Numerical simulation of spray break-up from cavitating nozzle flow by combined Eulerian–Eulerian and volume-of-fluid methods

Edelbauer, Wilfried; Kolar, Patrick; Schellander, David; Pavlović, Zoran; Almbauer, Raimund

doi:10.2495/cmem-v6-n2-314-325

Cited by 2 publications

(1 citation statement)

References 20 publications

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“…The model is applied to a gas assisted atomizer, showing proper matching of the results in Probability Density Function (PDF) of the scales larger than the grid size, while the smaller ones ae not properly represented. Edelbauer et al [13] performed another Volume-Of-Fluid simulation on an AdBlue dosing unit, whose purpose was to predict droplet breakup and couple the resulting droplets into an Eulerian-Lagrangian framework. From the three nozzles that composed the unit, only one was simulated to further increase the mesh resolution.…”

Section: Introductionmentioning

confidence: 99%

Mixture Model Approach for the Study of the Inner Flow Dynamics of an AdBlue Dosing System and the Characterization of the Near-Field Spray

Payri

Martí-Aldaraví

Marco-Gimeno

2021

SAE Technical Paper Series

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Selective Catalytic Reduction stands for an effective methodology for the reduction of NOx emissions from Diesel engines and meeting current and future EURO standards. For it, the injection of Urea Water Solution (UWS) plays a major role in the process of reducing the NOx emissions. A LES approach for turbulence modelling allows to have a description of the physics which is a very useful tool in situations where experiments cannot be performed. The main objective of this study is to predict characteristics of the flow of interest inside the injector as well as spray morphology in the near field of the spray. For it, the nozzle geometry has been reconstructed from X-Ray tomography data, and an Eulerian-Eulerian approach commonly known as Mixture Model has been applied to study the liquid phase of the UWS with a LES approach for turbulence modeling. The injector unit is subjected to typical low-pressure working conditions. The results extracted from it comprise parameters that characterize the hydraulic behavior as well as jet intact length. The conclusions drawn from the model depict differences in the flow behavior between the injector three orifices, with an under-prediction of nozzle and spray characteristics of LES formulation with respect to traditional RANS turbulence treatment.

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Section: Introductionmentioning

confidence: 99%

Mixture Model Approach for the Study of the Inner Flow Dynamics of an AdBlue Dosing System and the Characterization of the Near-Field Spray

Payri

Martí-Aldaraví

Marco-Gimeno

2021

SAE Technical Paper Series

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Numerical Simulation and Experimental Research of Cavitation Jets in Dual-Chamber Self-Excited Oscillating Pulsed Nozzles

Shi

Xing

Wang

et al. 2022

Shock and Vibration

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Self-excited oscillating pulsed cavitation jet has many advantages, such as easy operation, simply maintenance, and low investment costs. Based on the structural parameters of the traditional Helmholtz and organ pipe single-chamber self-excited oscillating pulsed nozzles, Helmholtz + Helmholtz, organ pipe + organ pipe, and Helmholtz + organ pipe dual-chamber self-excited oscillating pulsed nozzles with different structures are established in series, and the internal flow field of the dual chamber is studied to obtain the best combination nozzle by comparing numerical simulation and erosion experiments. The results indicate that the cleaning effect is the best when adopting the combined structure of Helmholtz + organ pipe, which brings out the largest volume fraction of the nozzle cavity with higher gas content and higher kinetic energy with larger jet velocity. By comparing the erosion experiments, it is found that the flushing area and erosion depth of the nozzle with the ratio of cavity and wall (D/a) of 2.50 is significantly higher than the nozzle with the ratio of cavity and wall (D/a) of 5.00. The pulse pressure of the flushing target increases by 0.0044 MPa, the pressure amplitude of the former changes significantly in the same cavitation cycle, and the cleaning effect is best.

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Numerical simulation of spray break-up from cavitating nozzle flow by combined Eulerian–Eulerian and volume-of-fluid methods

Cited by 2 publications

References 20 publications

Mixture Model Approach for the Study of the Inner Flow Dynamics of an AdBlue Dosing System and the Characterization of the Near-Field Spray

Mixture Model Approach for the Study of the Inner Flow Dynamics of an AdBlue Dosing System and the Characterization of the Near-Field Spray

Numerical Simulation and Experimental Research of Cavitation Jets in Dual-Chamber Self-Excited Oscillating Pulsed Nozzles

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