Zwertvaegher Ingrid, Lamare Aude, Douzals Jean-Paul, Balsari Paolo, Marucco Paolo, Grella Marco, Caffini Amedeo, Mylonas Nikos, Dekeyser Donald, Foqué Dieter, Nuyttens David
Flanders Research Institute for Agriculture, Fisheries and Food, Technology and Food Science Unit, Merelbeke, Belgium.
Institut National de Recherche pour l'Agriculture, l'Alimentation, et l'Environnement - UMR ITAP - Université de Montpellier, Montpellier, France.
Pest Manag Sci. 2022 Apr;78(4):1729-1739. doi: 10.1002/ps.6792. Epub 2022 Jan 25.
Pesticide losses and uneven spray distribution should be avoided as much as possible as they reduce the effectiveness of spraying and increase environmental contamination as well as costs. Within the H2020-project OPTIMA the goal is to develop a smart sprayer for bed-grown carrots, including optimizations such as air support and variable nozzle spacing. This paper focuses on selecting the most optimal nozzle types, spacing and height for spraying bed-grown crops, while taking into account different target zone widths depending on the growth stage, based on spray distribution and droplet characterization measurements.
The results indicate that four bed spray configurations consisting of four nozzles per bed, i.e. XR8004/XR8004/XR8004/XR8004, AIUB8504/AI11004/AI11004/AIUB8504, AI8004/AI8004/AI8004/AI8004 and XR8002/XR8002/XR8002/XR8002, spraying at 300 kPa and recalculated to 12.0 km h forward speed, are appropriate for spraying different target zone widths (ranging from 1.2 to 2.2 m) with high uniformity (CV < 12%) and minimal losses out of the target zone (<17%) when applied at the most appropriate nozzle spacing and height (varying from 0.35 to 0.65 m). Droplet characterization measurements showed that for the same nozzle size and spray pressure, air inclusion nozzles produced larger but slower droplets than standard flat-fan nozzles. Air support increased the droplet velocities but had only a very limited effect on droplet size.
Laboratory spray distribution and droplet characterization measurements allowed selection of the most optimal nozzle type, spacing and height for bed spray applications in terms of reduced pesticide losses compared to conventional broadcast applications. © 2022 Society of Chemical Industry.
应尽可能避免农药损失和喷雾分布不均,因为它们会降低喷雾效果,增加环境污染以及成本。在H2020项目OPTIMA中,目标是开发一种用于种植在苗床上的胡萝卜的智能喷雾器,包括如空气辅助和可变喷嘴间距等优化措施。本文基于喷雾分布和液滴特性测量,在考虑不同生长阶段目标区域宽度不同的情况下,重点研究为苗床种植作物喷雾选择最优的喷嘴类型、间距和高度。
结果表明,每床由四个喷嘴组成的四种苗床喷雾配置,即XR8004/XR8004/XR8004/XR8004、AIUB8504/AI11004/AI11004/AIUB8504、AI8004/AI8004/AI8004/AI8004和XR8002/XR8002/XR8002/XR8002,在300kPa压力下喷雾并重新计算为12.0km/h的前进速度时,适用于喷雾不同目标区域宽度(范围为1.2至2.2m),在最合适的喷嘴间距和高度(0.35至0.65m不等)下应用时具有高均匀性(变异系数<12%)且目标区域外损失最小(<17%)。液滴特性测量表明,对于相同的喷嘴尺寸和喷雾压力,空气混入式喷嘴产生的液滴更大但速度更慢,比标准扁平扇形喷嘴慢。空气辅助增加了液滴速度,但对液滴大小的影响非常有限。
与传统的全面喷洒应用相比,实验室喷雾分布和液滴特性测量能够选择出用于苗床喷雾应用的最优喷嘴类型、间距和高度,以减少农药损失。©2022化学工业协会。
