A conventional spraying mode and a fully autonomous fruit tree operation mode using a model DJ T30 unmanned aerial vehicle (UAV) were used to control aphids control on elm trees and to clarify the distribution of droplets in elm trees sprayed by an UAV. The effects of six aviation spray adjuvants on elm canopy droplet deposition and aphid control were evaluated. ImageJ software was used to analyze and measure the droplet density and deposition of water sensitive paper in two modes; this was done to calculate the droplet uniformity, depositional penetration and droplet penetration, and to verify the aphid control effect. The results showed that the droplet density increased by 79.7%-100.7% in the upper canopy and 0-394.1% in the lower canopy without adjuvants in the fully autonomous fruit tree operation mode. The upper canopy deposits increased by 65.7%-179.3%, and the lower canopy increased by 0-152.8%. When adjuvants were added, the droplet density in the upper canopy increased by 49.7-56.1% using Jiexiaofeng (JXF), and the lower canopy increased by 138.2%-177.8% using JXF, 45.8%-141.3% using Beidatong (BDT), 45.5%-92.9% using Gongbei (GB), 0-93.5% using Maisi (MS), and 0-95.2% using Manniu (MN). The deposits of the upper canopy increased by 888.1-1154.2% using JXF, 0-1298.3% using MN, 0-343.9% using BDT, 0-422.5% using GB, 0-580.3% using MS. The lower canopy increased by 746.4%-1426.0% using JXF, 226.2%-231.0% using BDT, 435.8%-644.0% using GB, 255.0%-322.4% using MS, and 249.3%-360.0% using MN. When JXF was added, the droplet uniformity, droplet penetration and depositional penetration were better than when using other adjuvants. The effects of JXF, BDT and GB in controlling aphids was significantly better than other adjuvants (p<0.05). The following control effects were observed; 94.1% with JXF, 93.1% with BDT, and 93.3% with GB after 3 d of application, and 97.9% with JXF, 95.6% with BDT, and 97.1% with GB after 7 d of application. At the same time, the application of the fully autonomous fruit tree operation mode and JXF can effectively improve the density and deposits, which will produce a superposition optimization effect. Our study focuses on the prevention and control of elm aphid infestations based on the operation mode of a UAV and aviation spray adjuvants, which can provide a baseline for the control of diseases and insect pests using UAVs in agriculture and forestry.
Keywords: adjuvants, UAV, operation mode, droplet deposition, aphid
DOI: 10.25165/j.ijabe.20231602.7424

Citation: Dou Z C, Fang Z H, Han X Q, Zeeshan M, Liu Y P, Lan Y B. Effects of spray adjuvants and operation modes on droplet deposition and elm aphid control using an unmanned aerial vehicle. Int J Agric & Biol Eng, 2023; 16(2): -.

adjuvants, UAV, operation mode, droplet deposition, aphid

Yang X D. Analysis and application of insect pest of elm investigation in Urumqi city. Yangling: Northwest A&F University, 2013.

He X K. Research and development of crop protection machinery and chemical application technology in China. Chinese Journal of Pesticide Science, 2019; 21(5-6): 921-930. (in Chinese)

Tang Y, Hou C J, Luo S M, Lin J T, Yang Z, Huang W F. Effects of operation height and tree shape on droplet deposits in citrus trees using an unmanned aerial vehicle. Computers & Electronics in Agriculture, 2018; 148: 1-7.

Dekeyser D, D Foqué, Duga A T, Verboven P, Hendrickx H, Nuyttens D. Spray deposits assessment using different application techniques in artificial orchard trees. Crop Protection, 2014; 64: 187-197.

Yu A P, Zhao Y, Zhao X M. Application of aircraft control in integrated forest pest control. The Journal of Hebei Forestry Science and Technology, 2015; 5: 97-98. (in Chinese)

Yan X J, Chu S H, Yang D B, Yuan H Z. Agriculture on the wings of science and technology: plant protection unmanned aerial vehicle (UAV) low-volume spraying technology reduces pesticide use and boosts control efficacy. Journal of Plant Protection, 2021; 48(3): 469-476. (in Chinese)

Shan C F, Wang G B, Wang H H, Xie Y J, Wang H Z, Wang S L, et al. Effects of droplet size and spray volume parameters on droplet deposition of wheat herbicide application by using UAV. Int J Agric & Biol Eng, 2021; 14(1): 74–81.

Chen S D, Lan Y B, Li J Y, Zhou Z Y, Jin J, Liu A M. Effect of spray parameters of small unmanned helicopter on distribution regularity of droplet deposits in hybrid rice canopy. Transactions of the CSAE, 2016; 32(17): 40-46. (in Chinese)

Zang Y, Zhou Z Y, Zang Y, Luo X Y, Liao J, Ming R, et al. Optimization of aviation adjuvants based on wettability analysis for insecticide application on maize using UAV. Int J Agric & Biol Eng, 2021; 14(5): 11-18.

Wang M, Wang X, He L, Shi J M, Fan J S, Zhong L, Yuan H Z. deposits distribution of pesticide droplets over the tea canopy and control efficiency against Empoasca flavescens sprayed by unmanned aerial vehicle (UAV). Plant Protection, 2019; 45(1): 62-68.

Garcerá C, Román C, Moltó E, Abad R, Insa J A, Torrent X, et al. Comparison between standard and drift reducing nozzles for pesticide application in citrus: Part II. Effects on canopy spray distribution, control efficacy of Aonidiella aurantii (Maskell), beneficial parasitoids and pesticide residues on fruit. Crop Protection, 2017; 94: 83-96.

Meng Y H, Song J L, Lan Y B, Mei G Y, Liang Z J, Han Y X. Harvest aids efficacy applied by unmanned aerial vehicles on cotton crop. Ind. Crop. Prod., 2019; 140: 111645.

Fan J B, Fan R J, Zhao J Y, Zhang P J, Liu Z F, Yang J, et al. deposits distribution and control effect of UAV on Aphid citrate under different flight modes. China Plant Protection, 2020; 40(11): 77-79. (in Chinese)

Guo X Y, Xue X Y, Qin W C, Wang S, Liu X M. Effect of operation parameters of plant protection UAV on droplet deposits of palm tree. Journal of Chinese Agricultural Mechanization, 2021; 42(6): 35-40. (in Chinese)

Gao Y, Chou C L, Wang G B, Xie C X, Cheng C. Flight Parameters of Unmanned Aerial Vehicle (UAV) in Spraying the Insecticide against Hyphantria cunea and the Control Effects. Scientia Silvae Sinicae, 2017; 53(12): 147-152.

Chen S D, Lan Y B, Zhou Z Y, Liao J, Zhu Q Y. Effects of spraying parameters of small plant protection UAV on droplets deposits distribution in citrus canopy. Journal of South China Agricultural University, 2017; 38(5): 97-102. (in Chinese)

Liao J, Zang Y, Zhou Z Y, Luo X W. Quality evaluation method and optimization of operating parameters in crop aerial spraying technology. Transactions of the CSAE, 2015; 31(S2): 38-46. (in Chinese)

Han P, Cui Z Y, Yan X J, Shi W P, Wang F L, Yuan H Z. Effect of three types of spray adjuvants on the distribution of spray droplet deposits in hilly citrus under precise fruit tree operation mod e of unmanned aerial vehicles. Chinese Journal of Pesticide Science 2020; 22(6): 1076-1084. (in Chinese)

Zhu H P, Masoud S, Robert D F. A portable scanning system for evaluation of spray deposit distribution. Computers and Electronics in Agriculture, 2011; 76(1): 38-43.

Wang C L, He X K, Zeng A J, Andreas H, Supakorn W, Qiao B Y, et al. Measuring method and experiment on spray drift of chemicals applied by UAV sprayer based on an artificial orchard test bench. Transactions of the CSAE, 2020; 36(13): 56-66. (in Chinese)

Wang X N, He X K, Song J L, Andreas H. Effect of adjuvant types and concentration on spray drift potential of different nozzles. Transactions of the CSAE, 2015; 31(22): 49-55. (in Chinese)

Wang X N, He X K, Song J L, Wang Z C, Wang C L, Wang S L, et al. Drift potential of UAV with adjuvants in aerial applications. Int J Agric & Biol Eng, 2018; 11(5): 54-58.

Gu W, Xue X Y, Chen C, Zhou Q Q, Zhang S C, Peng B. Influence of nozzle enabling strategy on spray deposition of crop protection unmanned aerial system. Int J Agric & Biol Eng, 2021; 14(4): 53-61.

Wang M, Chen Y X, Su X J, Yue H F, Yuan X J, Yuan H Z. Effects of adjuvants in low volume spraying by unmanned aerial vehicle on the deposition distribution of pesticide droplets and control efficiency against

Aphis spiraecola in apple orchards of high-density dwarfing cultivation pattern. Journal of Plant Protection, 2019; 46(6): 1316–1323.

Wang B, Song J L, Zeng A J, Liu Y J, Zhang J, He X K. Effects of formulations and surfactants on the behavior of pesticide liquid spreading in the plant leaves. Chinese Journal of Pesticide Science, 2012; 14(3): 334-340. (in Chinese)

Xu G C, Xu D J, Xu L, Wang C B, Cao A C, Gu Z Y. Study on the synergistic effect of organosilicon adjuvant on chlorantraniliprole in the control of rice leaffolder, Cnaphalocrocis medinalis Guenée. Chinese Journal of Pesticide Science, 2020; 2(22): 285-292. (in Chinese)

Wei M F, Yao Z, Fan Q L, Liu Z, Zang L P. Synergism effect of organosilicone additive on pesticides against Cacopsylla chinensis (Hemiptera: Psyllidae). China Fruits, 2019; 5: 54-57. (in Chinese)