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Droplets breakup via a splitting microchannel

Wei Gao, Cheng Yu, Feng Yao

2020Chinese Physics B17 citationsDOI

Abstract

On the basis of a volume of fluid (VOF) liquid/liquid interface tracking method, we apply a two-dimensional model to investigate the dynamic behaviors of droplet breakup through a splitting microchannel. The feasibility and applicability of the theoretical model are experimentally validated. Four flow regimes are observed in the splitting microchannel, that is, breakup with permanent obstruction, breakup with temporary obstruction, breakup with tunnels, and non-breakup. The results indicate that the increase of the capillary number Ca provides considerable upstream pressure to accelerate the droplet deformation, which is favorable for the droplet breakup. The decrease of the droplet size contributes to its shape changing from the plug to the sphere, which results in weakening droplet deformation ability and generating the non-breakup flow regime.

Topics & Concepts

BreakupMicrochannelVolume of fluid methodMechanicsCapillary actionMaterials scienceFlow (mathematics)Capillary numberVolumetric flow rateDeformation (meteorology)MicrofluidicsPhysicsNanotechnologyComposite materialInnovative Microfluidic and Catalytic Techniques InnovationElectrowetting and Microfluidic TechnologiesFluid Dynamics and Heat Transfer
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