Mohamed Si‐Ameur scite author profile

Direct numerical simulations (DNS) are performed to investigate mixing in free round coaxial jets. A great attention has been put on the influence of upstream conditions upon the global flow structure and the mixing process. The mixing behavior is studied through the spatial and temporal development of the mixture fraction of the annular and the inner fluids, and examined by means of flow visualization and statistics. It is shown that the turbulent mixing process and the mixture fraction field in coaxial jets depend on the upstream conditions, even though a quasi self-similar state is reached. The mixing alterations are explained by the understanding of the flow dynamics modifications implied by the different upstream conditions. These alterations are mainly due to the intense generation of streamwise vortices, favored by high inlet velocity gradients and velocity ratios, as well as low ratios between the inner and the outer jet diameters. This is associated with a high quality of mixing, as far as global mixedness is concerned. It is also shown that the annular fluid reaches the inner fluid and mixes swiftly into it. Conversely, the latter remains confined. Additionally, spots of pure unmixed species are observed at the end of the computational domain, and shown to be due to the annular jet.

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CFD Analysis of the Volute Geometry Effect on the Turbulent Air Flow through the Turbocharger Compressor

Chehhat

Si‐Ameur

Boumeddane

2013

Energy Procedia

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Mixing and coherent vortices in turbulent coaxial jets

Balarac¹,

Si‐Ameur²

2005

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Direct numerical simulations associated with mixing in constant-density round coaxial jets are performed. They are validated by comparison against laboratory experiments. The mixing process is studied by seeding a passive tracer first in the outer annular jet, then in the inner jet. We demonstrate the important role played by coherent vortices in the mixing mechanisms. The turbulent mixing exhibits an intermittent character as a consequence of fluid ejections caused by the counter-rotating streamwise vortices. We quantify also the domination of the outer jet and show that the fluid issuing from the central jet remains confined.

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Large Eddy simulation for lean premixed combustion

2012

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In comparison to previous numerical studies interested in the ORACLES benchmark (One Rig for Accurate Comparisons with Large Eddy Simulations), the present study demonstrates the advantages of LES-WALE model in both inert and reacting flows using the Fluent-CFD. So, the confirmation is based on the experimental research effort that was involved in the European Union-funded research program MOLECULES (Modelling of Low Emissions Combustors Using Large Eddy Simulations), for three parameters: longitudinal velocity, longitudinal velocity fluctuation, and length of recirculation zone. In line with what was observed by the experimental reference study, the dynamic model (LES-WALE) predicts, respectively, as well as the asymmetry and the symmetry, for both inert and reacting flows. In addition, the simulation succeeds to predict the zones of recirculation and shows the differences between the two cases, inert and reacting flows. Moreover, results have been compared with those of the k-ε model performed by Kurenkov and Obserlack [Kurenkov and Obserlack, Flow Turbulence Combustion 74, 387-407 (2005)] study.

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Mohamed Si‐Ameur

Enhanced heat and mass transfer in solar stills using nanofluids: A review

Direct numerical simulations of high velocity ratio coaxial jets: mixing properties and influence of upstream conditions

CFD Analysis of the Volute Geometry Effect on the Turbulent Air Flow through the Turbocharger Compressor

Mixing and coherent vortices in turbulent coaxial jets

Large Eddy simulation for lean premixed combustion

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