https://doi.org/10.1140/epjs/s11734-024-01374-1
Regular Article
Validation of a phase-field approach for contact line hysteresis against a sloshing droplet case
1
Computational Multiphase Flow Group, Technical University Darmstadt, 100190, Darmstadt, Hessen, Germany
2
ESA Propulsion Laboratory, European Space Agency, 10587, Darmstadt, Hessen, Germany
a
francisco.bodziony@tu-darmstadt.de
d
holger.marschall@tu-darmstadt.de
Received:
2
July
2024
Accepted:
17
October
2024
Published online:
4
November
2024
Understanding liquid propellants behavior in microgravity conditions is critical for efficient spacecraft design. For a number of operations, ranging from engine restart to orbital propellant storage and transfer, insight is needed to characterize capillary-dominated flows. In such conditions, surface tension and wetting properties, including contact angle hysteresis, can greatly impact the fluid’s behavior and therefore spacecraft performance. Using experimental data from ESA Propulsion Laboratory, a contact line model for the Cahn–Hilliard phase-field method is validated. The case studied is that of a droplet confined between two oscillating plates, which aims to isolate and observe contact angle-driven physics, limiting the effect of gravity on the flow in a simple and reproducible way on ground. The contact line model allows for the prediction of contact line motion without requiring the computation of dynamic contact angles or contact line velocities, thus simplifying implementation and reducing computational overhead. For the validation, contact line pinning and motion under varying oscillation frequencies is investigated. Specifically, the length between the rear and front contact line edges, as well as the shape of the sloshing droplet are compared. The results show good agreement between simulations and experimental data, confirming the model’s accuracy in predicting contact line behavior and pinning.
© The Author(s) 2024
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