Droplet Chart / Selection Guide
ID
442-031 (BSE-263P)
When choosing nozzles/droplet sizes for spray applications, applicators must consider both coverage needed and drift potential. As a rule, smaller droplets provide better coverage, but larger droplets are less likely to drift.
Nozzle type and application pressure govern droplet size (see Nozzles: Selection and Sizing, Virginia Cooperative Extension publication 442-032), which in turn affects system output (application rate), target deposition, uniformity, efficacy, and the risk of drift. Off-target movement in the form of spray drift is a major concern because it diverts the chemical from the intended target, reduces efficacy, and deposits pesticide where it is not needed or wanted. When a pesticide drifts, it may cause both environmental and economic damage, including exposure to people and property, injury to susceptible vegetation, harm to wildlife, deposition of illegal residues on crops, and contamination of water supplies.
In some cases, increased droplet size may reduce efficacy. Although fine or very fine droplets (if applied uniformly) can, theoretically, provide the best coverage, small, lightweight droplets may not penetrate plant canopies. Droplets produced by air-induction nozzles may break vs. bounce when they hit the target, providing better coverage than droplet size rating alone would indicate. In many cases, choosing a nozzle/droplet size for a job is a tradeoff between good coverage and drift potential.
So … what’s an applicator to do?! Many labels provide recommendations and/or requirements regarding droplet size, nozzle selection, and sprayer configuration. Research in application technology supports recommendations in nozzle-selection guides and directions on product labels. However, in the absence of specific guidance, Charts 1 and 2 may serve as a starting point.
Application | Droplet Category2 | Approximate VMD Range3 (in microns) |
---|---|---|
foliar protective or curative | Medium (M) | 236-340 |
Application | Droplet Category2 | Approximate VMD Range3 (in microns) |
---|---|---|
foliar contact or stomach poison | Medium (M) | 236-340 |
foliar systemic | Coarse (C) | 341-403 |
soil-applied systemic | Coarse (C) | 341-403 |
soil-applied systemic | Very Coarse (VC) | 404-502 |
soil-applied systemic | Extremely Coarse (XC) | 503-665 |
soil-applied systemic | Ultra Coarse (UC) | >665 |
Application | Droplet Category2 | Approximate VMD Range3 (in microns) |
---|---|---|
foliar/post-emergent contact | Medium (M) | 236-340 |
foliar/post-emergent systemic | Coarse (C) | 341-403 |
soil-applied/pre-emergent systemic | Coarse (C) | 341-403 |
soil-applied/pre-emergent systemic | Very Coarse (VC) | 404-502 |
soil-applied/pre-emergent systemic | Extremely Coarse (XC) | 503-665 |
soil-applied/pre-emergent systemic | Ultra Coarse (UC) | >665 |
1 Always read the label. Pesticide product labels may specify what droplet size to use, which will direct nozzle selection and, in turn, affect spraying equipment configuration and calibration.
2 ASABE (American Society of Agricultural & Biological Engineers) Standard 572.2 July 2018.
3 Reported VMD ranges vary widely, based upon the type of laser analyzer used. VMD = Volume Median Diameter: a value where 50% of the total VOLUME or mass of liquid sprayed is made up of droplets LARGER than and 50% SMALLER than this value.
Droplet Category1 | Symbol | Color Code | Approximate VMD Range2 (in microns) |
---|---|---|---|
Extremely Fine | XF | Purple | <60 |
Very Fine | VF | Red | 60-105 |
Fine | F | Orange | 106-235 |
Medium | M | Yellow | 236-340 |
Coarse | C | Blue | 341-403 |
Very Coarse | VC | Green | 403-502 |
Extremely Coarse | XC | White | 503-665 |
Ultra Coarse | UC | Black | >665 |
1 ASABE (American Society of Agricultural & Biological Engineers) Standard 572.2 July 2018.
2 Reported VMD ranges vary widely, based upon the type of laser analyzer used. VMD = Volume Median Diameter: a value where 50% of the total
VOLUME or mass of liquid sprayed is made up of droplets LARGER than and 50% SMALLER than this value.
Droplets, Coverage, and Drift:
Very fine droplets (VMD less than 105 microns) are collected efficiently by flying insects or needles on coniferous plants, but they tend to remain in the air stream, which carries them around the stems and leaves of weeds.
Fine and medium-size droplets (VMD between 106 and 340 microns) will deposit efficiently on stems and narrow vertical leaves such as grasses if applied when there is some air movement.
Coarse (or larger) droplets (VMD more than 341 microns) deposit efficiently on large, flat surfaces such as the leaves of broad-leaved weeds.
Insecticides, fungicides, and contact generally require smaller droplets (Chart 1) than systemic herbicides to obtain adequate coverage of the target. For foliar systemic herbicides, however, experimental results suggest that applications using droplet sizes in the course ranges do not significantly differ unless application volumes are extremely high or very low. (Exceptions may exist for specific herbicides.)
Summary:
- When choosing a nozzle, consider both flow rate and droplet size.
- Base decision on target and properties of active ingredient.
- Avoid using nozzles and pressures that will produce a volume median diameter (VMD) of less than 235 microns (fine–very fine - extremely fine).
- Always read the label. Pesticide product labels may specify what droplet size to use and how much finished spray mixture to apply to a given area. This will direct nozzle selection and, in turn, affect spraying equipment configuration and calibration.
References and Additional Information:
Strategies to Reduce Spray Drift, Kansas State University Agricultural Experiment Station and Cooperative Extension Service publication MF-2444; March 2000; http://www.ksre.ksu.edu/bookstore/pubs/MF2444.pdf. (accessed: July 2019)
Fine Tuning a Sprayer with “Ounce” Calibration Method, Virginia Cooperative Extension publication 442-453 (BSE-178P), December 2014; http://pubs.ext.vt.edu/442/442-453/442-453.html (accessed: July 2019)
Nozzles: Selection and Sizing, VCE publication 442-032; https://www.pubs.ext.vt.edu/442/442-032/442-032.html (accessed: July 2019)
Acknowledgments:
The authors would like to express their appreciation for the review and comments made by Mike Parrish, Mike Weaver, and Paul Sumner.
The authors would like to express our appreciation to former co-authors, Pat Hipkins, Bob Wolf, and Tom Reed, for their input in previous versions.
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Publication Date
August 13, 2019