Collisions of drops with an immiscible liquid jet

Carole Planchette; Sylvain Petit; Hannes Hinterbichler; Günter Brenn

doi:10.1103/PhysRevFluids.3.093603

Collisions of drops with an immiscible liquid jet

Carole Planchette^*, Sylvain Petit, Hannes Hinterbichler, Günter Brenn

^*Corresponding author for this work

Institute of Fluid Mechanics and Heat Transfer (3210)

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate the collisions of a regular stream of drops with a continuous immiscible liquid jet. By varying the jet and drop diameters, their velocities, and relative orientation, we observe a broad variety of liquid structures, some of which have a high applicability for capsule and advanced fiber production. First, these structures are described and classified into four regimes that account for potential liquid fragmentation and the resulting liquid distribution. Fragmentation mechanisms are proposed based on a physical analysis accounting for the problem geometry, the system inertia, and the system's surface energy. Corresponding dimensionless numbers are built, which are used to draw two-dimensional regime maps that can very well distinguish the experimental outcomes. Finally, the effects of viscosity, qualitatively evidenced by employing various liquid pairs, are discussed.

Original language	English
Article number	093603
Number of pages	14
Journal	Physical Review Fluids
Volume	3
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevFluids.3.093603
Publication status	Published - Sept 2018

Keywords

drop
jet
fragmentation
encapsulation
coalescence
collision
wetting
multiphase

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10.1103/PhysRevFluids.3.093603

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abstract = "We investigate the collisions of a regular stream of drops with a continuous immiscible liquid jet. By varying the jet and drop diameters, their velocities, and relative orientation, we observe a broad variety of liquid structures, some of which have a high applicability for capsule and advanced fiber production. First, these structures are described and classified into four regimes that account for potential liquid fragmentation and the resulting liquid distribution. Fragmentation mechanisms are proposed based on a physical analysis accounting for the problem geometry, the system inertia, and the system's surface energy. Corresponding dimensionless numbers are built, which are used to draw two-dimensional regime maps that can very well distinguish the experimental outcomes. Finally, the effects of viscosity, qualitatively evidenced by employing various liquid pairs, are discussed.",

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AU - Planchette, Carole

AU - Petit, Sylvain

AU - Hinterbichler, Hannes

AU - Brenn, Günter

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AB - We investigate the collisions of a regular stream of drops with a continuous immiscible liquid jet. By varying the jet and drop diameters, their velocities, and relative orientation, we observe a broad variety of liquid structures, some of which have a high applicability for capsule and advanced fiber production. First, these structures are described and classified into four regimes that account for potential liquid fragmentation and the resulting liquid distribution. Fragmentation mechanisms are proposed based on a physical analysis accounting for the problem geometry, the system inertia, and the system's surface energy. Corresponding dimensionless numbers are built, which are used to draw two-dimensional regime maps that can very well distinguish the experimental outcomes. Finally, the effects of viscosity, qualitatively evidenced by employing various liquid pairs, are discussed.

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KW - jet

KW - fragmentation

KW - encapsulation

KW - coalescence

KW - collision

KW - wetting

KW - multiphase

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JO - Physical Review Fluids

JF - Physical Review Fluids

IS - 9

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ER -

Collisions of drops with an immiscible liquid jet

Abstract

Keywords

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