H. Ettouati scite author profile

H. Ettouati

4Publications

18Citation Statements Received

36Citation Statements Given

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Affiliations

University of Monastir, École Normale Supérieure - PSL

Publications

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Numerical Simulation of Gas-Particles Two Phase Flow in Pipe of Complex Geometry: Pneumatic Conveying of Olive Cake Particles Toward a Dust Burner

Bounaouara¹,

Ettouati²,

Ticha³

et al. 2015

IJHT

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Two phase CFD calculations, using Eulerian-Lagrangian model with commercial Fluent 6.3 were employed to predict the gas and particle flow in pipe of complex geometry designed for pneumatic conveying of olive cake particles toward a pulverized burner. The numerical calculations were validated against experimental data from the literature. The effects of gas velocity and particles size distribution on the mixture flow behavior were studied. The present results help to understand the phenomena occurring in gas-solid flow and optimizing the conveying system.

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Radiative transfer effects of an axisymmetric particulate jet into a cylindrical pipe

et al. 2006

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Numerical modelling and simulation of pulverized solid‐fuel combustion in swirl burners

et al. 2009

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A finite-volume numerical model for computer simulation of pulverized solid-fuel combustion in furnaces with axisymmetric-geometry swirl burner is presented. The simulation model is based on the k − ε single phase turbulence model, considering the presence of the dispersed solid phase via additional source terms in the gas phase equations. The dispersed phase is treated by the particle source in cell (PSIC) method. Solid fuel particle devolatilization, homogenous and heterogeneous chemical reaction processes are modelled via a global combustion model. The radiative heat transfer equation is also resolved using the finite volume method. The numerical simulation code is validated by comparing computational and experimental results of pulverized coal in an experimental furnace equipped with a swirl burner. It is shown that the developed numerical code can successfully predict the flow field and flame structure including swirl effects and can therefore be used for the design and optimization of pulverized solid-fuel swirl burners.On présente un modèle numérique de volumes finis pour la simulation par ordinateur de la combustion de combustibles solides pulvérisés dans des fours munis de brûleurà tourbillon axisymétrique. Le modèle de simulation repose sur le modèle de turbulence monophasique k − ε, et décrit la présence de la phase solide dispersée par le biais de termes-sources additionnels dans leséquations de la phase gazeuse. La phase dispersée est traitée par la méthode PSIC. La dévolatilisation des particules combustibles solides et les procédés de réaction chimique homogène et hétérogène sont modélisésà l'aide d'un modèle de combustion global. L'équation de transfert de chaleur radiatif estégalement résolue par la méthode des volumes finis. Le code de simulation numérique aété validé en comparant les résultats des calculs par ordinateur avec des expériences pour du charbon pulvérisé dans un four expérimentaléquipé d'un brûleurà tourbillon. On montre que le code numérique peut prédire avec succès le champ d'écoulement et la structure de flamme y compris les effets tourbillonnaires et qu'il peut donc servirà la conception età l'optimisation des brûleursà tourbillons pour les combustibles solides pulvérisés.

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Radiative Heat Transfer in a Pulverized Coal Combustion Cylindrical Furnace

Boutoub

Ettouati

Benticha

et al. 2007

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H. Ettouati

Numerical Simulation of Gas-Particles Two Phase Flow in Pipe of Complex Geometry: Pneumatic Conveying of Olive Cake Particles Toward a Dust Burner

Radiative transfer effects of an axisymmetric particulate jet into a cylindrical pipe

Numerical modelling and simulation of pulverized solid‐fuel combustion in swirl burners

Radiative Heat Transfer in a Pulverized Coal Combustion Cylindrical Furnace

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