Spreading model of single droplet impacting the banana leaf surface and computational fluid dynamics simulation analysis.

[Display omitted] • The spreading model of pesticide droplets impacting on the surface of inclined banana leaves was constructed. • The dynamic behavior process of pesticide droplets impacting on the surface of banana leaves was revealed. • The CFD model of pesticide droplets impacting on the surface of banana leaves was established. • The spreading behavior of droplets impacting the surface of banana leaves was simulated by CFD. The droplet deposition behavior is an important indicator of precision agriculture and sustainable agriculture 4.0. Comprehensive analysis of the behavior and modeling of pesticide droplets impacting target leaves is an important basis for achieving efficient spray deposition. In this study, banana leaves were taken as the research object, the spreading model and computational fluid dynamics (CFD) model of single droplet impacting on the target leaf surface were studied from the micro and macro perspectives. The aim is to clarify and obtain the quantitative mapping relationship between droplet deposition performance and related operating parameters. The results showed that the pesticide droplets were asymmetrically spread and slipped on the surface of the inclined banana leaves. The maximum lateral spreading diameter D nmax was only affected by the normal component of Weber number We n , while the maximum tangential spreading diameter D tmax and slip distance L were affected by the normal component of Weber number We n and the inclination angle α. As the impact velocity increases, the pesticide droplets interact with the non-smooth morphology of the banana leaf surface to form a large number of pinning sites on the edge contact line. Combining the microscopic characteristics of banana leaves with the physicochemical characteristics of the droplets, a CFD model was established to carry out single-drop impact simulation verification. The impact velocity and inclination angle were set as variables to carry out CFD simulation of the dynamic process. The numerical simulation results are consistent with the spreading model obtained from the experimental study, which can quantitatively reflect the impact process of pesticide droplets. The spreading model and CFD model of pesticide droplets impacting on the banana leaf surface established in this study, can provide guidance for the selection of pesticide application for the spray droplet deposition behavior. At the same time, it can also provide methodological reference for other crop spray research and spray technology research in other fields. [ABSTRACT FROM AUTHOR]