What question did this study set out to answer?

The aim is to numerically investigate the dynamics of drop formation, detachment, and post-detachment oscillations.

April 10, 2026Open Access

Dynamics and Control of Drop Formation, Detachment, and Post-Detachment Oscillations-Computational Simulation, Using a Conservative Phase Field Model in Lattice Boltzmann Method

Key Points

The aim is to numerically investigate the dynamics of drop formation, detachment, and post-detachment oscillations.
Used the Lattice Boltzmann Method combined with a Conservative Phase Field model.
Analyzed drops at a non-capillary nozzle under very low velocity conditions.
Controlled parameters included Reynolds, Bond, and Capillary numbers.
Complex dynamics influenced by inertia, viscosity, gravity, and surface tension were observed.
Detachment of the drop led to transverse oscillations, impacting future drop formation and negating axisymmetric assumptions.

Abstract

This research numerically studies the dynamics and control of formation, detachment, and post-oscillations of a two-dimensional drop, using the Lattice Boltzmann Method (LBM) with a Conservative Phase Field (CPF) model. The problem is formulated for drop formation and detachment at a non-capillary nozzle with very low velocity. Reynolds (Re), Bond (Bo), and Capillary (Ca) numbers are used for control purposes. The results, validated by comparison with previous studies, show complex dynamics influenced by inertia, viscosity, gravity, and surface tension. Drop detachment induces transverse oscillations, affecting subsequent drop formation and limiting axisymmetric assumptions.

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Dynamics and Control of Drop Formation, Detachment, and Post-Detachment Oscillations-Computational Simulation, Using a Conservative Phase Field Model in Lattice Boltzmann Method

Key Points

Abstract

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