The objective of calibration is to apply the correct amount of pesticide. Calibration should be done regularly and whenever any components of application equipment are replaced.
GPA = gallons per acre
GPM = gallons per minute
MPH = miles per hours
PSI = pounds per square inch
Determine an adequate application rate (GPA)
from the label. Calibrating the sprayer to apply that amount of spray volume
per acre will ensure that you apply the proper amount of pesticide per acre.
For example, if the label recommends 20 GPA, your sprayer holds 200 gallons,
and you add a 21|2 gallon container of pesticide to fill the spray tank, you
know that one quart of pesticide will be applied per acre if the sprayer is
properly calibrated.
The steps are:
1. Determine the
distance the sprayer must travel to cover one acre by dividing swath width
(width covered by sprayer) in 43,560 (the square feet in an acre). For example,
a sprayer with an effective swath of 40 feet would have to travel 1089 feet to
cover an acre (43,560/40 = 1089).
2. To spray a
measured acre, mark off 1089 feet in the field to be sprayed. For convenience,
you could mark off a fraction of this amount and treat that fraction of an
acre. (Treating 544.5 feet would be the same as treating 1|2 acre).
3. Configure the
sprayer as you plan to use it (nozzles, pressure, boom height, etc.).
4. Fill the tank
with a measurable amount of water.
5. Spray the
marked course at a uniform speed, making sure to write down your throttle
setting so that it can be duplicated. Make sure to be at full speed when you
reach the start of the measured distance,
and turn the sprayer on and off exactly at the start and end of the
course.
6. Measure the
amount of water that has been applied by measuring either the amount remaining
in the tank or the amount of water needed to refill the tank to the original
level.
* If an oil solution is to be applied, and water was used during calibration, add 10% to the measured volume.
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GPA can be calculated as follows:
If you know your swath width, this can be simplified
to:
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GPM is measured by filling the sprayer with water, setting sprayer pressure to the level you plan to use in the field, placing a collection container under each nozzle, and running the sprayer for 33|4 minutes. The cups (8 oz.) of water collected equal the gallons per hour (GPH) output of the nozzle.
Nozzles off by more than five percent of the average output should be replaced. Inconsistent output will cause streaks in application pattern.
To measure MPH, time the sprayer over a
known distance. |
GPM, MPH and PSI can all be varied to achieve the desired application rate (GPA). Gallons per acre applied can be increased by slowing the sprayer down (simplest solution), increasing pressure, or increasing nozzle size. Gallons per acre applied can be reduced by the opposite actions. Changing sprayer pressure is not a good means of changing sprayer output, because sprayer output only increases as the square root of the pressure increase. For example, doubling the sprayer pressure would only result in increasing output 1.4 times. Furthermore, increased sprayer pressure may cause increased drift.
Granular applicators need to be calibrated unit by unit because individual variation is enough to affect application rates significantly. Granular pesticide products have unique flow characteristics and should be calibrated separately. These products are abrasive so calibration should be checked before each application. Applicator settings given on labels are only guidelines and need to be verified by calibration. Recommended granular insecticide application rates are generally given in ounces per thousand row feet. (Granular herbicide rates may be given pounds per acre, making band‑width a critical factor in calibration).
The steps to calibrate a granular applicator are:
1.
Set each applicator as
recommended on the label or at the setting used in your last calibrated
application.
2.
Fill the hoppers until they are
at least one‑half full with granules. Run the applicators until they all
begin to feed.
3.
Replace each drop tube with a
container, calibration bag, or pre-marked calibration tube.
4.
Travel a measured distance
(several hundred feet) over a surface similar to the one that you will plant
into, at your normal planting speed.
5.
Weigh and record the amount of
pesticide collected in each container using a scale that is accurate to 1|10
oz. Be sure to subtract the empty container weight.
6.
Calibrate the application rate
for each row unit.
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The application rate for insecticides applied in
ounces per1000 row feet can be calculated as follows:
Use this formula for application rates in pounds per
acre:
* If any unit is off the label rate by more than five
percent then adjust the rate control and repeat the calibration process. |
A simple method of monitoring the application rate is as follows. Place a vertical strip of tape in each hopper. Mark the tape as each pound of insecticide is added to the hopper (level the insecticide before marking the tape). The application rate now can be checked quickly by observing how many pounds of product were used while planting a known acreage.
The
following calculations must be made to accurately calibrate a chemigation
system:
1.
Area irrigated
2. Amount of chemical
required
3.
Travel speed
4.
Revolution time
5. Chemical
application rate
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The area irrigated for square or rectangular fields
is determined by:
For circular fields, calculate area irrigated as follows:
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Determining the area irrigated is made more difficult by irregular fields such as partial circles and by end guns. It is recommended to use the length of the pivot as the radius in the above formula and shut off the end gun during chemigation.
The amount of chemical required is determined by multiplying the area
irrigated in acres by the amount of chemical
used per acre, which is found on the label.
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To measure travel speed, either: Record
the time it takes for the outer pivot tower to travel 100 feet, or Measure
the distance traveled by the outer pivot tower in 10 minutes. * In either case, you need to figure the feet
traveled per minute by the system. |
If the terrain is rolling, these measurements should be made at several
locations around the circle or across the field to determine an average value.
Travel speed should be measured prior to each chemigation as it can change
through the season as wheel track resistance is
affected by changes in cover, soil compaction, track depth, etc. Always
recalibrate if the system speed has been changed.
Revolution time of center pivot systems is calculated by dividing the circumference (feet) of the last wheel track by the travel speed (feet per minute). Convert this figure to hours by dividing the outcome by 60.
Circumference (ft) = 6.28 x radius (length of pivot in ft).
The chemical application rate (in gallons per hour) is calculated by dividing the amount of chemical required (in gallons) by revolution time (in hours) of the center pivot system.
1. The field to be chemigated has a wetted radius (length of pivot) of 1300 feet without the end gun.
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Area
irrigated (acres) = |
3.14 x 1300 ft x 1300ft. |
=122 acres |
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43560 |
2. The label rate for the pesticide to be applied is 1 quart/acre, so the amount of chemical required is: 122 acres x 1 quart/acre = 122 quarts (30.5 gallons)
3. The outer tower moved a total of 195 ft in three 10-minute measurements, so the Travel speed is:
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Travel speed (ft/minute)
= |
195 ft |
= 6.5 ft/minute |
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30 minutes |
4. The radius to the last wheel track is 1280 feet (system radius minus the end gun and overhang), so the circumference traveled by the last tower is:
Revolution time (minutes) = |
8038 ft (last tower circumference) |
=1237minutes |
= 20.6 hours |
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6.5 ft/minute (last tower travel speed) |
6.28 x 1280 = 8038 ft.
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5. Application rate
(gallons/hr) = |
30.5 gallons (chemical required) |
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20.6 hours (revolution time) |
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=1.48 gallons/hr |
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* The injection pump can be set to this rate, using the calibration tube.
Categories: Calibrating, Field sprayers,Granular applicators, Chemigation systems, Center pivot chemigation
Date: 08/14/01