Investigation
of the Different Regimes Associated
with the Growth of an Interface at the Exit of a Capillary Tube into
a Reservoir: Analytical Solutions and CFD Validation
posted on 2022-08-09, 20:00authored byAmgad Salama, Paul J. Van Geel, Jisheng Kou, Maen M. Husein
The emergence of a droplet from a capillary tube opening
into a
reservoir is an important phenomenon in several applications. In this
work, we are particularly interested in this phenomenon in an attempt
to highlight the physics behind droplet appearance. The emergence
of a droplet from a tube opening into a reservoir under quasi-static
conditions passes through three stages. The first stage starts when
the meniscus in the tube reaches the exit. At this moment, the meniscus
intersects the wall of the tube at the equilibrium contact angle.
The interface then develops until its radius of curvature becomes
equal to the tube radius. During this stage, the capillary pressure
increases. In the second stage, the interface continues to evolve
with its radius of curvature increasing until the static contact angle
with respect to the surface of the reservoir is achieved. This marks
the end of the second stage and the start of the third in which the
contact line (CL) starts to depart the tube opening along the reservoir
surface and the contact angle remains constant. Analytical models
for the three stages have been derived based on the law of conservation
of linear momentum. The models account for pressure, gravitational,
capillary, and viscous forces, while inertia force is ignored. The
model can predict the profiles of the mean velocity in the tube, the
capillary pressure, and the evolution of the contact angle. In addition,
a computational fluid dynamics (CFD) simulation has been conducted
to provide a framework for validation and verification of the developed
model. The CFD simulation shows qualitative behavior in terms of snapshots
of the emerging droplet with time similar to that speculated by the
analytical model. In addition, quantitative comparisons with respect
to velocity, pressure, and volume profiles of the droplet show very
good agreement, which builds confidence in the modeling approach.