A Water Droplet Pinning and Heat Transfer Characteristics on an Inclined Hydrophobic Surface

A water droplet pinning on inclined hydrophobic surface is considered and the droplet heat transfer characteristics are examined. Solution crystallization of polycarbonate is carried out to create hydrophobic characteristics on the surface. The pinning state of the water droplet on the extreme inclined hydrophobic surface (0 degrees <= delta <= 180 degrees, delta being the inclination angle) is assessed. Heat transfer from inclined hydrophobic surface to droplet is simulated for various droplet volumes and inclination angles in line with the experimental conditions. The findings revealed that the hydrophobic surface give rise to large amount of air being trapped within texture, which generates Magdeburg like forces between the droplet meniscus and the textured surface while contributing to droplet pinning at extreme inclination angles. Two counter rotating cells are developed for inclination angle in the range of 0 degrees < delta < 20 degrees and 135 degrees < delta < 180 degrees; however, a single circulation cell is formed inside the droplet for inclination angle of 25 degrees <= delta <= 135 degrees. The Nusselt number remains high for the range of inclination angle of 45 degrees <= delta <= 135 degrees. Convection and conduction heat transfer enhances when a single and large circulation cell is formed inside the droplet.