论文信息 - The effect of oil-in-water emulsion pesticide on the evolution of liquid sheet rim disintegration and the spraying distribution - 字舞流文

The effect of oil-in-water emulsion pesticide on the evolution of liquid sheet rim disintegration and the spraying distribution

Mingxiong Ou | W. Jia | Wanting Yang | Xiang Dong | Wei Zhong | Tie Zhang | Suming Ding | Pengpeng Yu

[1] H. Kyotoh,et al. Propagation of the rim under a liquid-curtain breakup , 2022, Journal of Fluid Mechanics.

[2] Wei Zhong,et al. Effect of Physical Properties of an Emulsion Pesticide on the Atomisation Process and the Spatial Distribution of Droplet Size , 2022, Agriculture.

[3] C. Kang,et al. Visualisation of the evolution of bubbles in the spray sheet discharged from the air-induction nozzle. , 2022, Pest management science.

[4] Feng Kang,et al. Analysis of droplet size uniformity and selection of spray parameters based on the biological optimum particle size theory. , 2021, Environmental research.

[5] E. Esimbekova,et al. Pesticides: formulants, distribution pathways and effects on human health – a review , 2021, Toxicology reports.

[6] C. Dutcher,et al. A review of liquid sheet breakup: Perspectives from agricultural sprays , 2021 .

[7] G. Agbaglah. Breakup of thin liquid sheets through hole–hole and hole–rim merging , 2021, Journal of Fluid Mechanics.

[8] C. Kang,et al. The effect of spray structure of oil-based emulsion spray on the droplet characteristics , 2020 .

[9] A. K. Dasmahapatra,et al. Self-organized spreading of droplets to fluid toroids. , 2020, Journal of colloid and interface science.

[10] D. Juric,et al. Dynamics of retracting surfactant-laden ligaments at intermediate Ohnesorge number , 2020 .

[11] D. Ghosh,et al. Advances in controlled release pesticide formulations: Prospects to safer integrated pest management and sustainable agriculture. , 2019, Journal of hazardous materials.

[12] Irene Ruiz-Rodriguez,et al. Investigation of Spray Angle Measurement Techniques , 2019, IEEE Access.

[13] D. Bonn,et al. UvA-DARE ( Digital Academic Repository ) What Determines the Drop Size in Sprays ? , 2018 .

[14] D. Mishra,et al. Visualizations of sheet breakup of non-Newtonian gels loaded with nanoparticles , 2017 .

[15] Anthony L. Altieri,et al. Role of large inhomogeneities in initiating liquid sheet breakup in agricultural atomisation , 2017 .

[16] G. McKinley,et al. Ligament Mediated Fragmentation of Viscoelastic Liquids. , 2016, Physical review letters.

[17] P. Jones,et al. Kinetic Resolution of the Interactions between Agrochemical Products and Adjuvant Systems upon Mixing. , 2016, Journal of agricultural and food chemistry.

[18] Rodolfo G. Chechetto,et al. Determining the drift potential of Venturi nozzles compared with standard nozzles across three insecticide spray solutions in a wind tunnel. , 2016, Pest management science.

[19] Gary J. Dorr,et al. Impacts of polymer/surfactant interactions on spray drift , 2016 .

[20] N. Cameron,et al. Polymeric drift control adjuvants for agricultural spraying , 2016 .

[21] O. Diemuodeke,et al. Mechanistic Model for the Breakup Length in Jet Atomization , 2016 .

[22] S. Zaleski,et al. Spray formation: a numerical closeup , 2015, 1511.04234.

[23] R. V. Filho,et al. Behavior of RR soybeans subjected to different formulations and rates of glyphosate in the reproductive period , 2014 .

[24] C. Sinfort,et al. Influence of spray characteristics on potential spray drift of field crop sprayers: A literature review , 2014 .

[25] G. J. Leite,et al. Distribuição volumétrica de calda contendo Metarhizium anisopliae , 2012 .

[26] G. Blaisdell,et al. Measurements of axial instability waves in the near exit region of a high speed liquid jet , 2011 .

[27] M. Khadem,et al. Physics of Breakup in Liquid Column and Sheet , 2011 .

[28] E. Villermaux,et al. Physics of liquid jets , 2008 .

[29] C. R. Tuck,et al. How adjuvants influence spray formation with different hydraulic nozzles , 1999 .

[30] L. Slepyan. Principle of Maximum Energy Dissipation Rate in Crack Dynamics , 1993 .

[31] D. Sharp. An overview of Rayleigh-Taylor instability☆ , 1984 .

[32] N. Dombrowski,et al. A photographic investigation into the disintegration of liquid sheets , 1954, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[33] H. Squire. Investigation of the instability of a moving liquid film , 1953 .

[34] L. Rayleigh. On The Instability Of Jets , 1878 .

[35] T. Inamura,et al. TIME-DEPENDENT BREAKUP LENGTH OF LIQUID SHEET IN PREFILMING TYPE OF AIRBLAST ATOMIZER , 2019, Atomization and Sprays.

[36] Andrew J. Hewitt,et al. Flat-fan spray atomization model , 2018 .

[37] S. Masny,et al. Low-drift nozzles vs. standard nozzles for pesticide application in the biological efficacy trials of pesticides in apple pest and disease control. , 2017, The Science of the total environment.

[38] M. C. Stuart,et al. Mechanism of perforation based on spreading properties of emulsified oils , 2012 .

[39] Yang Jun,et al. Experimental Study Based on Nozzle Spray Uniformity , 2012 .

[40] S. Wilson,et al. CONTROLLING DROPLET-SIZE DISTRIBUTION USING OIL EMULSIONS IN AGRICULTURAL SPRAYS , 2010 .

[41] S. Yoon,et al. A nonlinear atomization model based on a boundary layer instability mechanism , 2004 .