Improving the Effectiveness of Aerial Pesticide Sprays

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Volume 2, Issue 4 (April 2005)

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ISSN: 1546-962X
Page Count: 15

Improving the Effectiveness of Aerial Pesticide Sprays
Smith, DB
Agricultural Engineer, Mississippi State University, MS

Kirk, IW
Agricultural Engineer, USDA ARS, TX

Ross, JB
Entomology Specialist/Agricultural Research Pilot, New Mexico State University, NM

Abstract

Thirty-eight aircraft setups were submitted in order to have droplet size and drift analyses performed. Four of the eleven insecticides predicted D^v0.5s were in the 351–400 µm range. Seven of the herbicide setups had predicted D^v0.5s in the 205–250 µm range, while ten D^v0.5s were > 351 µm. Five of the ten predicted D^v0.5s were between 386 and 413 μm. Twelve different herbicides were reported as having been applied with aircraft setups that had predicted D^v0.5s between 386 and 413 µm. A summary of the prior swath deposit data indicated that the percent recovery generally increased as the D^v0.5 increased. The magnitudes of the deposits on inert targets and cotton leaves appeared to be about equal for a given D^v0.5. The correlation coefficient between the “percent of the spray volume in droplets ≤100 µm and ≤200 µm in diameter” was 0.983. This result is consistent with prior results and indicates that either 100 or 200 µm can be effectively used as the upper limit when studying the “small droplet” component in sprays. We found several similarities or differences in the “small droplet” components based on data from different atomization tests. According to one set of atomization models, agricultural aircraft will be limited to about 225 km/h (i.e., 140 mph) in order to produce a 400 µm D^v0.5 spray when using currently available nozzles and water plus one or more pesticides. The extremes of the predicted drift deposits for 38 agricultural aircraft setups were over 30-fold apart.

Keywords:
aerial application, drift, droplet size, small droplets, pesticides

Paper ID: JAI12166
DOI: 10.1520/JAI12166
ASTM International is a member of CrossRef.

Author Title Improving the Effectiveness of Aerial Pesticide Sprays Symposium Pesticide Formulations and Application Systems: The Continued Evolution of Agrochemical Formulations, 2003-10-22 Committee E35

		Home Journals STPs Manuals Topics Subscriptions/Pricing Digital Library / Journals / Journal of ASTM International (JAI) / Citation Page Volume 2, Issue 4 (April 2005) Click here to download this paper now for $25 PDF (392K) View License Agreement ISSN: 1546-962X Page Count: 15 Improving the Effectiveness of Aerial Pesticide Sprays Smith, DB Agricultural Engineer, Mississippi State University, MS Kirk, IW Agricultural Engineer, USDA ARS, TX Ross, JB Entomology Specialist/Agricultural Research Pilot, New Mexico State University, NM Abstract Thirty-eight aircraft setups were submitted in order to have droplet size and drift analyses performed. Four of the eleven insecticides predicted D^v0.5s were in the 351–400 µm range. Seven of the herbicide setups had predicted D^v0.5s in the 205–250 µm range, while ten D^v0.5s were > 351 µm. Five of the ten predicted D^v0.5s were between 386 and 413 μm. Twelve different herbicides were reported as having been applied with aircraft setups that had predicted D^v0.5s between 386 and 413 µm. A summary of the prior swath deposit data indicated that the percent recovery generally increased as the D^v0.5 increased. The magnitudes of the deposits on inert targets and cotton leaves appeared to be about equal for a given D^v0.5. The correlation coefficient between the “percent of the spray volume in droplets ≤100 µm and ≤200 µm in diameter” was 0.983. This result is consistent with prior results and indicates that either 100 or 200 µm can be effectively used as the upper limit when studying the “small droplet” component in sprays. We found several similarities or differences in the “small droplet” components based on data from different atomization tests. According to one set of atomization models, agricultural aircraft will be limited to about 225 km/h (i.e., 140 mph) in order to produce a 400 µm D^v0.5 spray when using currently available nozzles and water plus one or more pesticides. The extremes of the predicted drift deposits for 38 agricultural aircraft setups were over 30-fold apart. Keywords: aerial application, drift, droplet size, small droplets, pesticides Paper ID: JAI12166 DOI: 10.1520/JAI12166 ASTM International is a member of CrossRef. Author Title Improving the Effectiveness of Aerial Pesticide Sprays Symposium Pesticide Formulations and Application Systems: The Continued Evolution of Agrochemical Formulations, 2003-10-22 Committee E35