Modelling flame turbulence interaction in RANS simulation of premixed turbulent combustion

Ahmed, Umair; Prosser, Robert

doi:10.1080/13647830.2015.1115130

Cited by 21 publications

(19 citation statements)

References 49 publications

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“…The k-ԑ model is also used to involve the turbulent effect within the Reynolds-averaged Navier-Stokes (RANS) framework (Tangermann et al 2010, Ahmed and Prosser 2016, and Huang et al 2016, which is a main approach used to simulate the premixed combustion and turbulence problem. Density varies during combustion.…”

Section: Modelling Of the Flame And Combustionmentioning

confidence: 99%

“…Therefore, the interaction between premixed flame and turbulence has become an important research area and is considered a main problem in combustion analysis (Pope 1978, Peters 2004, and Poinsot & Veynante 2005. Many researchers, such as (Marble and Broadwell 1977, Borghi 1989, Veynante and Vervisch 2002, and Ahmed & Prosser 2016, studied the influence of turbulence on a premixed turbulent flame and proposed many models for modeling premixed turbulent combustion. Most of these studies dealt with solving the source term in the species equation.…”

Section: Introductionmentioning

confidence: 99%

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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: Modelling Of the Flame And Combustionmentioning

confidence: 99%

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 approximation leads to simple closures for a number of turbulence related terms. Several modelling approaches have been developed by using the flamelet assumption and PPDF framework and include; laminar flamelets [10,28,41]; the G−equation [32]; scalar dissipation rate and flame turbulence interaction based approaches [2,3,12,40] and flame surface density models [18,60].…”

mentioning

confidence: 99%

“…Several scalar dissipation rate models of varying complexity have been proposed, and range from a complete transport equation to simple algebraic models. The algebraic scalar dissipation rate based modelling approaches have been used in previous studies by Dong et al [25], Ahmed and Prosser [2] and Kolla and Swaminathan [41] via the Reynolds Averaged Navier Stokes (RANS) framework and by Langella et al [45] via Large Eddy Simulation (LES). In a recent study by Ahmed and Prosser [2] the leading order scalar dissipation transport equation has been used to close the reaction rate and the performance of the algebraic scalar dissipation model proposed by Kolla et al [40] is also compared with the predictions from the leading order scalar dissipation transport equation.…”

mentioning

confidence: 99%

“…The algebraic scalar dissipation rate based modelling approaches have been used in previous studies by Dong et al [25], Ahmed and Prosser [2] and Kolla and Swaminathan [41] via the Reynolds Averaged Navier Stokes (RANS) framework and by Langella et al [45] via Large Eddy Simulation (LES). In a recent study by Ahmed and Prosser [2] the leading order scalar dissipation transport equation has been used to close the reaction rate and the performance of the algebraic scalar dissipation model proposed by Kolla et al [40] is also compared with the predictions from the leading order scalar dissipation transport equation. Furthermore Ahmed and Prosser [2] have also compared the results of the scalar dissipation rate based modelling approach with the flame surface density based modelling approach and concluded that the scalar dissipation rate based modelling approach leads to more physically plausible results.…”

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confidence: 99%

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A Posteriori Assessment of Algebraic Scalar Dissipation Models for RANS Simulation of Premixed Turbulent Combustion

Ahmed

Prosser

2017

Flow Turbulence Combust

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Citation for published version (APA):Ahmed, U., & Prosser, R. (2017). A posteriori assessment of algebraic scalar dissipation models for RANS simulation of premixed turbulent combustion. Flow, Turbulence and Combustion. https://doi.Abstract This paper examines the effects of scalar dissipation rate modelling on mean reaction rate predictions in turbulent premixed flames. The sensitivity of the mean reaction rate is explored by using different closures for scalar dissipation and the sensitivity of the scalar dissipation models themselves is also examined with respect to their defining constants. The influence of different scalar dissipation models on the flame location and mean velocities is reported and compared with experimental results. The predicted reaction rate is found to be sensitive to the choice of closure used for scalar dissipation and also to the respective constants used in the scalar dissipation models. It is also found that the scalar dissipation models involving chemical and turbulent time scales yield a more physically plausible reaction rate when compared with the scalar dissipation models relying only on the turbulent time scale.Keywords Algebraic scalar dissipation models · Flame turbulence interaction · RANS simulation of premixed turbulent combustion · Premixed turbulent combustion · Turbulence scalar interaction 1 Introduction Accurate prediction of the mean reaction rate using computational methods remains a challenge for premixed turbulent combustion, and usually requires the use of statistical methods. There is a strong coupling between turbulence and chemistry in premixed flames and several modelling strategies have been developed to account for their interaction. In many cases, the total aerothermochemistry of the flow can be described via a Probability Density Function (PDF) and a multidimensional PDF can in principal be obtained by a PDF transport equation [31,59]. This procedure circumvents a number of modelling assumptions and consequently produces quite general reaction rate models. However the method requires a closure for the molecular diffusion terms which remains a modelling challenge [31]. Conditional Moment Closure (CMC) is another method which provides an alternative strategy for closing the reaction rate [39]. This method was originally developed for non-premixed combustion [16,51] and recently has been extended to account for premixed combustion [5,4,49]. One of the major challenges encountered by the CMC approach in premixed combustion is the modelling of the conditional scalar dissipation rate [43].

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Scalar Gradient and Strain Rate Statistics in Oblique Premixed Flame–Wall Interaction Within Turbulent Channel Flows

Ahmed

Chakraborty

Klein

2020

Flow Turbulence Combust

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Three-dimensional direct numerical simulations of V-flames interacting with chemically inert walls in a fully developed turbulent channel flow have been performed under adiabatic and isothermal wall boundary conditions using single-step chemistry. These simulations are representative of stoichiometric methane-air mixture at unity Lewis number under atmospheric conditions. The turbulence in the non-reacting channel is representative of the friction velocity based Reynolds number $$Re_{\tau }=110$$ R e τ = 110 . Differences in the statistical behaviours of the mean values of progress variable, temperature, and density have been reported for different wall boundary conditions. It is found that the mean location of the oblique flame interacting with the wall is affected by the choice of the wall boundary condition used. The influence of these differences on the flame dynamics is investigated by analysing the statistical behaviours of the surface density function (SDF) and the strain rates, which govern the evolution of the SDF. The mean variation of the SDF and the flame displacement speed are strongly affected by the wall boundary condition within the viscous sub-layer region of the boundary layer. The behaviours of the normal and tangential strain rates are found to be influenced by not only the differences in the wall boundary conditions, but also by the distance from the wall. The differences in the displacement speed statistics for different wall boundary conditions and wall distance affect the behaviours of the normal strain rate arising due to flame propagation and curvature stretch. The changes in the SDF behaviour in the near wall region have been explained in terms of the statistics of effective normal strain rate experienced by the progress variable iso-surfaces under different wall boundary conditions and wall normal distances.

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Modelling flame turbulence interaction in RANS simulation of premixed turbulent combustion

Cited by 21 publications

References 49 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

A Posteriori Assessment of Algebraic Scalar Dissipation Models for RANS Simulation of Premixed Turbulent Combustion

Scalar Gradient and Strain Rate Statistics in Oblique Premixed Flame–Wall Interaction Within Turbulent Channel Flows

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