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Nozzle Description 
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Nozzle Selection and Sizing Example 
Nozzle Manufacturers 

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The proper selection of a nozzle type and size is essential for proper pesticide application. The nozzle is a major factor in determining the amount of spray applied to an area, the uniformity of application, the coverage obtained on the target surface, and the amount of potential drift.
Nozzles break the liquid into droplets, form the spray pattern, and propel the droplets in the proper direction. They determine the amount of spray volume at a given operating pressure, travel speed, and spacing. Drift can be minimized by selecting nozzles that produce the largest droplet size while providing adequate coverage at the intended application rate and pressure.

Spray Particle Size
The size of the spray particle is important because it affects both efficacy and spray drift of the pesticide. If the size of the spray particle (for example 300 to 600 microns) is doubled and the application volume stays the same, you have only 1/8 as many spray droplets. For optimum efficacy and 10 to 20 gallon spray volumes, a medium droplet size is suggested for contact non-translocating herbicides and a coarse droplet size for contact translocating herbicides. Concern for drift may cause you to consider larger droplet sizes and higher spray volumes.

Nozzle Description
Nozzle types commonly used in low-pressure agricultural sprayers include: flat, flood, air induction, raindrop, hollow-cone, full-cone, and others. Special features, or subtypes such as "extended range," are available for some nozzle types. 

Flat-Fan--

Flat-fan nozzles are widely used for broadcast spraying of herbicides. These nozzles produce a tapered edge, flat-fan spray pattern (Figure 1). These nozzles have several subtypes, such as standard flat-fan, even flat-fan, low pressure flat-fan, extended range flat-fan, and some special types such as off-center flat-fan and twin-orifice flat-fan.

The standard flat-fan normally operates between 30 and 60 psi, with an ideal range between 30 and 40 psi. The even (E) flat-fan nozzles apply uniform coverage across the entire width of the spray pattern. They are used for banding pesticide over the row and should not be used for broadcast applications. The band width can be controlled with the nozzle height and the spray angle.

The extended range (XR or LFT) flat-fan nozzle provides fair drift control when operated between 15 and 25 psi. This nozzle is ideal for an applicator who likes the uniform distribution of a flat-fan nozzle and wants lower operating pressures for drift control. Since extended range nozzles have an excellent spray distribution over a wide range of pressures (15-60 psi), they can be used on sprayers equipped with flow controllers.

The special feature flat-fan nozzles, such as the off-center (LX) flat-fan, are used for boom end nozzles so a wide swath projection is obtained. The twin-orifice (TJ) flat-fan produces two spray patterns - one angled 30 degrees forward and the other directed 30 degrees backward. The droplets are small due to the atomizing by two smaller orifices. The two spray directions and smaller droplets improve coverage and penetration, a plus when applying postemergence contact herbicides. Because of the small spray droplets, drift is a concern. To produce fine droplets, the twin-orifice usually operates between 30 and 60 psi.

Flat-fan nozzles are available in several spray angles. The most common spray angles are 65, 73, 80 and 110 degrees. Recommended nozzle heights for flat-fan nozzles during broadcast application are given in Table I.

Table I. Suggested minimum spray heights. 
Spray Height (in) 
20" Spacing Overlap 30" Spacing Overlap 
Spray Angle
Degrees 30% 100% 30% 100% 
65 22-24 -NR- -NR- -NR- 
73 20-22 -NR- 29-31 -NR- 
80 17-19 26-28 26-28 37-39 
110 10-12 15-17 14-18 25-27 
-NR- Not recommended. 


The correct nozzle height is measured from the nozzle to the target, which may be the top of the ground, growing canopy, or stubble. Use 110 degree nozzles when booms are less than 30 inches high with a 30-inch nozzle spacing, and 80 degree nozzles when the booms are higher.

Although wide-angle nozzles produce smaller droplets, which are more prone to drift, the lower boom height reduces the drift potential more than the corresponding decrease in droplet size. The nozzle spacing and orientation should provide for 100 percent overlap at the target height. Nozzles should not be oriented more than 30 degrees back from vertical.

Spraying Systems Company1 identifies its flat-fan nozzles with a four or five digit number. The first numbers are the spray angle and the other numbers signify the discharge rate at rated pressure. For example, an 8005 has an 80 degree spray angle and will apply 0.5 gallons per minute (GPM) at rated pressure of 40 psi. An 11002 nozzle has a 110 degree spray angle and will apply 0.2 GPM at rated pressure of 40 psi. Additional designations are "BR" - brass material; "SS" - stainless steel; "HS" - hardened stainless steel; "VP' - polymer with color coding; "VK" - ceramic with color coding; "VH" - hardened stainless steel with color coding; and "VS" - stainless steel with color coding.

Some nozzles are identified by "LF" or "LF-R," which reflect the standard and extended range flat-fan nozzles. The first numbers are the spray angle followed by a dash, and then the discharge rate at rated pressure. For example, an LF 80-5R is an extended range nozzle with an 80 degree spray angle that will apply 0.5 GPM at the rated pressure of 40 psi.

The turbulence chamber nozzle is an updated nozzle design that incorporates a pre-orifice concept with an internal turbulence chamber. These design improvements have resulted in larger, less driftable droplets and improved spray pattern uniformity. Turbulence chamber nozzles are available in flood and flat-fan tip designs.

The Turbo TeeJet has the widest pressure range of the flat-fan nozzles - 15 to 90 psi. It produces larger droplets for less drift and is available only in 110 degrees.

The drift guard flat-fan has a pre-orifice that controls the flow. The spray tip is approximately one nozzle size larger and therefore produces larger droplets and reduces the small, drift-prone droplets.

The venturi type nozzle produces large air-filled drops through the use of a venturi air aspirator for reducing drift. These include the Delavan Raindrop Ultra, Greenleaf Turbo Drop and Airmix, Lurmark Ultra Lo-Drift, Spraying Systems AI Teejet, ABJ Agri. Air Bubble Jet, and Wilger's Combo-Jet.

Flood--

Flood nozzles are popular for applying suspension fertilizers where clogging is a potential problem. These nozzles produce large droplets at pressures of 10 to 25 psi. The nozzles should be spaced less than 60 inches apart. The nozzle orientation and height should be set for 100 percent overlap.

Nozzle spacing between 30 to 40 inches produces the best spray patterns. Pressure influences spray patterns of flooding nozzles more than flat-fan nozzles. However, the spray pattern is not as uniform as with the flat-fan nozzles, and special attention to nozzle orientation and correct overlap is critical. The new turbo flood nozzles which have a pre-orifice and turbulence chamber have excellent spray patterns. Besides fertilizer suspensions, these nozzles are used with soil incorporated herbicides, preemergence without contact herbicides, and with spray kits mounted on tillage implements.

Flooding nozzles are designated "TK" or "TF" by Spraying Systems and "D" by Delavan. The value following the letters is the flow rate divided by 10 at a rated pressure of 10 psi. For example, TK-SS2 or D-2 are flood nozzles that apply 0.2 GPM at 10 psi.


TurfJet® 
The TurfJet® is a new nozzle designed for the turf industry. It is modeled after the Turbor® flood nozzle, which is used extensively in the application of crop protection products for agricultural field crops. The major difference is that the TurfJet® nozzle incorporates a larger orifice to accommodate heavier application volumes, which are common in the turf industry.

Hollow-Cone

Hollow-cone nozzles generally are used to apply insecticides or fungicides to field crops when foliage penetration and complete coverage of the leaf surface is required. These nozzles operate at pressures ranging from 40 to 100 psi. Spray drift potential is higher from hollow-cone nozzles than from other nozzles due to the small droplets produced.

Full-Cone

The wide-angle full-cone nozzles produce large droplets. Full-cone nozzles, which are recommended for soil-incorporated herbicides, operate at pressures between 15 and 40 psi. Optimum uniformity is achieved by angling the nozzles 30 degrees and overlapping the spray coverage by 100 percent.


Nozzle Materials
Nozzles can be made from several materials, including brass, nylon, stainless steel, hardened stainless steel and ceramic. Stainless steel nozzles last longer than brass or nylon and generally produce a more uniform pattern over a longer time. Nylon nozzles with stainless steel or hardened stainless steel inserts offer an alternative to solid stainless steel nozzles at a reduced cost. Ceramic nozzles have the longest life and are usually worth the added cost. Thermoplastic nozzles have good abrasion resistance, but swelling can occur with some chemicals. They are easily damaged when cleaned.

Do not mix nozzles of different materials, types, spray angles, or spray volumes on the same spray boom. A mixture of nozzles produces uneven spray distribution. 

Nozzle Selection
It is important to select a nozzle that develops the desired spray pattern. The specific use of a nozzle, such as broadcast application of herbicides or spraying of insecticides on row crops, determines the type of nozzle needed. Examine current and future application requirements and be prepared to have several sets of nozzles for a variety of application needs. In general, do not select a nozzle that requires a nozzle screen less than 50 mesh. Nozzles requiring 80-100 mesh screens plug too easily.
Follow the steps below to determine the correct nozzle type and capacity needed.

Step 1. Consult the label. The most important source of information is the pesticide label. Not only will the label specify the application rates, controllable pests and conditions needed to apply the pesticide, it often will provide information concerning the gallons per acre, nozzle type and spacing. Follow the guidelines outlined on the pesticide label. If nozzle recommendations are not stated on the label, use Table II to select a nozzle type best fitted to the application.

Step 2. Select operating conditions. Select or measure ground speeds in miles per hour (mph). If speed is unknown, follow the steps in NebGuide G88-865, Fine Tuning a Sprayer with the "Ounce" Calibration Method. Select the desired nozzle spacing and spray volume. For most broadcast applications, a 30-inch spacing is preferred. If the label doesn't recommend nozzle spacing or spray volume, follow university and chemical company recommendations.

Correct selection of a spray volume is important. It will influence several spray characteristics such as drift potential, coverage, droplet size, acres per tank, and pesticide efficacy. Generally the greater the operating pressure or spray angle, the smaller the droplets. Smaller droplets increase the drift potential. As the orifice opening becomes larger, the droplets increase in size.

Step 3. Calculate required nozzle discharge. To select a specific orifice size, the spray volume, nozzle spacing, and travel speed are needed for the following calculation: 

Nozzle Discharge (GPM) = Travel Speed x Nozzle Spacing x Spray Volume
____________________________
5940 


where: Travel Speed - miles per hour (mph) 
Nozzle Spacing - inches (in) 
Spray Volume - gallons per acre (GPA) 
Step 4. Consult a nozzle catalog. Once the nozzle discharge (GPM) has been determined, consult a nozzle catalog for a specific nozzle number or size. Using the nozzle type selected from the application guide (Table II), review the specification of these nozzles in the discharge capacity column. Several consecutive nozzles may meet your needs, but select a nozzle that operates at a low pressure and gives the desired particle size and still gives a range for "fine-tuning." Remember, most nozzles only perform well over a limited pressure range.

A linear relationship does not exist between pressure and flow discharge. If the discharge rate is not found in the catalogs, calculate the operating pressure using known catalog conditions:

psi1 = psi2 x [ GPM1
__________
GPM2 ] ² [1] 


where: subscript "1" is the desired condition, and 
subscript "2" is the known catalog condition. 
Avoid high pressures for the nozzle used. Higher pressures increase the drift potential and put strain on the sprayer components. Conversely, avoid pressures less than the recommended minimum pressure because spray patterns begin to distort and cause poor spray uniformity.

Step 5. Calibrate the sprayer. Once the nozzles are selected, purchased, installed and flushed, calibrate the spray system. Nozzle catalogs provide tables to show spray volumes for various nozzles, spacing, pressures, and ground speeds. Use these tables to initially set up the sprayer, and then use the "ounce" calibration method (NebGuide G88-865) to evaluate and adjust the sprayer for accurate application.

Table II. Spray nozzle selection guide for broadcast applications. 
Herbicides Fungicides Insecticides 
Post-Emerge 
Soil 
Incorporated Pre-Emerge Contact Systemic Contact Systemic Contact Systemic Liquid
Fertilizer 
Turbo TeeJet Good Good Good Good+ Good Good+ Good Good+ Good 
Air induction Good+ Good+ Good Good+ Good Good+ Good Good+ Good+ 
Extended range flat fan - - Good+ Good Good+ Good Good+ Good Good 
Pre-orifice flat fan Good+ Good+ Good Good+ Good Good+ Good Good+ Good 
Standard flat fan - - Good Good Good Good Good Good - 
Twin orifice flat fan - - Good+ - Good+ - Good+ - - 
Turbo FloodJet Good+ Good+ - Good - Good - Good Good+ 
TurfJet Good+ Good+ - Good - Good - Good Good+ 
Solid cone - - - Good - Good - Good Good+ 
- Information not available or not applicable. 


Nozzle Selection and Sizing Example
Suppose a postemergence herbicide is to be broadcast at 15 GPA at a speed of 5 mph. Using Table II as a guide, the "best" choice is a Turbo TeeJet. The recommended nozzle spacing is 30 inches. Calculate the required nozzle discharge:
Nozzle Discharge = 5 mph x 30 in x 15 GPA

5940 = 0.38 GPM 


Consult a nozzle catalog. The selected nozzle must have a flow discharge of 0.38 GPM when operated within the recommended range for the nozzle. A nozzle performance table shows the discharge rate at various pressures for several nozzle sizes. Table III shows that four nozzles listed in the catalog are possible choices. The TT11003, TT11004, TT11005, or TT11006 nozzles may be purchased for this application, but the TT11004 gives the most flexibility with a wide pressure range for "fine-tuning."

Table III. Nozzle data and comparison of pressures and discharge 
Catalog Calculated Eq. [1] 
Nozzle psi GPM psi GPM 
TT11003 60 0.37 64 0.38 
TT11004 30 0.35 36 0.38 
TT11005 20 0.35 24 0.38 
TT11006 15 0.37 16 0.38 

Nozzle Manufacturers
Several principal spray nozzle manufacturers supply local equipment dealers. Each manufacturer distributes nozzle catalogs. These can be obtained from the local dealer or ordered from the following addresses:
Century Engineering
P.O. Box 3018
Cedar Rapids, IA 52406
Phone: 800-472-4624

CP Products Co., Inc.
418 S. Price Road
Tempe, AZ 85281
Phone: 866-303-0600
Web: www.cpproductsinc.com

Greenleaf Technologies
P.O. Box 1767
Covington, LA 70434
Phone: 985-892-3870
Web: www.greenleaftech.com/

H D Ceramics
475 Steamboat Rd
Greenwich, CT 06836

Hardi Inc.
1500 West 76th St.
Davenport, IA 52806
Phone: 563-386-1730
Web: www.hardi-US.com

HYPRO
375 Fifth Avenue NW
New Brighton, MN 55112-3288
Phone: 800-424-9776
Web: www.hypropumps.com/Agriculture/

Lurmark, U.D.
Smyra, GA 30080
Phone: 404-435-4627
Web: www.lurmark.com/agriculture

Spraying Systems Co.
P.o. Box 7900
Wheaton, IL 60189-7900
Phone: 630-665-5201
Web: www.spray.com

Wilger Inc.
16549 Highway 194N
Lexington, TN 38351
Phone: 877-968-7695
Web: www.wilger.net

Additional Resource
Grisso, R. and R. Klein. Fine Tuning a Sprayer with the "Ounce" Calibration Method. Cooperative Extension, University of Nebraska. NebGuide G88-865. 

Weight and Measures Conversions
Weight 
16 ounces = 1 pound = 453.6 grams 
1 gallon water = 8.34 pounds = 3.78 liters 
Liquid Measure 
1 fluid ounce = 2 tablespoons = 29.57 milliliters 
16 fluid ounces = 1 pint = 2 cups 
8 pints = 4 quarts = 1 gallon 
Length 
3 feet = 1 yard = 91.44 centimeters 
16.5 feet = 1 rod 
5,280 feet = 1 mile = 1.61 kilometers 
320 rods = 1 mile 
Area 
9 square feet = 1 square yard 
43,560 square feet = 1 acre = 160 square rods 
1 acre = .405 hectare 
640 acres = 1 square mile 
Speed 
88 feet per minute = 1 mph 
1 mph = 1.61 km/h 
Volume 
27 cubic feet = 1 cubic yard 
1 cubic foot = 1,728 cubic inches = 7.48 gallons 
1 gallon = 231 cubic inches 
1 cubic foot = 0.028 cubic meters 
Common Abbreviations and Terms Used: 
GPM = gallons per minute 
GPA = gallons per acre 
psi = pounds per square inch 
mph = miles per hour 
RPM = revolutions per minute 
GPH = gallons per hour 
FPM = feet per minute