Modern precision pneumatic drills (1-500 kg/ha) used in the cultivation of high density crops such as winter cereals (up to 400 plants/m2) are very high performance equipment that triple the working width (up to 9m) and rates (up to 14 km/h) compared to those used fifteen years ago. Most of enterprises commercialize such devices using as cornerstone a central pneumatic distributor in combination with a large number of radial outlets (24-48). In spite of the unquestionable advantages of these devices with regard to more conventional gravitational distributors, the main drawback remains the lack of transversal uniformity which has proven to be fairly sensitive to seed size and shape, to slight air flow changes related to partial obstructions of outlets, elbows and grips in discharge outlets, or vibrations and inclinations of the central distributor, as well associated to inadequate maintenance of the machine by untrained operators. Moreover, the lack of behavior predictability derives in a certain discredit of the pneumatic procedure. This work proposes a theoretical-empirical methodology to analyze the pneumatic circuit and its interaction with a variety of seeds types to be delivered, and selected operational machinery settings, within the aim of elaborating a test protocol which combined with low cost instrumentation will serve a base for predictive maintenance. Experimental data gathered in static and dynamic tests performed by the authors on at least two different seeders together with published information available on technical papers will be reviewed and used for further discussion on reliable diagnosis procedure

Barreiro Elorza, Pilar

Diezma Iglesias, Belen

Garrido Izard, Miguel

Moya Gonzalez, Adolfo

Urbina, Diego

Valero Ubierna, Constantino

English

Servicio de Coordinación de Bibliotecas de la Universidad Politécnica de Madrid

An IFPS Symposium Presentation                                                   
Common causes of failure of pneumatic 
distributors in high precision pneumatic seeders: 
Proposals towards predictive maintenance
Barreiro-Elorza P.*a,Urbina Da, Diezma  B.a, Moya A.a , Garrido M.a, Valero C. a 
aLPF-TAGRALIA, Departamento de Ingeniería Rural, ETSI Agrónomos. UPM, Madrid, Spain, e-mail: 
pilar.barreiro@upm.es   
Written for presentation at the 
2011 International Freight Pipeline Society Symposium 
Escuela Universitaria de Ingeniería Técnica Industrial (EUITI) 
Ronda de Valencia 3 
28012 Madrid 
Spain 
29 June - 1 July 2011 
Abstract. Modern precision pneumatic drills (1-500 kg/ha) used in the cultivation of high density crops  
such as winter cereals (up to 400 plants/m2) are very high performance equipment that triple the working 
width (up to 9m) and rates (up to 14 km/h) compared to those used fifteen years ago. Most of enterprises 
commercialize such devices using as cornerstone a central pneumatic distributor in combination with a 
large number of radial outlets (24-48). In spite of the unquestionable advantages of these devices with 
regard to more conventional gravitational distributors, the main drawback remains the lack of transversal 
uniformity which has proven to be fairly sensitive to seed size and shape, to slight air flow changes 
related to partial obstructions of outlets, elbows and grips in discharge outlets, or vibrations and 
inclinations of the central distributor, as well associated to inadequate maintenance of the machine by 
untrained operators. Moreover, the lack of behavior predictability derives in a certain discredit of the 
pneumatic procedure. This work proposes a theoretical-empirical methodology to analyze the pneumatic 
circuit and its interaction with a variety of seeds types to be delivered, and selected operational machinery 
settings, within the aim of elaborating a test protocol which combined with low cost instrumentation will 
serve a base for predictive maintenance. Experimental data gathered in static and dynamic tests 
performed by the authors on at least two different seeders together with published information available 
on technical papers will be reviewed and used for further discussion on reliable diagnosis procedures. 
Keywords. Granular product; advanced mechanization systems, agricultural machinery; fault diagnosis.    
Proceedings of th 14th International Freight Pipeline Society Symposium
- 226 -
Introduction
Pneumatic drill is a well established practice that allows large working widths together with 
centralized hopers which enable transport folding mechanisms. Frequently used machinery 
includes working widths with up to 9 m, with working rates of 14 km/h. 
The American Society of Agricultural and Biological Engineers awards yearly the 50 outstanding 
innovations in the field, the so called AE50. In the last five years, seven air drill systems have 
been awarded: two in 2007 (3310 Paralink Hoe Drill, SD550 Air Hoe Drill), three in 2008 (84 Air 
Drill See Hawk, Bourgault 6700ST Air Seeder, YP2425 Yield-Pro Planter) and two in 2010 
(1260 Early Riser Planter, P2070 Precision Hoe Drill). All of them hold in common the even 
larger work width (up to 21 m) compared to conventional systems, and high folding performance 
together with precision depth control. Figure 1 highlights the complexity of the pneumatic circuits 
that are required for upcoming machinery. 
Figure 1. 3310 Paralink Hoe Drill. AE50 outstanding innovation in 2007. 
http://www.asabe.org/resource/ae5011entry.html 
There is but little technical information about the performance of pneumatic drills (Profi Test 
2010 & 2011, Gil-Quirós et al., 2007; Barreiro et al., 2010; Diezma et al. 2011), and none 
scientific analysis of the pneumatic circuits, even though the ultimate quality of seed distribution 
relays on the homogeneity of the transversal distribution of seeds.  
Standard machine testing includes static and dynamic analysis of seed distribution, and sensors 
are continuously evolving to assess the amount of seeds being distributed by the pneumatics 
http://www.dickey-john.eu/. Supervision of the pneumatics is restricted to the rotating speed of 
the turbine or alternatively the hydraulic pressure that drives it, which must be adjusted 
according to the type of seeds, since its physical properties (size, shape, and specific weight) 
greatly affecting the flow properties (Barreiro et al., 2010). 
Figure 2 shows an example of static test on the transversal distribution of seeds for a 25 seed 
hoes machine (Diezma et al., 2011). A clear difference can be found between the areas where 
the tubes are clean and free of obstructions (left hand side) and the rest (right hand side). Any 
obstruction either partial or full has as counteract the increase in seed delivery for adjacent tube.  
Proceedings of th 14th International Freight Pipeline Society Symposium
- 227 -
020
40
60
80
100
120
140
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26
%
w
ith
re
sp
ec
tt
o
th
ea
ve
rg
ae
seederboot
Wellmaintained poorlymaintained
Figure 2. An example of static test on the transversal distribution of seeds for a 25 seed hoes 
machine (Diezma et al., 2011). Note the difference between correctly maintained tubes (hoes 1-
11) compared to those with poor revision (12-25). 
Some of the technical papers published lately (Profi Tests 2010 & 2011) refer the fact that 
smaller seeds such as oilseed rape show far poorer transversal distribution than large seeds as 
wheat. Figure 3 compares the transversal distribution with the same machine Pottinger 
Terrasem 3000 for peas (left) and barley (right) as referred by Gil-Quirós et al. (2007), several of 
the authors also contributing to this work. 
0.0%
20.0%
40.0%
60.0%
80.0%
100.0%
120.0%
140.0%
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24%
w
ith
re
sp
ec
tt
o
av
er
ag
e
seeder boot
peas
100 kg/ha 100 kg/ha occluded 140 kg/ha
0.0%
20.0%
40.0%
60.0%
80.0%
100.0%
120.0%
140.0%
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
%
w
ith
re
sp
ec
tt
o
av
er
ga
e
Seeder boot
Barley
200 kg/ha 200 kg/ha occluded 120 kg/ha 
Figure 3. Comparison of transversal distribution with the same machine Pottinger Terrasem 
3000 for peas (left) and barley (right) as referred by Gil-Quirós et al. (2007 
The primary objective of this work is to analyze the pneumatic circuit of two pneumatic drills: 4F-
AIRSEM-SNL 5032, and AIRSEM-6040, to study the variation of airflow in various situations 
throughout their width, as a mean for reflecting on the needs for prognosis and diagnostic tools 
to be developed in the near future. 
Proceedings of th 14th International Freight Pipeline Society Symposium
- 228 -
Material and Methods 
In this paragraph an overview is given on the machines and instruments used for this study  
Figure 4. One of the seeders used for this study. 
Pneumatic seeders 
Two different machines have been used: 4F-AIRSEM-SNL 5032 and AIRSEM-6040, one of 
which is presented in Figure 4. Note that boots are gathered in several rows: 4 and 3 for each 
machine respectively. 
To this end, a measurement was made on each tube during 30 seconds to get 7 speed data 
regarding the air rate (m/s) through the tubes. Each tube is characterized for three different 
turbine rates at 3000, 3500 and 4000 rpm. Also several strategic seed tubes have been 
characterized measured according to air rate (m/s) at the so called mushroom distributor.  
As a result, a total amount of 1708 air speed data has been obtained for the two pneumatic 
drills: 32 and 40 boots respectively. 
Machine 4F-AIRSEM-SNL 
5032 
AIRSEM-6040
Working Width 5.0 m 6.0 m 
Transport width 2.7 m 2.0 m 
Number of boots 32 40
Hopper capacity 1400 L 1400 L 
Table 1. Technical details of the pneumatic drills used for the tests. 
Proceedings of th 14th International Freight Pipeline Society Symposium
- 229 -
Instrumentation 
The pneumatic distributor of each seeder is analyzed by means of an electric motor (15HP) 
driving a hydraulic pump (30L/min) that powers the air turbine. The air speed is measured 
through a digital manometer with Pitot coupling. Details of the test assembly are given in Figure 
5.
Figure 5. Details of the test assembly: hydraulic pump (left) and Pitot digital manometer (right). 
Data Analysis 
Data are analyzed by means of Matlab 7.5 (Mathworks Inc.) using statistical analysis toolbox 
and dedicated data gathering routines. 
Results and discussion 
Effect of turbine speed and boot row 
The average air speed (m/s) for air drill 5032 is significantly higher from that of air drill 6040, 
9.91 + 0.06 m/s and 8.51 + 0.04 m/s respectively, which reflects the fact that a higher number of 
tubes (40 compared to 32) is used for the latter under the same turbine. Figure 6 and 7 show 
the results of means comparison for two factors studied (X1, row) and (X2, turbine regime). The 
effect on air speed as a result of turbine regime is clear and higher for 6040 compared to 5032 
(F value of 812 and 115 respectively). The effect of seeder row is higher in 5032 than for 6040 
(59.6 and 30.5 respectively) and the interaction is significant for the former (F=24.4) and not for 
the latter (F=2.2). Table 2 summarizes the results of ANOVA. 
Generally speaking in both seeders the differences among rows increases for increasing turbine 
regime (Figures 6 and 7). As expected the tube length is related with seeder row, since longer 
path is needed to reach the tubes (F=48.2 and 33.8 for model 5032 and 6040 respectively).  
The effect of turbine speed on air speed drop between the distributor and the end of the tubes is 
higher for model 6040 compared to 5032, while row a significant interaction with turbine regimen 
Proceedings of th 14th International Freight Pipeline Society Symposium
- 230 -
for the latter which is inexistent for model 6040. In General the air speed drop is higher for 
higher air speed. 
 5032 6040
 airspeed airspeeddrop tubelength airspeed airspeeddrop tubelength
SeederRow 64.0 59.6 48.2 30.5 53.2 33.8
 ** ** ** ** ** 
Turbinerate 812.1 0.2  1515.4 29.9 
 ** ns  ** ** 
Row*Tur.Rate 3.4 24.4  0.3 2.2 
 ** **  ns ns 
Table 2. Analysis of Variance on air speed flow, air speed drop between pneumatic distributor 
and the end of tubes, and tube length. The level of significance is indicated as follows: ** <0.01, 
* < 0.05, ns non significant. 
7.5 8 8.5 9 9.5 10 10.5 11 11.5 12 12.5
X1=4,X2=4000
X1=3,X2=4000
X1=2,X2=4000
X1=1,X2=4000
X1=4,X2=3500
X1=3,X2=3500
X1=2,X2=3500
X1=1,X2=3500
X1=4,X2=3000
X1=3,X2=3000
X1=2,X2=3000
X1=1,X2=3000
Click on the group you want to test
9 groups have population marginal means significantly different from X1=1,X2=3000
Figure 6. Means separation for pneumatic seeder 5032 according to air speed (m/s, x axis) the 
different factors (X1=row, X2=turbine regime) together with all interactions is displayed. 
Tube length versus air speed  
Figure 8 and 9 provide a scatter plot of air speed (m/s) versus tube length (m) for seeders 5032 
and 6040 respectively, comparing the effect of the different turbine regimes. Data from the 32 
and 40 boots are available and can be recognized as block of data. Seeder 5032 shows much 
higher varaibility in air speed as turbine regime increases (7.2%, 8.2% and 9.2 % for regimes 
3000, 3500, 4000rpm), compared to model 6040 (6.0%, 6.2% and 6.4% for 3000, 3500 and 
4000 rpm). 
Proceedings of th 14th International Freight Pipeline Society Symposium
- 231 -
7 7.5 8 8.5 9 9.5 10 10.5
X1=3,X2=4000
X1=2,X2=4000
X1=1,X2=4000
X1=3,X2=3500
X1=2,X2=3500
X1=1,X2=3500
X1=3,X2=3000
X1=2,X2=3000
X1=1,X2=3000
Click on the group you want to test
7 groups have population marginal means significantly different from X1=1,X2=3000
Figure 7. Means separation for pneumatic seeder 6040 according to air speed (m/s, x axis) the 
different factors (X1=row, X2=turbine regime) together with all interactions is displayed. 
7 8 9 10 11 12 13 14 15
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
3.8
air speed end tube (m/s)
tu
be
 le
ng
th
 (m
)
pneumatic drill 5032
3000
3500
4000
Figure 8. Scatter plot of air speed (m/s) versus tube length (m) for seeder 5032, comparing the 
effect of the different turbine regimes. 
Proceedings of th 14th International Freight Pipeline Society Symposium
- 232 -
Air speed at the distributor versus air speed drop  
Figures 10 and 11 present the scatter plot of air speed at the distributor compared to air speed 
drop in the seed pipes, for both seeders 5032 and 6040. The air speed drop is higher for 
increasing air speed and slightly higher for model 6040 compared to 5032 (3.02 +0.11 and 2.91 
+0.11 respectively) 
6 7 8 9 10 11 12
2.6
2.8
3
3.2
3.4
3.6
3.8
4
4.2
air speed end tube (m/s)
tu
be
 le
ng
th
 (m
)
pneumatic drill 6040
3000
3500
4000
Figure 9. Scatter plot of air speed (m/s) versus tube length (m) for seeder 6040, comparing the 
effect of the different turbine regimes. 
.
10.5 11 11.5 12 12.5 13 13.5 14 14.5 15 15.5
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
ai
r s
pe
ed
 d
ro
p 
(m
/s
)
air speed distributor (m/s)
pneumatic drill 5032
3000-1
4000-1
3000-2
4000-2
3000-3
4000-3
4000-4
Proceedings of th 14th International Freight Pipeline Society Symposium
- 233 -
Figure 10. Scatter plot of air speed at the distributor compared to air speed drop in the seed 
pipe for seeders 5032. 
8 9 10 11 12 13 14 15
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
5.5
ai
r s
pe
ed
 d
ro
p 
(m
/s
)
air speed distributor (m/s)
pneumatic drill 6040
3000-1
4000-1
3000-2
4000-2
3000-3
4000-3
Figure 11. Scatter plot of air speed at the distributor compared to air speed drop in the seed 
pipe for seeders 6040. 
Conclusion 
The starting point of this work was the demonstration that pneumatic seeders are becoming 
increasingly complex with working widths up to 21m, while technical field tests indicate that 
transversal uniformity is poor depending on maintenance and type of seed used. 
Any prognosis system needs to take into account the pneumatic characteristics yet no published 
data are available on the pneumatic behavior. 
The use of simple Pitot manometer on two models of seeder with varying number of rows and 
boots has allowed demonstrating the dramatic effect of seeder design and pipes lengths both on 
air speed and air speed drop. 
Monitoring the behavior of pneumatic seeders requires the incorporation of low cost sensors 
that enable the identification of faulty situations like occlusions. 
Acknowledgements 
The authors would like to thank Julio Gil Agüeda and Sons, seeder manufacturers, for their 
unexampled engagement in the development of pneumatics test essay   
Proceedings of th 14th International Freight Pipeline Society Symposium
- 234 -
References
ASABE. 2007-2011. AE50 outstanding innovations. www.asabe.org/resource/ae5011entry.html 
Barreiro, P. 2010. Amazone Cayena 2001: la siembra directa cuando el cielo no acompaña. 
VIDA RURAL 320:34-39. 
Diezma,B.; Garrido, M.; Valero, C.; Moya-González, A.; Barreiro, P; Espada, R.; Urbina, D. 
2011. Sembrando en las lomas de Villarrubia de Santiago con una Kuhn SD 4500. VIDA 
RURAL (suplemento MAQ Marzo) 2:9  
Gil-Quirós, V.; Barreiro, P. 2007. La sembradora Pottinger 3000T Terrasem de siembra rápida, 
en campo. VIDA RURAL 246: 46-50. Ruiz-García, L.; Barreiro, P.; Rodriguez-Bermejo, 
J.; Robla J.I. 2006. Supervisión del transporte mediante sistema de comunicación 
CANbus. HORTICULTURA INTERNACIONAL nº 51: 40-43. 
Profi Tests. 2010. Out of the ‘Pött’, into the dirt. Nº 12/2010  pp 16-19. ISSN 1430-6239 
Profi Tests. 2010. In good spirits in the right soil. Nº 02/2011  pp 16-20. ISSN 1430-6239 
Proceedings of th 14th International Freight Pipeline Society Symposium
- 235 -


Common causes of failure of pneumatic distributors in high precision pneumatic seeders: Proposals towards predictive maintenance

Archivo Digital UPM

AE50 outstanding innovations. www.asabe.org/resource/ae5011entry.html

Out of the ‘Pött’, into the dirt. Nº 12/2010 pp 16-19. ISSN 1430-6239 Profi Tests.

Sembrando en las lomas de Villarrubia de Santiago con una Kuhn SD 4500.

Common causes of failure of pneumatic distributors in high precision pneumatic seeders: Proposals towards predictive maintenance

Abstract

Similar works

Full text

Available Versions

Servicio de Coordinación de Bibliotecas de la Universidad Politécnica de Madrid

Archivo Digital UPM