Design of a fixed-pipe cold aerosol spraying system for chemical application in greenhouse
Abstract
Keywords: greenhouse, twin-fluid nozzle, spraying system, droplet spectra, distribution, deposition
DOI: 10.25165/j.ijabe.20231601.6573
Citation: Wang S L, Lu D P, Li X, Lei X H, Tang Y X, Lyu X L. Design of a fixed-pipe cold aerosol spraying system for chemical application in greenhouse. Int J Agric & Biol Eng, 2023; 16(1): 53–59.
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Qi F, Wei X M, Zhang Y F. Development status and future research emphase on greenhouse horticultural equipment and its relative technology in China. Transactions of the CSAE, 2017; 33(24): 1–9. (in Chinese)
Yearbook C S. National Bureau of statistics of China. China Statistical Yearbook, Beijing, 2014. (in Chinese)
Li Y J, Li Y F, Pan X, Chen R H, Li X S, Pan C P, et al. Comparison of a new air-assisted sprayer and two conventional sprayers in terms of deposition, loss to the soil and residue of azoxystrobin and tebuconazole applied to sunlit greenhouse tomato and field cucumber. Pest Management Science, 2018; 74(2): 448–455.
Sánchez-Hermosilla J, Rincón V J, Páez F, Agüera F, Carvajal F. Field evaluation of a self-propelled sprayer and effects of the application rate on spray deposition and losses to the ground in greenhouse tomato crops. Pest management science, 2011; 67(8): 942–947.
Sánchez-Hermosilla J, Páez F, Rincón V J, Carvajal F. Evaluation of the effect of spray pressure in hand-held sprayers in a greenhouse tomato crop. Crop protection, 2013; 54: 121–125.
Wang S L, Song J L, He X K, Li Y J, Ling Y. Design of air-assisted electric knapsack sprayer and experiment of its operation performance. Transactions of the CSAE, 2016; 32(21): 67–73. (in Chinese)
Foque D, Pieters J G, Nuyttens D. Comparing spray gun and spray boom applications in two ivy crops with different crop densities. Hortscience, 2012; 47: 51–57.
Rincon V J, Sanchez-Hermosilla J, Paez F, Perez-Alonso J, Callejon A J. Assessment of the influence of working pressure and application rate on pesticide spray application with a hand-held spray gun on greenhouse pepper crops. Crop Protection, 2017; 96: 7–13.
Yang X J, Yan H R, Xu S Z, Liu Z. Current situation and development trend of equipment for crop protection. Transactions of the Chinese Society of Agricultural Machinery, 2002, 33: 129–131. (in Chinese)
Nuyttens D, Windey S, Sonck B. Optimisation of a vertical spray boom for greenhouse spray applications. Biosystems Engineering, 2004; 89(4): 417–423.
Nuyttens D, Windey S, Sonck B. Comparison of operator exposure for five different greenhouse spraying applications. Journal of Agricultural Safety & Health, 2004; 10(3): 187–195.
Llop J, Gil E, Gallart M, Contador F, Ercilla M. Spray distribution evaluation of different settings of a hand-held-trolley sprayer used in greenhouse tomato crops. Pest Management Science, 2016; 72(3): 505–516.
Derksen R C, Vitanza S, Welty C, Miller, S, Bennett M, Zhu H. Field evaluation of application variables and plant density for bell pepper pest management. Transactions of the ASABE, 2007; 50(6): 1945–1953.
Balsari P, Oggero G, Bozzer C, Maruccco P. An autonomous self-propelled sprayer for safer pesticide application in glasshouse. Aspects of Applied Biology, 2011; 114: 197–204.
Subramanian V, Burks T F, Singh S. Autonomous greenhouse sprayer vehicle using machine vision and LADAR for steering control. Applied Engineering in Agriculture, 2005; 21(5): 935–943.
Gonzalez R, Rodriguez F, Sanchez-Hermosilla J, Donaire J G. Navigation techniques for mobile robots in greenhouses. Applied Engineering in Agriculture, 2009; 25(2): 153–165.
Lee I, Lee K, Lee J, You K. Autonomous greenhouse sprayer navigation using automatic tracking algorithm. Applied Engineering in Agriculture, 2015; 31(1): 17–21.
Shi J Y, Ren S L, Ma Y X, Shi G. Design of intelligent remote control mobile spray machine for greenhouse. Agricultural Science & Technology and Equipment, 2014; 7: 26–27. (in Chinese)
Qi L J, Wang H, Zhang J H, Ji R H, Wang J. 3-D numerical simulation and experiment of air-velocity distribution of greenhouse air-assisted sprayer. Transactions of the CSAM, 2013; 44(2): 69–74. (in Chinese)
Qi L J, Du Z W, Ji R H, Wu Y L, Cao J L. Design of remote control system for automatic sprayer based on GPRS in greenhouse. Transactions of the CSAE, 2016; 32(23): 51–57. (in Chinese)
Jia W D, Yan J, Ou M X, Shen Y, Wang H Y, Dong X. Design and experiment of adaptive control system for greenhouse sprayer based on remote control. Journal of Agricultural Mechanization Research, 2018; 40(4): 62–67. (in Chinese)
Xiahou B, Sun D Z, Song S R, Xue X Y, Dai Q F. Simulation and experimental research on droplet flow characteristics and deposition in airflow field. Int J Agric & Biol Eng, 2020; 13(6): 16–24.
Chen J, Yuan S X, Tang Y M. Design for a Spray Nozzle Based on Venturi Tube. Mechanical Research & Application, 2015; 28(2): 114–115. (in Chinese)
Zhang L, Shao J, Chen X. CFD simulation of nozzle characteristics in a gas aggregation cluster source. Vacuum, 2016; 129: 105–110.
ISO 25358:2018. Crop protection equipment—Droplet-size spectra from atomizers—Measurement and classification.
ASAE National Standard No. S572.1: 2009. Spray nozzle classification by droplet spectra. ASABE, 2009.
Li X, Lu D P, Wang S L, Zhang M N, Lei X H, Lyu X L. Droplet distribution and airflow simulation of a newly designed agricultural twin fluid nozzle. International Agricultural Engineering Journal, 2019; 28(2): 194–202.
Ebert T A, Derksen R C, Downer R A, Krause C R. Comparing greenhouse sprayers: The dose-transfer process. Pest management science, 2004; 60(5): 507–513.
Olivet J J, Val L, Usera G. Distribution and effectiveness of pesticide application with a cold fogger on pepper plants cultured in a greenhouse. Crop Protection, 2011; 30(8): 977–985.
Wang S L, Li X, Liu Y J, Lyu X L, Zheng W. Comparison of a new knapsack mist sprayer and three traditional sprayers for pesticide application in plastic tunnel greenhouse. Phytoparasitica, 2022; 50(1): 177–190.
Zhang D Y, Chen L P, Zhang R R, Xu G, Lan Y B, Hoffmann W C, et al. Evaluating effective swath width and droplet distribution of aerial spraying systems on M-18B and Thrush 510G airplanes. Int J Agric & Biol Eng, 2015; 8(2): 21–30.
Smith D B. Uniformity and recovery of broadcast sprays using fan nozzles. Transactions of the ASAE, 1992; 35(1): 39–44.
Sanchez-Hermosilla J, Rincon V J, Paez F, Fernandez M. Comparative spray deposits by manually pulled trolley sprayer and a spray gun in greenhouse tomato crops. Crop Protection, 2012; 31(1): 119–124.
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