Skip to Main Content
Skip Nav Destination
ASTM Selected Technical Papers
Pesticide Formulation and Delivery Systems: 33rd Volume, “Sustainability: Contributions from Formulation Technology”
By
Carmine Sesa
Carmine Sesa
Editor
Search for other works by this author on:
ISBN:
978-0-8031-7578-5
No. of Pages:
196
Publisher:
ASTM International
Publication date:
2014

Spray applicators have many choices in selecting a spray nozzle to make an application of an agricultural product. They must balance flow rate, spray pressure, and nozzle type and setup to deliver their agrochemical in the right droplet size for their particular needs. Studies were conducted to determine the spray exit angle and droplet velocity from three different flat fan nozzles (80°, 40°, and 20°) at three different spray pressures (140, 280, and 420 kPa). Each combination of nozzle and pressure was evaluated in a wind tunnel with airspeeds of 35.7, 53.6, 62.6, 71.5, and 80.5 m/s. At the nozzle exit, droplet velocities for the three nozzles tested were approximately 14, 20, and 25 m/s (∼30, 45, and 56 mph) for spray pressures of 140, 276, and 415 kPa (20, 40, and 60 psi), respectively. Droplet velocities were constant across the entire flowfield measured with airstreams speed were 35.7 m/s (80 mph), but as the airstream speed increased, droplets at the end of the spray sheet were quickly accelerated. The data presented will allow applicators and researchers to select the nozzle and operating conditions that best suit their spraying needs.

1.
Sirignano
,
W. A.
,
Fluid Dynamics and Transport of Droplets and Sprays
,
Cambridge University Press
,
New York
,
1999
, 329 pp.
2.
Iyer
,
V. A.
,
Abraham
,
J.
, and
Magi
,
V.
, “
Exploring Injected Droplet Size Effects on Steady Liquid Penetration in a Diesel Spray with a Two-Fluid Model
,”
Int. J. Heat Mass Trans.
, Vol.
45
,
2002
, pp. 519–531.
3.
Lin
,
S. P.
and
Reitz
,
R. D.
, “
Drop and Spray Formation from a Liquid Jet
,”
Annu. Rev. Fluid Mech.
, Vol.
30
,
1998
, pp. 85–105.
4.
Pilch
,
M.
and
Erdman
,
C. A.
, “
Use of Breakup Time Data and Velocity History Data to Predict the Maximum Size of Stable Fragments for Acceleration-Induced Breakup of a Liquid Drop
,”
Int. J. Multiphase Flow
, Vol.
13
,
1987
, pp. 741–757.
5.
Hoffmann
,
W. C.
,
Fritz
,
B. K.
,
Bagley
,
W. E.
, and
Lan
,
Y.
, “
Effects of Air Speed and Liquid Temperature on Droplet Size
,”
J. ASTM Int.
, Vol.
8
,
2011
, Paper ID JAI103461.
6.
Blaisot
,
J. B.
and
Yon
,
J.
, “
Droplet Size and Morphology Characterization for Dense Sprays by Image Processing: Application to the Diesel Spray
,”
Exp. Fluids
, Vol.
39
,
2005
, pp. 977–994.
7.
Panchagnula
,
M. V.
and
Sojka
,
P. E.
, “
Spatial Droplet Velocity and Size Profile in Effervescent Atomizer-Produced Sprays
,”
Fuel
, Vol.
78
,
1999
, pp. 729–741.
8.
Kahen
,
K.
,
Jorabchi
,
K.
,
Gray
,
C.
, and
Montaser
,
A.
, “
Spatial Mapping of Droplet Velocity and Size for Direct and Indirect Nebulization in Spectrometry
,”
Anal. Chem.
, Vol.
76
,
2004
, pp. 7194–7201.
9.
Knoche
,
M.
, “
Effect of Droplet Size and Carrier Volume on Performance of Foliage-Applied Herbicides
,”
Crop Prot.
, Vol.
13
,
1994
, pp. 163–178.
10.
Lake
,
J. R.
, “
The Effect of Drop Size and Velocity on the Performance of Agricultural Sprays
,”
Pestic. Sci.
, Vol.
8
,
1977
, pp. 515–520.
11.
Marchant
,
J. A.
, “
Calculation of Spray Droplet Trajectory in a Moving Airstream
,”
J. Agric. Eng. Res.
, Vol.
22
,
1977
, pp. 93–96.
12.
Stevens
,
P. J. G.
and
Kimberley
,
M. O.
, “
Adhesion of Spray Droplets to Foliage: The Role of Dynamic Surface Tension and Advantages of Organosilicone Surfactants
,”
Pestic. Sci.
, Vol.
38
,
1993
, pp. 237–245.
13.
Reichard
,
D. L.
,
Copper
,
J. A.
,
Bukovac
,
M. J.
, and
Fox
,
R. D.
, “
Using a Videographic System to Assess Spray Droplet Impaction and Reflection from Leaf and Artificial Surfaces
,”
Pest. Sci.
, Vol.
53
,
1998
, pp. 291–298.
14.
Miller
,
P. C. H.
and
Butler Ellis
,
M. C.
, “
Effects of Formulation on Spray Nozzle Performance for Applications from Ground-Based Boom Sprayers
,”
Crop Protect.
, Vol.
19
,
2000
, pp. 609–615.
15.
Hewitt
,
A. J.
,
Robinson
,
A. G.
,
Sanderson
,
R.
, and
Huddleston
,
E. W.
, “
Comparison of the Droplet Size Spectra Produced by Rotary Atomizers and Hydraulic Nozzles under Simulated Aerial Application Conditions
,”
J. Environ. Sci. Health
, Vol.
29
,
1994
, pp. 647–660.
16.
Nyttens
,
D.
,
Baetens
,
K.
,
De Schampheleire
,
M.
, and
Sonck
,
B.
, “
Effect of Nozzle Type, Size and Pressure on Spray Droplet Characteristics
,”
Biosyst. Eng.
, Vol.
97
,
2007
, pp. 333–345.
17.
Giles
,
D. K.
and
Ben-Salem
,
E.
, “
Spray Droplet Velocity and Energy Intermittent Flow from Hydraulic Nozzles
,”
J. Agric. Eng. Res.
, Vol.
51
,
1992
, pp. 101–112.
18.
Butler-Ellis
,
M. C.
and
Tuck
,
C. R.
, “
How Adjuvants Influence Spray Formation with Different Hydraulic Nozzles
,”
Crop Prot.
, Vol.
18
,
1999
, pp. 101–109.
19.
Butler-Ellis
,
M. C.
,
Tuck
,
C. R.
, and
Miller
,
P. C. H.
, “
How Surface Tension of Surfactant Solutions Influences the Characteristics of Sprays Produced by Hydraulic Nozzles Used for Pesticide Application
,”
Colloid Surface A
, Vol.
180
,
2001
, pp. 267–276.
20.
Fritz
,
B. K.
,
Hoffmann
,
W. C.
, and
Bagley
,
W. E.
, “
Effects of Spray Mixtures on Droplet Size under Aerial Application Conditions and Implications on Drift
,”
Appl. Eng. Agric.
, Vol.
26
,
2010
, pp. 21–29.
21.
Fore
,
L. B.
,
Ibrahim
,
B. B.
, and
Bens
,
S. G.
, “
Visual Measurements of Droplet Size in Gas Liquid Annual Flow
,”
Int. J. Multiphase Flow
, Vol.
28
,
2002
, pp. 254–262.
22.
Hoffmann
,
W. C.
,
Fritz
,
B. K.
,
Thornburg
,
J. W.
,
Bagley
,
W. E.
,
Birchfield
,
N. B.
, and
Ellenberger
,
J.
, “
Spray Drift Reduction Evaluations of Spray Nozzles Using a Standardized Testing Protocol
,”
J. ASTM Int.
, Vol.
7
,
2010
, Paper ID JAI102820.
23.
Klein-Douwel
,
R. J. H.
,
Frijters
,
P. J. M.
,
Somers
,
L. M. T.
,
de Boer
,
W. A.
, and
Baert
,
R. S. G.
, “
Macroscopic Diesel Fuel Spray Shadowography Using High Speed Digital Imaging in a High Pressure Cell
,”
Fuel
, Vol.
86
,
2007
, pp. 1994–2007.
24.
Goldsworthy
,
L. C.
,
Bong
,
C.
, and
Brandner
,
P. A.
, “
Measurement of Diesel Spray Dynamics and the Influence of Viscosity Using PIV and Shadowography
,”
Atomization Spray
, Vol.
21
,
2011
, pp. 167–178.
25.
Dodge
,
L. G.
, “
Comparison of Performance of Drop-Sizing Instruments
,”
Appl. Optics
, Vol.
26
,
1987
, pp. 1328–1341.
26.
Hoffmann
,
W. C.
and
Hewitt
,
A. J.
, “
Comparison of Three Imaging Systems for Water-Sensitive Cards
,”
Appl. Eng. Agric.
, Vol.
21
,
2005
, pp. 961–964.
27.
Hinds
,
W. C.
, “
Aerosol Technology: Properties, Behavior, and Measurement of Airborne Particles
,”
Wiley
,
New York
,
1982
, 432 pp.
28.
ASAE S572.1
,
2009
, “
Spray Nozzle Classification by Droplet Spectra
,”
American Society of Agricultural Engineers
,
St. Joseph, MI
.
29.
Bouse
,
L. F.
, “
Effect of Nozzle Type and Operation on Spray Droplet Size
,”
Trans ASAE
, Vol.
37
,
1994
, pp. 1389–1400.
This content is only available via PDF.
You do not currently have access to this chapter.
Close Modal

or Create an Account

Close Modal
Close Modal