In China, it is difficult for manned aircraft to sow seeds in small and scattered plots, especially in areas including hills, swamps, telegraph poles, windbreaks, and residential areas; in such terrain, the sowing machinery cannot function properly. However, unmanned helicopters (UHs) are flexible enough to control and adapt to the complex environments that are not easily accessible by terrain sowing machinery and large agricultural aircraft, which have been widely used in agriculture. In this study, a centrifugal disc-type sowing device for an unmanned helicopter (CDTSDUH) was designed. The factors influencing the seed velocity when the seeds move away from the disc were explored by analyzing the forces of the seed acting on the sowing disc and the wind field of the UHs. The influential factors include the distance from the falling mouth to the center of the disc, the offset angle of the falling mouth, and the rotation speed of the disc. An orthogonal test was designed with the sowing width and the curvature of the sowing area as the indexes. The test results showed that the three factors mentioned above had a greater impact on the sowing width than the curvature of the seeding area. Moreover, the superior parameters of the disc were determined. It was also suggested that the above factor levels had little effect on the offset width of sowing. The results of the test conducted for studying the sowing uniformity of the CDTSDUH indicated that the maximum and minimum difference values among the number of particles of the sampling points in the forward direction was 11 and 8, and the coefficient of variation of the number of particles in each row was more than 20%, indicating less uniformity was achieved when sowing in the lateral (perpendicular to the forward direction) direction, as compared to that in the forward direction. This study determined the ideal values for the radius of particles position, the offsetting angle, and the disc speed of the sowing machinery designed. Furthermore, considering that there are so many factors that influence the manner in which a UH functions, more analysis results and test data of influencing factors need to be acquired by experiments. The uniformity of sowing needs to be further improved. The results provided some theoretical and experimental references for the technology research on the centrifugal disc-type sowing device for UHs.
Keywords: sowing, unmanned helicopter, aircraft sowing, centrifugal disc, uniformity, sowing disc
DOI: 10.25165/j.ijabe.20181102.3757

Citation: Song C C, Zhou Z Y, Luo X W, Lan Y B, He X G, Ming R, et al. Design and test of centrifugal disc type sowing device for unmanned helicopter. Int J Agric & Biol Eng, 2018; 11(2): 55–61.

sowing, unmanned helicopter, aircraft sowing, centrifugal disc, uniformity, sowing disc

Luo X W. Thinking of speeding up the development of our country agricultural aviation technology. Agricultural Technology and Equipment, 2014; 5(281): 7–15. (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)

Zhang Y C. Sketch of the current development situation and technology innovation of the world agricultural aviation. Hunan Agricultural Mechinery, 2013; 4(2): 16–17. (in Chinese)

Zhang C. Development of the aircraft plant protection and agricultural aviation application technology in American. Journal of Era of Agricultural Machinery, 2015; 42(7): 168. (in Chinese)

Zhang Y. The application of remote control helicopter agriculture in Japan. World Agriculture, 1997; 4: 49–50. (in Chinese)

Zhang P, Zheng H G, Yu J X. Study on the improving technology of cold soak field in the high land area. Journal of Yunnan Agricultural University, 2005; 20(5): 665–670. (in Chinese)

Jiao J G, Zhang H J, He D L. Character and improving measures of cold spring paddy soil in China. Journal of Agricultural Science, 2012; 40(7): 4247–4248. (in Chinese)

Li C S, Tang Y L, Wu C, Huang G. Effect of sowing patterns on growth, development and yield formation of wheat in rice stubble land. Transactions of the CSAE, 2012; 28(18): 36–43. (in Chinese)

Tang Y L, Li C S, Wu C, Wu X L, Huang G, Ma X L. Effects of sowing patterns on establishment quality, grain yield and production benefit of intercropping wheat in hilly countries. Chinese Agricultural Science, 2013; 46(24): 5089–5097. (in Chinese)

Ren M E. Current Situation and Countermeasures of Mudflat Development and Utilization in China. Journal of Chinese Academy of Sciences, 1996; 14(6): 440–443. (in Chinese)

Wan T B. Marsh resources and its development and protection in China. Journal of World Environment, 1991; 1: 24–25. (in Chinese)

Yang M L, Bai R P, Liu M, Tu Z Q. Development of agricultural mechanization and construxtion of modern agriculture. Transactions of the CSAM, 2005; 36(7): 68–72. (in Chinese)

Chen D C, Liu W X. Discussion of the south rice mechanization production mode. Journal of Guangxi Agricultural Mechanization, 2000; 3: 4–6. (in Chinese)

You G W. Discussion on the development suggestions and the problems existing in the mechanization of rice production. Agricultural Machinery Use and Maintenance, 2015; 12: 22–23. (in Chinese)

Greipsson S, El-Mayas H. Large-scale reclamation of barren lands in iceland by aerial seeding. Land Degradation and Development, 1999; 10: 185–193.

Xiao X, Wei X H, Liu Y Q, Ouyang X Z. Aerial seeding: An effective

forest restoration method in highly degraded forest landscapes of sub-tropic regions. Forests, 2015; 6(6): 1748–1762.

Xu F. Apply and market prospect of agricultural plant protection UAV. Agricultural Equipment Technology, 2016; 42(1): 49–51. (in Chinese)

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.

Ruan X D. Agricultural UAV, the helper of modern agriculture. New Economy Weekly, 2015-04-05. (in Chinese)

Zhao D W, Meng Y. Research on the mechanized precision seeding technology. Agricultural Science & Technology and Equipment, 2010; 6: 58–60. (in Chinese)

He X K, Bonds J, Herbst A, Langenakens J. Recent development of unmanned aerial vehicle for plant protection in East Asia. Int J Agric & Biol Eng, 2017; 10(3): 18–30.

Pan S Q. Experimental study of the horizontal disc type spreader parts. Changchun: Jilin Agricultural University, 2004. (in Chinese)

Sun Q L, Zhao H L, Zhang X H. Current situation and development of seed sowing devices. Shandong Agricultural Mechinery, 2002; 2: 8–9. (in Chinese)

Du X Q, Xiao M H, Hu X Q, Chen J N, Zhao Y. Numerical simulation and experiment of gas-solid two-phase flow in cross-flow grain cleaning device. Transactions of the CSAE, 2014; 30(3): 27–34. (in Chinese)

Li J Y, Zhou Z Y, Hu L, Zang Y, Xu S, Liu A M. Optimization of operation parameters for supplementary pollination in hybrid rice breeding using round multi-axis multi-rotor electric unmanned helicopter. Transaction of the CSAE, 2014; 30(11): 1–9. (in Chinese)

Zhao Y N, Sun Y Z, Mo D J. Research and development of a gas flow sensor with suspending gyrorotor. Journal of Beijing University of Chemical Technology, 1998; 25(4): 67–72. (in Chinese)

Hu L, Zhou Z Y, Luo X W, Wang P, Yang Y A, Li J Y. Development and experiment of a wireless wind speed sensor network measurement system for unmanned helicopter. Transactions of the CSAM, 2014; 45(5): 221–226. (in Chinese)

Deng C X, Tao D C, Gao J P. Dynamic characteristics and factors affecting performance of air-stream cleaning windmill. Transactions of the CSAE, 2006; 22(4): 121–125. (in Chinese)

Ahmed B, Pota H R, Garratt M. Flight control of a rotary wing UAV using backstepping. International Journal of Robust & Nonlinear Control, 2010; 20(6): 639–658.