Calibrating Your Sprayer to Provide Effective, Consistent Control

Calibrating Your Sprayer to Provide Effective, Consistent Control

Uneven pressure throughout the sprayer boom can mean uneven application of pesticides. The first step in sprayer calibration is to determine that the spray pressure is equal throughout the spray boom.

  • Check pressure all along the boom first because there might be a restriction in the line and uneven pressure. If the pressure is not even through the boom, you’ll be wasting your time trying to calibrate the sprayer.
  • Check and compare the cab pressure with boom pressure. If there’s a difference, make adjustments so you know the sprayer’s exact pressure.
  • Set up the pressure gauge with quick-attach fittings that can snap in place on the nozzle fitting.
  • Select glycerin-filled stainless steel gauges, as lesser quality gauges won’t last.

Application Rate

Three basic things affect the number of gallons applied per acre.

Speed. If you run the tractor twice as fast, you’ll apply half the rate, if nothing else is changed.

Nozzle Spacing. The typical nozzle spacing is 20 inches, but 30-inch nozzle spacing is just as effective if 110-degree nozzles are used. Most new air-induction nozzles are only available in 110 degrees. Another reason for 30-inch nozzle spacing is that most farmers are still planting 30-inch rows. If you want to use drop nozzles, add extensions to have drop nozzles.

Thirty-inch nozzle spacing also allows for 50% larger nozzles. That, in turn, provides for using lower application rates without going to extremely small nozzles. Avoid nozzles that require less than a 50-mesh nozzle screen because smaller screens tend to plug.

Nozzle Flow Rate. This is determined by the nozzle orifice size, pressure, and solution density. Remember that anything heavier than water will come out more slowly than water and anything lighter than water may come out faster. Adjust the sprayer accordingly. 

Calibrating a Sprayer Using the Ounce Calibration Method

Field sprayer
Figure 1. Drive and time the sprayer in seconds several times and average the number of seconds it takes to drive the required time.
Measuring sample amount for sprayer calibration
Figure 2. Measure the nozzle discharge in ounces. The number of ounces applied in 128th of an acre is equal to the number of gallons that would be applied to one acre.

Sprayer calibration provides the information you need to determine the amount of spray solution (both pesticide and carrier) being applied per acre. This information can help ensure you're applying the amount of solution stated on the product label.

The ounce calibration method involves collecting the spray from an application of water to 128th of an acre, measuring the amount delivered, and using that information to calibrate your sprayer. This method does not require any calculations, but does require a stopwatch, container to collect nozzle discharge, a tape measure, marking flags, and a container graduated in ounces.  (For more information see NebGuide G1756, Fine-Tuning a Sprayer with the ‘Ounce’ Calibration Method.)

Step 1. Select the travel distance according to the nozzle spacing on the sprayer using Table 1. Measure the travel distance in a level field. The travel area should be typical of the surface and soil conditions of the area to be sprayed. Many tractors and sprayers will gain or lose more than 10% of desired travel speed while moving up and down slopes.

If field variations exist, several speed check areas may be needed. Remember, the time required to drive the travel distance will give the speed of the sprayer, so the measured distance and timing must be exact.

Step 2. Drive and time the sprayer in seconds (Figure 1) at the throttle setting, pressure setting, and load used during spraying (spray tank should be one-half to two-thirds full). Engage incorporation equipment (disks, planter, etc.) or other devices used while spraying. Do not change the gear or throttle setting after you have chosen a spraying speed. A change in ground speed will change the sprayer application rate and will require recalibration.

Step 3. While in a stationary position, bring the power unit to the proper throttle setting and sprayer to the boom pressure used in Step 2. Catch the nozzle discharge for the time recorded in Step 2. Measure the discharge in ounces (Figure 2) with a graduated container. For an accurate assessment of the sprayer, measure all nozzles and average the results.

Remember, from a safety point, the collection of discharge should be done using water only! Even when collecting water, use the proper personal safety clothing and protection.

Step 4. The measured ounces from a nozzle are equal to gallons per acre that will be applied. Since this calibration was based on water, conversion factors must be used when spraying solution heavier or lighter than water. Multiply the observed rates of water by the conversion factors to attain the rate of other spray solutions.

Robert Klein
Extension Western Nebraska Crops Specialist

 

Table 1. Calibration distances and speed for varying nozzle or row spacing.
Nozzle or Row
Calibration
Time in seconds for various ground speeds (mph)*
Spacing(in)

Distance (ft)

 3.0  3.5  4.0** 4.5**  5.0** 6.0**

7.0**

8.0**

Use ½ the time for these mph

9**

10**

12**

14**

16**

40

102

23.2

19.9

17.4

15.5

14.0

12.6

9.9

8.7

38

107

24.3

20.8

18.2

16.2

14.6

12.2

10.4

9.1

36

113

25.7

22.0

19.3

17.1

15.4

12.8

11.0

9.6

34

120

27.3

23.4

20.5

18.2

16.4

13.6

11.7

10.2

32

127

28.9

24.7

21.6

19.2

17.3

14.4

12.4

10.8

30

136

30.9

26.5

23.2

20.6

18.5

15.5

13.2

11.6

28

146

33.2

28.4

24.9

22.1

19.9

16.6

14.2

12.4

26

157

35.7

30.6

26.8

23.8

21.4

17.8

15.3

13.4

24

170

38.6

33.1

29.0

25.8

23.2

19.3

16.6

14.5

22

185

42.0

36.0

31.5

28.0

25.2

21.0

18.0

15.8

20

204

46.4

39.7

34.8

30.9

27.8

23.2

19.9

17.4

18

227

51.6

44.2

38.7

34.4

31.0

25.8

22.1

19.3

16

225

58.0

49.7

43.5

38.6

34.8

29.0

24.8

21.7

14 291 66.1 56.7 49.6 44.1 39.7 33.1 28.3 24.8

*1 MPH = 88 feet per minute
**Note: for times less than 30 seconds, improved accuracy can be attained by doubling the collection time (Step 3), and dividing the output collected by two. For times less than 10 seconds, increase the collection time by four times and divide the output collected by four.
 

Table 2.  Conversion factors for solutions with densities different than water.  REMOVE 

Density of Solution
(lbs/gallon)
 

 

 

 

Conversion Factors

7.0

 

1.092

8.0

 

1.021

8.34

Water

1.000

9.0

 

0.963

10.0

 

0.913

10.65

28% nitrogen solution

0.885

11.0

7-27-7 fertilizer

0.871

11.06

32% nitrogen solution

0.868

11.40

10-34-0 fertilizer

0.855

11.50

12-0-0-26 fertilizer

0.852

11.60

11-37-0

0.848

12.0

 

0.834

14.0

 

0.772

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