Damping of three-dimensional waves on coating films dragged by moving substrates

Paints and coatings often feature interfacial defects due to disturbances during the deposition process which, if they persist until solidification, worsen the product quality. In this article, we investigate the stability of a thin liquid film dragged by a vertical substrate moving against gravity, a flow configuration found in a variety of coating processes. The receptivity of the liquid film to three-dimensional disturbances is discussed with Direct Numerical Simulations (DNS), an in-house non-linear Integral Boundary Layer (IBL) film model, and Linear Stability Analysis (LSA). The thin film model, successfully validated with the DNS computations, implements a pseudo-spectral approach for the capillary terms that allows for investigating non-periodic surface tension dominated flows. The combination of these numerical tools allows for describing the mechanisms of capillary and non-linear damping, and identifying the instability threshold of the coating processes. The results show that transverse modulations can be beneficial for the damping of two-dimensional waves within the range of operational conditions considered in this study, typical of air-knife and slot-die coating.

Automated summary

In this article, the stability of a thin liquid film dragged by a vertical substrate moving against gravity is investigated in the context of coating processes. The receptivity of the film to three-dimensional disturbances is discussed using Direct Numerical Simulations, an in-house non-linear Integral Boundary Layer film model, and Linear Stability Analysis. The results show that transverse modulations can be beneficial for damping two-dimensional waves in air-knife and slot-die coating processes.