Searching for a Numerical Model for Prediction of Pressure-Swirl Atomizer Internal Flow

Malý, Milan; Slama, Jaroslav; Cejpek, Ondřej; Jedelský, Jan

doi:10.3390/app12136357

Applied Sciences

2022

DOI: 10.3390/app12136357

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Searching for a Numerical Model for Prediction of Pressure-Swirl Atomizer Internal Flow

Milan Malý

Jaroslav Slama²,

Ondřej Cejpek

et al.

Abstract: Numerical prediction of discharge parameters allows design of a pressure-swirl atomizer in a fast and cheap manner, yet it must provide reliable results for a wide range of geometries and operating regimes. Many authors have used different numerical setups for similar cases and often concluded opposite suggestions on numerical setup. This paper compares 2D (two-dimensional) axisymmetric, 3D (three-dimensional) periodic and full 3D numerical models used for estimation of the internal flow characteristics of a p… Show more

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Cited by 5 publications

References 27 publications

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Gas–liquid and liquid–liquid vortex technology for process intensification

Kourou,

Chen,

Ouyang

2024

Current Opinion in Chemical Engineering

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Gas–liquid and liquid–liquid vortex technology for process intensification

Kourou,

Chen,

Ouyang

2024

Current Opinion in Chemical Engineering

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The Effects of Shape and Liquid Properties on Pressure Swirl Atomizer in-Nozzle Flow

Tonini,

Conti,

Cossali

2024

Atomiz Spr

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The internal flow in pressure swirl atomizers is numerically predicted by performing large eddy simulations and using a volume of fluid approach. The output of the numerical model is validated by comparing it with three databases of experimental measurements obtained on large-scale pressure swirl atomizers available in the open literature. A simplified analytical model previously developed by the authors, which relates the swirl intensity to the thickness of the fluid exiting the nozzle, is used to analyze the flow behavior in three pressure swirl atomizers, with large differences in the injector geometry, the operating conditions, and the fluid thermophysical properties. This simple relationship is found to hold for the three pressure swirl atomizers, with small changes of the parameter that accounts for energy losses, while data obtained with relatively small variations of the injector geometry are found to collapse on the same curve. The effects of operating conditions and fluid thermophysical properties on this relation are found to be irrelevant.

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An Improved Comprehensive Atomization Model for Pressure Swirl Atomizers

Qian,

Wang,

Hui

et al. 2024

Aerospace

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This study presents an improved comprehensive atomization model for a pressure swirl atomizer. The model integrates internal flow predictions, linear instability analysis of a swirling annular liquid sheet, primary atomization sub-model, and droplet velocity sub-model. Measurement data combined with the inviscid theory model predict the internal flow, providing liquid sheet velocity and thickness at the atomizer outlet. The dispersion relation of surface disturbances is obtained through linear instability analysis. A primary breakup predictive model for particle size distribution is constructed based on the wavelength and growth rate within the full unstable wavenumber range of the dispersion relation. Assuming uniform circumferential distribution and a normal distribution of spray angles, the droplet velocity is assigned according to the liquid sheet velocity. The model is implemented into Eulerian–Lagrangian simulations as initial conditions for discrete phase droplets to simulate the spray field. Results show the model can accurately predict the Sauter mean diameter with an error of less than 6% and effectively predicts the spray structure and spray cone angle. The dependency of the model on its parameters is also studied, determining that the values of the ligament constant and dispersion angle have an obvious impact on the prediction of Sauter mean diameter and spray structure.

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Searching for a Numerical Model for Prediction of Pressure-Swirl Atomizer Internal Flow

Cited by 5 publications

References 27 publications

Gas–liquid and liquid–liquid vortex technology for process intensification

Gas–liquid and liquid–liquid vortex technology for process intensification

The Effects of Shape and Liquid Properties on Pressure Swirl Atomizer in-Nozzle Flow

An Improved Comprehensive Atomization Model for Pressure Swirl Atomizers

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