A numerical study of evaporation characteristics of spherical n-dodecane droplets in high pressure nitrogen environment
22 Jun 2011-Physics of Fluids (American Institute of Physics Publising LLC)-Vol. 23, Iss: 6, pp 063601
TL;DR: In this paper, a model for evaporation of n-dodecane in a zero-gravity and high pressure nitrogen environment is presented, and the model is quantitatively validated using published experimental data.
Abstract: Evaporation of stagnant (zero relative velocity) as well as moving spherical droplets of n-dodecane in a zero-gravity and high pressure nitrogen environment is modeled. The non-ideal effects, solubility of ambient gas into the liquid-phase, variable thermo-physical properties, and gas- and liquid-phase transients are included in the model. The model is quantitatively validated using published experimental data. Numerical predictions show that, for stagnant droplets at sub-critical ambient temperatures, the droplet lifetime continuously increases with pressure, while at critical temperature, the lifetime initially increases and thereafter remains almost constant. At super-critical temperatures, the lifetime decreases continuously with increasing ambient pressure and the average evaporation constant shows a local maximum at a particular ambient pressure. In the case of moving droplets, at super-critical ambient temperature, the rate of increase of average evaporation constant with ambient pressure becomes significant as the initial droplet relative velocity increases. For low initial velocities (<1 m/s), the average evaporation constant gradually increases with ambient pressure and subsequently levels-off with further increase in ambient pressure. The droplet lifetime decreases with increase in ambient pressure or initial velocity. Penetration distance of the moving droplets decreases with ambient pressure and increases with initial droplet relative velocity. The mechanisms influencing the differences in evaporation under varying conditions of pressure and temperature are discussed.
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TL;DR: In this article, a two-phase model for Eulerian large-eddy simulations of liquid-fuel injection and mixing at high pressure is presented and evaluated for the Spray A benchmark case of the Engine Combustion Network (ECN) and three additional operating conditions are found to agree very well with available experimental data.
101 citations
Cites methods from "A numerical study of evaporation ch..."
...…temperature and pressure using the two-phase model and the fully-conservative formulation of the governing equations. c e t p c ( w e c l o 1 i t g a t p a t r c ( t 2 s N r e t s alibrating the binary interaction parameter for the PR EOS, see, .g., Balaji et al. (2011) and Qiu and Reitz (2015) ....
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TL;DR: In this paper, the authors investigated the heat and mass transfer of deformable droplets in turbulent flows and found that the mass transfer is crucial to cloud dynamics and internal combustion engines.
Abstract: The heat and mass transfer of deformable droplets in turbulent flows is crucial to a wide range of applications, such as cloud dynamics and internal combustion engines. This study investigates a dr ...
32 citations
Cites methods from "A numerical study of evaporation ch..."
...We choose the Peng–Robinson (PR) EOS which has shown as a suitable EOS to represent hydrocarbon fluids close to the critical point (Balaji et al. 2011)....
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TL;DR: In this article, the effects of ambient temperature, pressure and relative velocity between droplet and airflow on evaporation characteristics of multi-component droplet were investigated numerically, and the results showed that, present model predicts satisfactory results when compares with experimental data.
20 citations
Posted Content•
TL;DR: In this paper, a detailed multi-species two-phase thermodynamic equilibrium model for large-eddy simulations (LES) of liquid-fuel injection and mixing at high pressure is presented and evaluated.
Abstract: We present and evaluate a detailed multi-species two-phase thermodynamic equilibrium model for large-eddy simulations (LES) of liquid-fuel injection and mixing at high pressure. The model can represent the coexistence of supercritical states and multicomponent subcritical two-phase states. LES results for the transcritical Spray A of the Engine Combustion Network (ECN) are found to agree very well to available experimental data. We also address well-known numerical challenges of trans- and supercritical fluid mixing and compare a fully conservative formulation to a quasi conservative formulation of the governing equations. Our results prove physical and numerical consistency of both methods on fine grids and demonstrate the effects of energy conservation errors associated with the quasi conservative formulation on typical LES grids.
18 citations
Cites methods from "A numerical study of evaporation ch..."
...Standard LPT methods are very efficient computationally, but neglect real-gas effects and dissolved ambient gases in the liquid fuel phase, which become substantial at high pressures (Balaji et al. 2011; Qiu & Reitz 2015)....
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TL;DR: In this paper, the behavior of laminar liquid jet in its own vapor as well as supercritical fluid environment is conducted and the study of liquid jet injection into nitrogen (N2) environment is carried out at supercritical conditions.
Abstract: In the present experimental work, the behavior of laminar liquid jet in its own vapor as well as supercritical fluid environment is conducted. Also the study of liquid jet injection into nitrogen (N2) environment is carried out at supercritical conditions. It is expected that the injected liquid jet would undergo thermodynamic transition to the chamber condition and this would alter the behavior of the injected jet. Moreover at such conditions there is a strong dependence between thermodynamic and fluid dynamic processes. Thus the thermodynamic transition has its effect on the initial instability as well as the breakup nature of the injected liquid jet. In the present study, the interfacial disturbance wavelength, breakup characteristics, and mixing behavior are analysed for the fluoroketone liquid jet that is injected into N2 environment as well as into its own vapor at subcritical to supercritical conditions. It is observed that at subcritical chamber conditions, the injected liquid jet exhibits classical liquid jet characteristics with Rayleigh breakup at lower Weber number and Taylor breakup at higher Weber number for both N2 and its own environment. At supercritical chamber conditions with its own environment, the injected liquid jet undergoes sudden thermodynamic transition to chamber conditions and single phase mixing characteristics is observed. However, the supercritical chamber conditions with N2 as ambient fluid does not have significant effect on the thermodynamic transition of the injected liquid jet.
18 citations
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456 citations
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