Yallappa D, Kavitha R, Surendrakumar A, Suthakar B, Mohan Kumar A P, Kannan Balaji, Kalarani M K
Department of Farm Machinery and Power Engineering, Agricultural Engineering College and Research Institute, Tamil Nadu Agricultural University, Coimbatore, India.
Department of Soil and Water Conservation Engineering, Agricultural Engineering College and Research Institute, Tamil Nadu Agricultural University, Coimbatore, India.
Front Nutr. 2024 Dec 18;11:1487074. doi: 10.3389/fnut.2024.1487074. eCollection 2024.
Drones play a key role in enhancing nutrient management efficiency under climate change scenarios by enabling precise and adaptable spray applications. Current aerial spray application research is primarily focused on examining the influence of drone spraying parameters flight height, travel speed, rotor configuration, droplet size, payload, spray pressure, spray discharge and wind velocity on spray droplet deposition characteristics. The present study aimed to study and optimize the effect of spray height, operating pressure, nozzle spacing and spray nozzle mounting configuration on spray discharge rate, spray width, spray distribution pattern, spray uniformity and spray liquid loss. A spray patternator of 5.0 m x 5.0 m was developed per Bureau of Indian Standards (BIS) standard to study the spray volume distribution pattern of boom and hex nozzle configuration. Initially, drone spray operational parameters spray discharge rate (Lm), operating pressure (kg cm) and spray angle (°) were measured using digital nozzle tester, digital pressure gauge and digital protractor, respectively, in the laboratory. Then optimized the nozzle spacing for boom configuration attachment to drone sprayer and recorded best spray uniformity at 0.6 m nozzle spacing. The drone sprayer hovered at three different heights, 1.0, 2.0 and 3.0 m from the top of the patternator and spray operating pressure was maintained at 4.0 kg cm in outdoor condition. Single pass distribution pattern and one-direction application distribution pattern method used for optimizing height of spray, operating pressure and nozzle mounting confirmation from the results of discharge rate, spray angle, effective spray width, spray liquid loss and spray distribution uniformity. Results showed that, the better spray uniformity distribution was found when the drone sprayer hover height was increased from the top of the patternator (2.0 m). More round spray droplet vertex pattern was generated during the 1.0 m hover height compared to the 2.0 and 3.0 m hover heights due to the direct impact of downwash airflow generated by the rotors. Finally it was concluded that, the good spray volume distribution was found at 2.0 m height of spray with standard hexa nozzle configuration arrangement as compared to the boom spray nozzle arrangement.
在气候变化情景下,无人机通过实现精确且适应性强的喷雾应用,在提高养分管理效率方面发挥着关键作用。当前的航空喷雾应用研究主要集中于考察无人机喷雾参数(飞行高度、行进速度、旋翼配置、液滴大小、有效载荷、喷雾压力、喷雾流量和风速)对喷雾液滴沉积特性的影响。本研究旨在研究并优化喷雾高度、工作压力、喷嘴间距和喷嘴安装配置对喷雾流量、喷雾宽度、喷雾分布模式、喷雾均匀性和喷雾液体损失的影响。按照印度标准局(BIS)标准开发了一个5.0米×5.0米的喷雾模式仪,以研究喷杆和六孔喷嘴配置的喷雾体积分布模式。最初,在实验室中分别使用数字喷嘴测试仪、数字压力计和数字量角器测量无人机喷雾操作参数(喷雾流量(升/分钟)、工作压力(千克/平方厘米)和喷雾角度(度))。然后优化了喷杆配置与无人机喷雾器连接的喷嘴间距,并记录了在0.6米喷嘴间距时最佳的喷雾均匀性。在室外条件下,无人机喷雾器在距喷雾模式仪顶部1.0米、2.0米和3.0米这三个不同高度悬停,喷雾工作压力保持在4.0千克/平方厘米。根据喷雾流量、喷雾角度、有效喷雾宽度、喷雾液体损失和喷雾分布均匀性的结果,采用单程分布模式和单向应用分布模式方法来优化喷雾高度、工作压力和喷嘴安装确认。结果表明,当无人机喷雾器从喷雾模式仪顶部(2.0米)升高悬停高度时,喷雾均匀性分布更佳。与2.0米和3.0米悬停高度相比,在1.0米悬停高度时,由于旋翼产生的下洗气流的直接影响,产生了更多圆形喷雾液滴顶点模式。最后得出结论,与喷杆喷嘴配置相比,采用标准六孔喷嘴配置在2.0米喷雾高度时可实现良好的喷雾体积分布。
