Numerical simulation of gas–liquid flow behavior in the nozzle exit region of an effervescent atomizer

Sun, Chen; Ning, Zhi; Qiao, Xinqi; Lv, Ming; Fu, Junwei; Zhao, Jin; Wang, Xintao

doi:10.1177/1756827718821592

Cited by 9 publications

(1 citation statement)

References 26 publications

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“…Computational studies of effervescent atomizers have mainly concentrated on the nozzle exit region. Sun et al 14,15 investigated the internal flow in a converging effervescent nozzle exit region with 3d simulations. The internal flow pattern was noted to affect the fluctuation characteristics of the spray.…”

Section: Please Cite This Article As Doi:101063/50028963mentioning

confidence: 99%

Numerical study of bubbly flow in a swirl atomizer

et al. 2020

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In the present work, we extend our previous research on swirl nozzles by introducing bubbles at the nozzle inlet. A large-scale hollow cone pressure-swirl atomizer is studied using scale-resolving simulations. The present flow conditions target a Reynolds number range of 600 ≤ Re ≤ 910 and gas-to-total volumetric flow rate ratios between 0.07 ≤ β ≤ 0.33 with β = 0 as an experimental and computational reference. The computational setup has relevance to high-viscosity bio-fuel injection processes. Flow rate ratio and bubble diameter sweeps are carried out to study their effect on the inner-nozzle flow and the liquid film characteristics outside the nozzle. The present flow system is shown to pose highly versatile physics including bubble coalescence, bubble-vortex interaction, and faster liquid film destabilization relative to β = 0 case. The main results are as follows. (1) β is found to have a significant effect on the bimodal bubble volume probability density function (PDF) inside the swirl chamber. Also, the total resolved interfacial area of the near-orifice liquid film increases with β. (2) At representative value of β = 0.2, the exact bubble size at the inlet is observed to have only a minor effect on the swirl chamber flow and liquid film characteristics. (3) The bubble-free (β = 0) and bubbly (β > 0) flows differ in terms of effective gas core diameter, core intermittency features, and spray uniformity. The quantitative analysis implies that bubble inclusion at the inlet affects global liquid film characteristics with relevance to atomization.

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Section: Please Cite This Article As Doi:101063/50028963mentioning

confidence: 99%