Numerical Investigation of a Bluff-Body Stabilised Nonpremixed Flame with Differential Reynolds-Stress Models

Li, Guo-Xiu; Naud, Bertrand; Roekaerts, Dirk

doi:10.1023/b:appl.0000004931.07292.55

Cited by 27 publications

(31 citation statements)

References 22 publications

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“…Turbulence is modeled using the second-moment closure RANS model of [20]. This is the isotropization of production model of [27], with modified constant value C ε1 = 1.6, instead of the standard value C ε1 = 1.44.…”

Section: Turbulence Modelmentioning

confidence: 99%

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Joint Scalar versus Joint Velocity-Scalar PDF Simulations of Bluff-Body Stabilized Flames with REDIM

Merci

Naud

Roekaerts

et al. 2008

Flow Turbulence Combust

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Two transported PDF strategies, joint velocity-scalar PDF (JVSPDF) and joint scalar PDF (JSPDF), are investigated for bluff-body stabilized jet-type turbulent diffusion flames with a variable degree of turbulence-chemistry interaction. Chemistry is modeled by means of the novel reaction-diffusion manifold (REDIM) technique. A detailed chemistry mechanism is reduced, including diffusion effects, with N 2 and CO 2 mass fractions as reduced coordinates. The second-moment closure RANS turbulence model and the modified Curl's micro-mixing model are not varied. Radiative heat loss effects are ignored. The results for mean velocity and velocity fluctuations in physical space are very similar for both PDF methods. They agree well with experimental data up to the neck zone. Each of the two PDF approaches implies a different closure for the velocity-scalar correlation. This leads to differences in the radial profiles in physical space of mean scalars and mixture fraction variance, due to different scalar flux modeling. Differences are visible in mean mixture fraction and mean temperature, as well as in mixture fraction variance. In principle, the JVSPDF simulations can be closer to physical reality, as a differential model is implied for the scalar fluxes, whereas the gradient diffusion hypothesis is implied in JSPDF simulations. Yet, in JSPDF simulations, turbulent diffusion can be tuned by means of the turbulent Schmidt number. In the neck zone, where the turbulent flow field results deteriorate, the joint scalar PDF results are in somewhat better agreement with experimental data, for the test cases considered. In composition space, where results are reported as scatter plots, differences between the two PDF strategies are small in the calculations at hand, with a little more local extinction in the joint scalar PDF results.

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Section: Turbulence Modelmentioning

confidence: 99%

“…In order to achieve good agreement to experimental data for the turbulent flow field, in terms of radial profiles in physical space of mean velocities and velocity fluctuations, a second moment closure model is applied with modified model constants [4,20]. Good quality of the results is obtained up to the neck zone.…”

Section: Introductionmentioning

confidence: 99%

Joint Scalar versus Joint Velocity-Scalar PDF Simulations of Bluff-Body Stabilized Flames with REDIM

Merci

Naud

Roekaerts

et al. 2008

Flow Turbulence Combust

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“…As a result, the prediction of temperature profiles at downstream locations were not good. Li et al [16] investigated this flame using various differential Reynolds stress models with the equilibrium chemistry model. They reported that all the differential stress models in the standard form failed to reproduce the mean velocity, velocity fluctuations, mean mixture fraction and its variances.…”

Section: Introductionmentioning

confidence: 99%

A combustion model sensitivity study for CH₄/H₂ bluff-body stabilized flame

Hossain

Malalasekera

2007

Proceedings of the Institution of Mechanical Engineers, Part C:

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Citation: HOSSAIN, M. and MALALASEKERA, W., 2007 Abstract: The objective of the current work is to assess the performance of different combustion models in predicting turbulent non-premixed combustion in conjunction with the k−ε turbulence model. The laminar flamelet, equilibrium chemistry, constrained equilibrium chemistry, and flame sheet models are applied to simulate combustion in a CH 4 /H 2 bluff-body flame experimentally studied by the University of Sydney. The computational results are compared to experimental values of mixture fraction, temperature, and constituent mass fractions. The comparison shows that the laminar flamelet model performs better than other combustion models and mimics most of the significant features of the bluff-body flame.

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“…From the comparative study presented in [29] for the bluff-body flame HM1, the LRR-IPM Reynolds-stress model is used with the modified constant value C 1 = 1.6. Figure 1 shows that the mean flow field is reasonably well predicted as in [29,10].…”

Section: Flow Fieldsmentioning

confidence: 99%

Generalised Langevin Model in Correspondence with a Chosen Standard Scalar-Flux Second-Moment Closure

Naud

Merci

Roekaerts

2010

Flow Turbulence Combust

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In the context of transported joint velocity-scalar probability density function methods, the correspondence between Generalised Langevin Models (GLM) for Lagrangian particle velocity evolution and Eulerian Reynolds-stress turbulence models has been established in the 1990's by S.B. Pope. It was shown that the GLM representation of a given Reynolds stress model is not unique. It was also shown that a given GLM together with a given mixing model for particle composition evolution implies a differential scalar-flux model. In this paper, we study how extra constraints can be applied on the choice of the GLM coefficients in order to imply a chosen scalar-flux model. This correspondence between GLM-implied and standard scalar-flux models is based on the linear relaxation term and on the mean velocity gradient contributions in the rapid term. In general, GLM-implied models possibly involve more terms (including anisotropy effects in the scalar-flux decay rate and some high-order terms in the rapid-pressure-scrambling term). The proposed form of the GLM supposes a non-constant value for the diffusion coefficient C0, originally identified as a Kolmogorov constant. Here, the value of C0 is determined in order to yield the Monin model for linear relaxation of the scalar-flux, and the constant in the rapid-pressure contribution is related to the choice of the parameter β in the GLM. We finally show how GLM-implied scalar-flux models are in general dependent on the choice of the mixing model and how the proposed GLM can reduce this dependency. These developments are illustrated by results obtained from calculations of the Sydney bluff-body stabilised flame HM1.Response to Reviewers: First of all, we would like to thank the reviewers for their comments which helped to improve the paper. #1We included all the suggestions of Reviewer #1. About remark 5: we used the more general formalism introduced by Wouters [REF. 4] that allows to deal with variable density flows, and with Reynoldsstress models that include cubic terms (we added a remark in the text after Equation (27) at the beginning of Section 4.1). #2The remarks of Reviewer #2 allowed us to distinguish more clearly in the text two aspects: 1. setting the C_0 value depending on the Monin linear relaxation term and 2. removing the effect of the mixing model as much as possible. This lead to some modifications of the text. The modification of β in order to be in agreement with Launder's model for the rapid-pressure-scrambling term is indeed pragmatic. We added some clarifications on this aspect on page 12 in the paragraph "Rapid-pressure-scrambling term". About the "philosophical questions" raised by the reviewer, here are some remarks on the modification of C_0 in order to lead the Monin linear return to isotropy (the main contribution of this paper). As mentioned by the reviewer "the scalar field is dynamically passive". With Taylor's hypothesis, we see the relation between the Monin constant and the GLM coefficient C_0. As discussed in the paper, there is no re...

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Numerical Investigation of a Bluff-Body Stabilised Nonpremixed Flame with Differential Reynolds-Stress Models

Cited by 27 publications

References 22 publications

Joint Scalar versus Joint Velocity-Scalar PDF Simulations of Bluff-Body Stabilized Flames with REDIM

Joint Scalar versus Joint Velocity-Scalar PDF Simulations of Bluff-Body Stabilized Flames with REDIM

A combustion model sensitivity study for CH₄/H₂ bluff-body stabilized flame

Generalised Langevin Model in Correspondence with a Chosen Standard Scalar-Flux Second-Moment Closure

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Numerical Investigation of a Bluff-Body Stabilised Nonpremixed Flame with Differential Reynolds-Stress Models

Cited by 27 publications

References 22 publications

Joint Scalar versus Joint Velocity-Scalar PDF Simulations of Bluff-Body Stabilized Flames with REDIM

Joint Scalar versus Joint Velocity-Scalar PDF Simulations of Bluff-Body Stabilized Flames with REDIM

A combustion model sensitivity study for CH4/H2 bluff-body stabilized flame

Generalised Langevin Model in Correspondence with a Chosen Standard Scalar-Flux Second-Moment Closure

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A combustion model sensitivity study for CH₄/H₂ bluff-body stabilized flame