2015
DOI: 10.1063/1.4919809
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A computational study of droplet evaporation with fuel vapor jet ejection induced by localized heat sources

Abstract: A computational study of droplet evaporation with fuel vapor jet ejection induced by localized heat sources Droplet evaporation by a localized heat source under microgravity conditions was numerically investigated in an attempt to understand the mechanism of the fuel vapor jet ejection, which was observed experimentally during the flame spread through a droplet array. An Eulerian-Lagrangian method was implemented with a temperaturedependent surface tension model and a local phase change model in order to effec… Show more

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Cited by 7 publications
(4 citation statements)
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“…Finally, it is important to point out that the suppression of surface tension forces adopted in this work could in principle affect the internal motion in the liquid phase, because of the different the tangential shear stress at the interface. However, our comparative analyses in this sense, not reported in this work, show that the results obtained with DropletSMOKE++ are in a reasonable agreement both with experimental [66,67] and numerical [36,68] works not based on the VOF methodology. These investigations are still preliminary, but indicate that even neglecting surface tension the internal circulation phenomenon can be quantitatively and qualitatively captured with a reasonable accuracy.…”
Section: Numerical Results and Discussionsupporting
confidence: 66%
“…Finally, it is important to point out that the suppression of surface tension forces adopted in this work could in principle affect the internal motion in the liquid phase, because of the different the tangential shear stress at the interface. However, our comparative analyses in this sense, not reported in this work, show that the results obtained with DropletSMOKE++ are in a reasonable agreement both with experimental [66,67] and numerical [36,68] works not based on the VOF methodology. These investigations are still preliminary, but indicate that even neglecting surface tension the internal circulation phenomenon can be quantitatively and qualitatively captured with a reasonable accuracy.…”
Section: Numerical Results and Discussionsupporting
confidence: 66%
“… whereby u is the velocity, ρ the density, t the time, p the pressure, g the gravitational acceleration, τ the stress tensor, c the specific heat, and k the thermal conductivity. The source term S m of Equation (6) accounts for the phase change, and is given by [ 29 ]: whereby . The expression h ( T e − T g ) represents the heat transferred between the droplet and gas, and, thus, h ( T e − T g )/ L v represents the mass transfer per unit area along the interface.…”
Section: Numerical Implementationmentioning
confidence: 99%
“…whereby u is the velocity, ρ the density, t the time, p the pressure, g the gravitational acceleration, τ the stress tensor, c the specific heat, and k the thermal conductivity. The source term S m of Equation ( 6) accounts for the phase change, and is given by [29]:…”
Section: Transport Equationsmentioning
confidence: 99%
“…For the evaporating surface, tracking the droplet fluid-air-interface remains important. In the numerical treatment, an approach of moving mesh incorporating the Arbitrary Lagrangian-Eulerian (ALE) technique becomes fruitful as compared to that utilized volume of fluid technique 18 . Heating and flow are coupled and incompressible flow situation is considered.…”
Section: Mathematical Analysis and Numerical Solutionmentioning
confidence: 99%