Analogous Charging Effect of Surfactant-Pesticide Spray Jet on Droplet Characteristics and Deposition on Hydrophobic Leaf Surfaces

S. Appah, Eric Amoah Asante, Christopher Amigangre Ayambire
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Abstract

An induction charging principle had been applied to enhance spray droplet characteristics and quantity deposition on hydrophobic abaxial-adaxial leaf surfaces from pesticide EC Glyphosate [C3H8NO5P] and surfactant Silwet L-77 [C13H34O4Si3] formulations. A nozzle cap containing two electrodes (spacing at 9 mm apart) was used to superpose charges to spray droplets under applied voltages of 2–12 kV in an electric field (E) of 8.9 × 105 V/m. From a tee-jet flat fan (TP11004VS) nozzle tip fitted into the electrode cap and positioned at 60 cm high above targeted Brassica campestris leave surfaces, the spray droplets were directed onto the leaves at a liquid flow pressure of 4 bar and travelling speed of 2 m/s. The measurements were done using Keithsley picoammeter to quantify spray chargeability (CMR), droplet sizes by lesser particle size analyzer (LPSA) and deposition on leaf surfaces by high-speed camera. In effect, droplet sizes of EC, L-77 and EC + L-77 decreased with an increasing applied voltage. The CMR of L-77 was lower than EC and highest for EC + L-77 composite solution. Based on Image analysis of droplets density per leaf area, maximum exposure of adaxial leaf surfaces intercepted many charged spray droplets than abaxial surfaces. As regressed, the quantity of charged spray deposition from EC + L-77 formulation was highest at both adaxial (approx. 27.44 Qd/cm2) and abaxial (approx. 5.57 Qd/cm2) hydrophobic leaf surfaces than EC of 26.12: 3.19 Qd/cm2 and L-77 of 24.80: 2.53 Qd/cm2, respectively. Also, contact angle, Theta E, of charged spray droplets was smaller than Theta C on adaxial than abaxial leave surfaces, a phenomenon attributed to high chemo-electrical properties of formulations that aided the direct flight, coiling and deposition of droplets in order of EC > EC + L-77 > L-77. Generally, there was no observable droplet rebound; hence, surfactant-pesticide composite spraying is considered suitable for electrostatic application in plant protection technology. Therefore, for effective application, charged droplets from glyphosate EC in silwet L-77 solution should be recommended, as it provides optimum droplet sizes, chargeability, contact angle and deposition on hydrophobic leave surfaces.
表面活性剂-杀虫剂喷雾射流对液滴特性和在疏水性叶片表面沉积的类比充电效应
应用感应充电原理提高了农药草甘膦[C3H8NO5P]和表面活性剂Silwet L-77 [C13H34O4Si3]制剂在疏水性叶片背面的喷雾液滴特性和沉积量。在 8.9 × 105 V/m 的电场 (E) 中,使用包含两个电极(间距为 9 mm)的喷嘴帽在 2-12 kV 的外加电压下对喷雾液滴叠加电荷。喷雾液滴从安装在电极帽上的三叶扁平风扇(TP11004VS)喷嘴喷出,喷嘴位于目标甘蓝叶片表面上方 60 厘米处,液流压力为 4 巴,流速为 2 米/秒。测量使用 Keithsley 微微安培计量化喷雾电荷率(CMR),使用较小粒度分析仪(LPSA)量化液滴大小,并使用高速照相机测量叶片表面的沉积情况。实际上,随着施加电压的增加,EC、L-77 和 EC + L-77 的液滴尺寸都有所减小。L-77 的 CMR 低于 EC,而 EC + L-77 复合溶液的 CMR 最高。根据每叶面积液滴密度的图像分析,叶片正面最大暴露量比背面截获的带电喷雾液滴多。回归结果表明,EC + L-77 配方在疏水性叶片正面(约 27.44 Qd/cm2)和背面(约 5.57 Qd/cm2)的带电喷雾沉积量最高,分别为 EC 26.12:3.19 Qd/cm2,L-77 24.80:2.53 Qd/cm2。此外,带电喷雾液滴在叶片正面的接触角 Theta E 小于叶片背面的 Theta C,这种现象归因于制剂的高化学电特性,有助于液滴的直接飞行、卷绕和沉积,其顺序为 EC > EC + L-77 > L-77。一般来说,没有观察到液滴反弹现象;因此,表面活性剂-杀虫剂复合喷洒被认为适用于植物保护技术中的静电应用。因此,为了有效施药,应推荐使用硅湿 L-77 溶液中的草甘膦乳油带电液滴,因为它能提供最佳的液滴大小、带电性、接触角和在疏水性叶片表面的沉积。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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