RTDrift: a real time model for estimating spray drift from ground applications

[en] A spray drift model called RTDrift was developed to estimate drift caused by ground sprayer machines. The sprayer was equipped with sensors measuring operational parameters namely spray pressure, boom height and movements, and geolocalization. Climatic parameters, including wind speed and direction, were measured using a 2-D ultrasonic anemometer mounted on the sprayer. The nozzles spray drop size spectra were characterized using Phase Doppler Interferometer measurements. At every successive boom position, a diffusion-advection Gaussian tilted plume model computed the spray drift deposits for each drop class taking into account evaporation. The contribution of a single nozzle was calculated by integration of the individual puffs with respect to time and summation of the contributions of individual drops classes. The overall drift generated by the sprayer machine was obtained adding the contributions of all the nozzles. Field trials were performed on a fallow field with water and on crops with pesticides in various wind conditions. The ground drift was measured at different drift distances using fluorometric methods. When comparing the results of the model with experimental measurements of deposits, the model produced realistic maps of drift deposits. Some further improvement is needed in the presence of large scale eddies. The model offers potential benefits for the farmer as a real time drift estimator embedded on a sprayer machine

Disciplines :

Physics
Materials science & engineering
Agriculture & agronomy

Author, co-author :

Lebeau, Frédéric ; Université de Liège - ULiège > Sciences et technologie de l'environnement > Mécanique et construction

Verstraete, Arnaud ; Université de Liège - ULiège > Sciences et technologie de l'environnement > Mécanique et Construction

Stainier, Charles ; Université de Liège - ULiège > Doct. sc. agro. & ingé. biol.

Destain, Marie-France ; Université de Liège - ULiège > Sciences et technologie de l'environnement > Mécanique et construction

Language :

English

Title :

RTDrift: a real time model for estimating spray drift from ground applications

Alternative titles :

[en] RTDrift: un modèle temps réel pour l'estimation de la dérive de la pulvérisation à jet projeté

Publication date :

July 2011

Journal title :

Computers and Electronics in Agriculture

ISSN :

0168-1699

eISSN :

1872-7107

Publisher :

Elsevier Science

Volume :

Issue :

Pages :

161-174

Peer reviewed :

Peer Reviewed verified by ORBi

Name of the research project :

DRIFT-INDIC project n°2907

Available on ORBi :

since 27 April 2011

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Bibliography

Amsden R.C. Reducing the evaporation of sprays. Agricultural Aviation 1962, 4:88-93.
Baetens K., Nuyttens D., Verboven P., De Schampheleire M., Nicolai B., Ramon H. Predicting drift from field spraying by means of a 3D computational fluid dynamics model. Computers and Electronics in Agriculture 2007, 56:161-173.
Butler Ellis M.C., Tuck C.R. How adjuvants influence spray formation with different hydraulic nozzles. Crop Protection 1999, 18:101-109.
Craig I.P. The GDS model, a rapid computational technique for the calculation of aircraft spray drift buffer distances. Computers and Electronics in Agriculture 2004, 43:235-250.
DIRECTIVE 2009/127/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL of 21 October 2009 amending Directive 2006/42/EC with regard to machinery for pesticide application. Official Journal of the European Union L 310 of 25.11.2009, pp. 29-33.
Gil Y., Sinfort C. Emission of pesticides to the air during sprayer application: A bibliographic review. Atmospheric Environment 2005, 39:5183-5193.
Hewitt A.J. Spray drift: impact of requirements to protect the environment. Crop Protection 2000, 19:623-627.
Holterman H.J., Van De Zande J.C., Porskamp H.A.J., Huijsmans J.F.M. Modeling spray drift from boom sprayers. Computers and Electronics in Agriculture 1997, 19:1-22.
ISO 22866 2005. International Standard: Equipment for crop protection - Methods for field measurement of spray drift.
Lebeau F. Modelling the Dynamic Distribution of Spray Deposits. Biosystems Engineering 2004, 89(3):255-265.
Miller D.R., Stoughton T.E., Steinke W.E., Huddleston E.W., Ross J.B. Atmospheric stability effects on pesticide drift from an irrigated orchard. Transactions of the ASAE 2000, 43(5):1057-1066.
Miller P.C.H., Hadfield D.J. A simulation model of the spray drift from hydraulic nozzles. Journal of Agricultural Engineering Research 1989, 42:135-147.
Miller P.C.H., Butler Ellis M.C. Effects of formulation on spray nozzle performance for applications from ground-based boom sprayers. Crop Protection 2000, 19:609-615.
Mokeba M.L., Salt D.W., Lee B.E., Ford M.G. Simulating the dynamics of spray droplets in the atmosphere using ballistic and random-walk models combined. Journal of Wind Engineering and Industrial Aerodynamics 1997, 67(8):923-933.
Ooms D., Lebeau F., Ruter R., Destain M.F. Measurements of the horizontal sprayer boom movements by sensor data fusion. Computers and Electronics in Agriculture 2002, 33:139-162.
Pal Arya S. Air pollution meteorology and dispersion 1999, Oxford University Press, Oxford.
Reible Danny D. Fundamentals of Environmental Engineering 1999, CRC Press, LLC, Boca Raton, p. 526.
Smith D.B., Bode L.E., Gerard P.D. Predicting ground boom spray drift. Transactions of the ASAE 2000, 43(3):547-553.
Stainier C., Destain M.F., Schiffers B., Lebeau F. Effect of the entrained air and initial droplet velocity on the release height parameter of a Gaussian spray drift model. Communications in Agricultural and Applied Biological Sciences 2006, 71:197-200.
Teske M.E., Bird S.L., Esterly D.M., Curbishley T.B., Ray S.L., Perry S.G. AgDRIFT®: a model for estimating near-field spray drift from aerial applications. Environmental Toxicology and Chemistry 2002, 21:659-671.
Thompson N., Ley A.J. Estimating spray drift using a random-walk model of evaporating droplets. Journal of Agricultural Engineering Research 1983, 28 419-435.
Tsai M.Y., Elgethun K., Ramaprasad J., Yost M., Felsot A., Hebert V., Fensk e R. The Washington aerial spray drift study: modeling pesticide spray drift deposition from an aerial application. Atmospheric Environment 2004, 38 5703-5713.
Woods N., Craig I.P., Dorr G., Youn g B. Spray drift of pesticides arising from aerial application in cotton. Journal of Environmental Quality 2001, 30 697-701.
Zhu H., Reichard D.L., Fox R.D., Brazee R.D., Ozkan H.Z. Simulation of drift of discrete sizes of water droplets from field sprayers. Transactions of the ASAE 1994, 37:1401-1407.