Litcius/Paper detail

Visualization of the evolution of bubbles in the spray sheet discharged from the air‐induction nozzle

Chen Gong, Dongyang Li, Can Kang

2022Pest Management Science28 citationsDOI

Abstract

BACKGROUND: The air-induction nozzle greatly reduces drift potential by increasing spray droplet size compared with a standard flat-fan nozzle. The current study aims to reveal the mechanism behind the formation of large droplets through the air-induction nozzle from the aspect of bubble evolution in the spray sheet. RESULTS: Bubble break-up leads directly to the formation of perforations because large bubbles reach both sides of the spray sheet. The surface disturbance induced by bubble break-up modulates spray sheet thickness, which indirectly leads to the generation of perforations. Compared with the spray pressure, nozzle configuration has a more significant effect on both the volumetric flow rate of intake air and the thickness of the spray sheet. As the nozzle is changed from ID-120-01 to ID-120-05, the volumetric flow rate of intake air increases by 801.30% at a spray pressure of 0.3 MPa, whereas spray sheet thickness increases by 412.50% at a radial distance of 10 mm. CONCLUSION: Bubble break-up is the main reason for the generation of perforations within an air-induction nozzle, leading to early break-up of the spray sheet and the production of large spray droplets. Bubble break-up can be effectively controlled by modifying the nozzle configuration.

Topics & Concepts

NozzleSpray nozzleSpray characteristicsBubbleMaterials scienceMechanicsLiquid bubbleFlow visualizationAirflowComposite materialFlow (mathematics)Mechanical engineeringPhysicsEngineeringPlant Surface Properties and TreatmentsFluid Dynamics and Heat TransferAerosol Filtration and Electrostatic Precipitation