Dynamics of fluid–structure interaction in paintbrush

Fluid–structure interactions are fundamental in both natural phenomena and industrial applications, particularly in dip-coating processes where withdrawal velocity and drainage dynamics are crucial. Understanding these interactions is essential for optimizing various processes, from enhancing the ef...

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Bibliographic Details
Published in:Physics of fluids (1994) 2024-11, Vol.36 (11)
Main Authors: Moon, Seokmin, Ha, Jonghyun
Format: Article
Language:English
Subjects:
Assembly
Capillary flow
Complex systems
Dip coatings
Dynamics
Fluid-structure interaction
Immersion coating
Industrial applications
Viscous flow
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Summary:Fluid–structure interactions are fundamental in both natural phenomena and industrial applications, particularly in dip-coating processes where withdrawal velocity and drainage dynamics are crucial. Understanding these interactions is essential for optimizing various processes, from enhancing the efficiency of industrial coatings to developing advanced materials with tailored properties. Here, we examine the capillary-induced dynamics of fiber bundles using paintbrush-like structures. We submerge fiber bundles in water and withdraw them at various velocities, observing that water trapped within the bundles leads to capillary-driven fiber assembly. Our experiments show that the bundle diameter after emergence increases with higher withdrawal speed due to viscous effects. We develop a theoretical model that accurately predicts the dynamics of fiber assembly driven by capillary and viscous flows. The mathematical model agrees well with our experimental results, demonstrating the complex interplay between capillary forces and fiber packing. We anticipate that our findings improve the understanding of fluid-structure interactions in fibrous media, providing physical insights that can be applied to more complex systems such as nanopattern collapse and nano/micro-manufacturing.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0233298