Understanding liquid-jet atomization cascades via vortex dynamics
Arash Zandian, William A. Sirignano, Fazle Hussain

TL;DR
This study uses DNS to analyze vortex dynamics in liquid jet breakup, revealing mechanisms like hairpin vortex formation and their influence on atomization, across different flow regimes.
Contribution
It provides a detailed vortex dynamics perspective on liquid jet breakup mechanisms and their dependence on flow parameters, enhancing understanding of primary atomization.
Findings
Vortex dynamics explains hairpin formation and lobe perforation.
Perforation and corrugation are suppressed by high surface tension and viscosity.
Streamwise vorticity is generated mainly by vortex stretching and baroclinic torque.
Abstract
Temporal instabilities of a planar liquid jet are studied using direct numerical simulation (DNS) of the incompressible Navier-Stokes equations with level-set (LS) and volume-of-fluid (VoF) surface tracking methods. contours are used to relate the vortex dynamics to the surface dynamics at different stages of the jet breakup, namely, lobe formation, lobe perforation, ligament formation, stretching, and tearing. Three distinct breakup mechanisms are identified in the primary breakup, which are well categorized on the parameter space of gas Weber number () versus liquid Reynolds number (). These mechanisms are analyzed here from a vortex dynamics perspective. Vortex dynamics explains the hairpin formation, and the interaction between the hairpins and the Kelvin-Helmholtz (KH) roller explains the perforation of the lobes, which is attributed to the streamwise…
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