Design and Development of a Side Spray Device for UAVs to Improve Spray Coverage in Obstacle Neighborhoods

Electric multirotor plant protection unmanned aerial vehicles (UAVs) are widely used in China for efficient and precise plant protection at low altitude for low volumes. Unstructured farmland in China has various types of obstacles, and UAVs usually use a detour path to avoid obstacles due to flight...

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Bibliographic Details
Published inAgronomy (Basel) Vol. 14; no. 9; p. 2002
Main Authors Kong, Fanrui, Qiu, Baijing, Dong, Xiaoya, Yi, Kechuan, Wang, Qingqing, Jiang, Chunxia, Zhang, Xinwei, Huang, Xin
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2024
Subjects
Agricultural land
Altitude
Aviation
Drone aircraft
Droplets
Effectiveness
Energy consumption
Error analysis
Flight
Flight altitude
improved droplet coverage
Low altitude
Measurement methods
Neighborhoods
Obstacle avoidance
obstacle neighborhoods
Parameters
Pesticides
Plant protection
plant protection UAV
Position measurement
side spray device
Simulation models
Swath width
Unmanned aerial vehicles
Variance analysis
Wind effects
Wind measurement
China
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Summary:Electric multirotor plant protection unmanned aerial vehicles (UAVs) are widely used in China for efficient and precise plant protection at low altitude for low volumes. Unstructured farmland in China has various types of obstacles, and UAVs usually use a detour path to avoid obstacles due to flight altitude limitations. However, existing UAV spray systems do not spray when in obstacle neighborhoods during obstacle avoidance, resulting in insufficient droplet coverage and reduced plant protection quality in the area. To improve the droplet coverage in obstacle neighborhoods, this article carries out a study of side spray technology with an electric quadrotor UAV, and proposes the design and development of a side spray device. The relationship between the obstacle avoidance path of the UAV and the spray pattern of the side spray device and their effect on droplet coverage in obstacle neighborhoods was explored. An accurate measurement method of the relative position between the UAV and obstacles was proposed. Spray angle calculations and nozzle selection for the side spray device were carried out in conjunction with the relative position. A rotor wind field simulation model was designed based on the lattice Boltzmann method (LBM), and the spatial layout of the side spray device on the UAV was designed based on the simulation results. To explore suitable spray patterns for the side spray device, comparative experiments of droplet coverage in obstacle neighborhoods were carried out under different environments, spray patterns, and flight parameter combinations. The relationship between the flight parameter combinations and the distribution uniformity of droplets and the effective swath width of the side spray device was explored. The experimental results were analyzed by an analysis of variance (ANOVA) and a relationship model was obtained. The results showed that the side spray device can effectively improve droplet coverage in obstacle neighborhoods compared to a device without side spray using the same flight parameter combinations. The effective swath width in obstacle neighborhoods can be increased by a minimum of 6.35%, maximum of 35.32%, and average of 15.25% using the side spray device. The error between the predicted values of the relational model and the field experiment results was less than 15%. The results verify the effectiveness and rationality of the method proposed in this article. This study can provide technical and theoretical references for improving the plant protection quality of UAVs in obstacle environments.
ISSN:2073-4395
2073-4395
DOI:10.3390/agronomy14092002