In order to reduce the use of chemical pesticides in crop plant protection and improve the utilization efficiency of pesticides, it is necessary to study advanced application machinery and application techniques. The use of unmanned aerial vehicle (UAV) for pesticide spraying has the characteristics of less application, strong penetrability, wide applicability and flexible operation scheduling, and has gradually become one of the important development directions in the field of aviation plant protection. However, the operation process of the UAV is often affected by meteorological factors and human manipulation, resulting in poor actual operation with inaccurate spray volume and uneven application. Therefore, to improve the stability and uniformity of the application of the plant protection UAV under variable operating conditions, in this paper a real-time control method was proposed for the application flow rate, and a precision variable-rate spray system was designed based on single-chip microcomputer and micro diaphragm pump that can controls the flow rate of the pump in real time with the changes of the operating state. The response s-peed of the variable-rate spray system was tested. The average control response time of the system was 0.18 s, and the average stability time of the pump flow change was 0.75 s. The test results showed that the system has a quick response to the working state and the adjustment of the target flow of the pump can be quickly completed to realize the variable-rate spray function. The research results can provide a reference for the practical application of plant protection UAV variable-rate spray system.
Keywords: UAV, plant protection, automatic control, spray system, variable-rate spray, precision application
DOI: 10.25165/j.ijabe.20191202.4701

Citation: Lian Q, Tan F, Fu X M, Liu X, Zhang P, Zhang W. Design of precision variable-rate spray system for unmanned aerial vehicle using automatic control method. Int J Agric & Biol Eng, 2019; 12(2): 29–35.

UAV, plant protection, automatic control, spray system, variable-rate spray, precision application

He X K, Improving severe draggling actuality of plant protection machinery and its application techniques. Transactions of the CSAE, 2004; 20(1): 13–15. (in Chinese)

Chen S D, Lan Y B, Li J Y, Zhou Z Y, Liu A M, Mao Y D. Effect of wind field below unmanned helicopter on droplet deposition distribution of aerial spraying. Int J Agric & Biol Eng, 2017; 10(3): 67–77.

Ministry of Agriculture of the People's Republic of China. Zero-growth action plan for pesticide use by 2020. 2015.3.18. (in Chinese)

Zhou Z Y, Zang Y, Luo X W, Lan Y B, Xue X Y. Technology innovation development strategy on agricultural aviation industry for plant protection in China. Transactions of the CSAE, 2013; 29(24): 1–10. (in Chinese)

Yang X J, Yan H R. Current Situation and Development Trend of Equipment for Crop Protection. Transactions of the CSAM, 2002; 33(6): 130–137. (in Chinese)

Kirk I W, Hoffmann W C, Fritz B K. Aerial application methods for increasing spray deposition on wheat heads. Applied Engineering in Agriculture, 2007; 23(6): 357–364.

Zhang J, He X K, Song J L, Zeng A J, Liu Y J, Li X F. Influence of spraying parameters of unmanned aircraft on droplets deposition. Transactions of the CSAM, 2012; 43(12): 94–96. (in Chinese)

Zhang D Y, Lan Y B, Chen L P. Current status and future trends of agricultural aerial spraying technology in China. Transactions of the CSAM, 2014; 45(10): 53–59. (in Chinese)

Tang Q, Zhang R R, Chen L P, Xu M, Yi T C, Zhang B, et al. Droplets movement and deposition of an eight-rotor agricultural UAV in downwash flow field. Int J Agric & Biol Eng, 2016; 9(5): 24–32

Yang F B, Xue X Y, Zhang L, Sun Z. Numerical simulation and experimental verification on downwash air flow of six-rotor agricultural unmanned aerial vehicle in hover. Int J Agric & Biol Eng, 2017; 10(4): 41–53.

Ramasamy M, Lee T E, Leishman J G. Flow field of a rotating-wing micro air vehicle. Journal of Aircraft, 2012; 44: 1236–1244.

Lan Y B, Chen S D, Fritz B K. Current status and future trends of precision agricultural aviation technologies. Int J Agric & Biol Eng, 2017; 10(3): 1–17.

Lan Y, Thomson S J, Huang Y B, Hoffmann W C, Zhang H H. Current status and future directions of precision aerial application for site-specific crop management in the USA. Computers and Electronics in Agriculture, 2010; 74(1): 34–38.

Andrews J. Variable rate spraying--not so far fetched. Farmers Weekly, 2010; 152(6): 64.

Deng W, Huang Y B, Zhao C J, Wang X, Liu J L. Spatial distribution visualization of PWM continuous variable-rate spray. Int J Agric & Biol Eng, 2013; 6(4): 1–8.

Maghsoudi H, Minaei S. A review of applicable methodologies for variable-rate spraying of orchards based on canopy characteristics. Journal of Crop Protection, 2014; 3(4): 531–542.

K Hu, Z Fu, R Ji, J Wang, Li J Q. Design and development of variable rate spraying system based on canopy volume measurement. IFIP Advances in Information & Communication Technology, 2016; 368: 402–413.

Chen Y, Ozkan E, Zhu H J, Derksen R, Krause C R. Spray deposition inside tree canopies from a newly developed variable-rate air-assisted sprayer. Transactions of the ASABE, 2013; 56(6): 1263–1272.

Han S, Hendrickson L, Ni B, Robert P C, Rust R H, Larson W E. A variable rate application system for sprayers. International Conference on Precision Agriculture, 2015.

Wang L, Lan Y B, Hoffmann W C, Fritz B K. Design of variable spraying system and influencing factors on droplets deposition of small UAV. Transactions of the CSAM, 2016; 47(1): 15–22. (in Chinese)

Wu T K, Zhou Y C, Xie P. Remote control variable rate sprayer controller system based on PWM. Journal of Agricultural Mechanization Research, 2017; 7: 76–82. (in Chinese)

Zhang J, Chen X. Multi-rotor UAV variable spray system. China Patent: 205131680. 2016-04-06. (in Chinese)

Yang J P, Zhu X P. Nonlinear flight control system design of bank-to-turn unmanned aerial vehicle. Acta Armamentarii, 2009; 30(11): 1504–1509. (in Chinese)

Li L, Long S C, Li H J, Zhang L Y. Precise point positioning based on reference station augmentation information. Acta Geodaetica et Cartographica Sinica, 2014; 43(5): 481–485, 492. (in Chinese)

Wu B T, Liu B, Li Y F, Zhang Y. Testing and Analysis on differential GPS aerial drones technology. Journal of Yangtze River Scientific Research Institute, 2017; 34(1): 142–144, 154. (in Chinese)

Yu Q F, Li Q, Lei Z H, Shang Y, Zhu X W, Liu X C. Methods and experiments of velocity measurement of UAV from image sequence. Acta Aeronautica et Astronautica Sinica, 2009; 30(8): 1503–1507. (in Chinese)

Gong X L, Fang J C, Sheng W. A method of intercalibration for GPS and high precision baro-altimeter on line. Journal of Electronics & Information Technology, 2009; 31(4): 818–821. (in Chinese)

GB/T 17997-2008, Pesticide sprayer field operation procedure and spray quality assessment. (in Chinese)

Civil Aviation Industry Standards of China: Part 1 Agricultural aviation operation quality technical indicators: MH/T 1002-1995. Beijing: Civil Aviation Administration of China, 1995; 11. (in Chinese)

Chen L J, Li Y K. Experimental research on respective cooling measure of glass greenhouse in summer. Journal of Agricultural Mechanization Research, 2010; 32(8): 142–145. (in Chinese)