the bulk advective heat flux and turbulence levels. The negative edge flame velocities were obtained with high speed stereo-view chemiluminescence and two dimensional PIV measurements. Autoignition stabilization was studied in the presence of both temperature and species stratification, using a simple laminar flowfield. OH and CH2O PLIF measurements showed autoignition characteristics ahead of the flame base. Numerical chemical and flow simulations also revealed lower temperature chemistry characteristics ahead of the flame base leading to the conclusion of lower temperature chemistry dominating the stabilization behavior. An energy budget analysis was conducted which described the stabilization behavior.

Published

2018

22. Structure of n-heptane/air triple flames in partially-premixed mixing layers

Author

Habib N. Najm, Mauro Valorani, Jens Prager, and Dimitris A. Goussis

Subjects

Premixed flame, Work (thermodynamics), Laminar flame speed, Chemistry, General Chemical Engineering, Diffusion flame, Analytical chemistry, General Physics and Astronomy, Energy Engineering and Power Technology, General Chemistry, Mechanics, Edge (geometry), triple flames, law.invention, edge flames, Ignition system, Fuel Technology, law, Diffusion (business), n-heptane, Mixing (physics)

Abstract

Results of a detailed numerical analysis of an n-heptane/air edge flame are presented. The equations of a low-Mach number reacting flow are solved in a two-dimensional domain using detailed models for species transport and chemical reactions. The reaction mechanism involves 560 species and 2538 reversible reactions. We consider an edge flame that is established in a mixing layer with a uniform velocity field. The mixing layer spans the equivalence ratios between pure air and 3.5. The detailed model enables us to analyze the chemical structure of the n-heptane edge flame. We identify major species profiles, discuss reactions causing the heat-release, and exploit Computational Singular Perturbation (CSP) to discuss the main fuel-consumption pathways and the structure of explosive modes in the edge flame. This analysis is performed for several regions in the edge flame to discuss the different processes at work in the premixed branches and the trailing diffusion flame. We compare different cuts through the 2D edge flame to canonical 1D premixed and diffusion flames. We also analyze the accuracy of a skeletal mechanism which was previously developed using CSP from homogeneous ignition calculations of n-heptane and show that a significant reduction in size of the mechanism can be achieved without a significant decrease in accuracy of the edge flame computation. This skeletal mechanism is then used to study the effects of increasing the equivalence ratio in the partially-premixed fuel stream.

Published

2011

23. Analysis of Methane-Air Edge Flame Structure

Author

Mauro Valorani, Habib N. Najm, Jens Prager, and Dimitris A. Goussis

Subjects

Computational singular perturbation, Singular perturbation, triple flame, Laminar flame speed, Basic structure, Edge flames, General Chemical Engineering, Flame structure, Analytical chemistry, General Physics and Astronomy, Energy Engineering and Power Technology, Flux, Edge (geometry), Chemical kinetics, edge flame, methane–air, computational singular perturbation, low-dimensional manifold, Physics::Chemical Physics, Mixing (physics), Premixed flame, Chemistry, General Chemistry, Fuel Technology, Chemical physics, Modeling and Simulation

Abstract

We study the structure of a methane–air edge flame stabilized against an incoming mixing layer. The flame is computed using detailed chemical kinetics, and the analysis is based on computational singular perturbation theory. We focus on examination of the dynamical fast/slow structure of the flame, exploring the distribution of time-scales, the composition of the related specific modes and the effective low-dimensional structure. We also study the importance of chemical/transport processes for both major species and radicals in the flame, analyzing the information available from slow/fast importance indices as compared to reaction flux analysis. Results provide enhanced understanding of the flame, outlining the role of different chemical and transport processes in its observed structure.

Published

2007

24. Upstream Islands of Flame in Lifted-Jets Partially Premixed Combustion

Author

NORTH CAROLINA STATE UNIV AT RALEIGH DEPT OF MECHANICAL AND AEROSPACE ENGINEERING, Lyons, K. M., Watson, K. A., Carter, C. D., Donbar, J. M., NORTH CAROLINA STATE UNIV AT RALEIGH DEPT OF MECHANICAL AND AEROSPACE ENGINEERING, Lyons, K. M., Watson, K. A., Carter, C. D., and Donbar, J. M.

Abstract

Contemporary interest exists in understanding the roles of leading edge flow deflection, secondary jet instabilities and islands of ignited gases in permitting lifted flames to stabilize. To assess these issues, elements of the leading-edge of a lifted turbulent jet flame have been investigated using laser-imaging techniques. Images of flame position, morphology and dynamics are presented primarily from CH planar laser-induced fluorescence (CH-PLIF) measurements. In particular, evidence of flame islands, or flame fragments, upstream of the bulkflame leading edge are reported and discussed. This evidence is presented in the form of sequential CH-PLIF images and well as CH-PLIF=Rayleigh scattering images. Images showing thermal characteristics of the regions surrounding the edge flame are also described., Federal Purpose Rights Pub. in Jnl. of Combust. Sci. and Tech., v179 p1029-1037, 2007. Supported in part by NSF and AFRL.

Published

2007

25. A COMPUTATIONAL STUDY OF THE STRUCTURE, STABILITY, DYNAMICS, AND RESPONSE OF LOW STRETCH DIFFUSION FLAME

Author

Nanduri, Jagannath Ramchandra

Subjects

Diffusion Flame Stability, Diffusional Thermal Instability, Flame Oscillations, Flame Radiation Interaction, Edge Flames, Cellular Flames

Abstract

Diffusional thermal instabilities occur because of the imbalance between the diffusion of heat and the diffusion of species into the reaction zone. While the phenomenon of diffusional thermal instability (DTI) has been recorded in detail in the high stretch extinction regime of diffusion flames, fundamental understanding of the DTI near the low stretch radiation induced extinction regime is lacking. Low stretch flames are relevant to the fire safety characteristics in many practical engineering fields. In the current study we investigate the phenomena of DTI for low stretch diffusion flames with radiative heat loss and map the one-dimensional and two-dimensional flame structure, stability and dynamics. Low stretch nonpremixed combustion including radiative heat loss is modeled using a planar counterflow configuration (PCC) and an axisymmetric counterflow configuration (ACC) to highlight the effects of flow configuration on low stretch flame instabilities. It is found that the 1D low stretch diffusion flames in both ACC and PCC systems initially lose their stability to pulsations which lead to oscillatory extinction for stretch rates much higher than the 1D steady state extinction limit. The effects of the Lewis number and reaction rate on this 1D oscillatory instability is also presented along with a fast Fourier transform (FFT) analysis to map the frequency and amplitude characteristics of the oscillatory instability. The stability of the 2D flame is mapped using different initial profiles. The 2D low-stretch diffusion flame in both ACC and PCC systems was found to lose its stability to wavy flames very close to the 1D neutral stability point subsequently leading to steady/unsteady stationary/traveling cellular flames for PCC system and unsteady cellular flames for ACC system. These multi-dimensional flame phenomena are shown to extend the dynamic extinction limits predicted by the 1D model. Comparisons between the ACC system and the PCC system also show the effects of flow configuration on multi-dimensional flame phenomenon for low-stretch radiative diffusion flames. A 2D bifurcation of the flame solution close to the 1D low-stretch radiation induced extinction limit is identified.

Published

2006