Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019                           RESEARCH 
 
DOI: 10.17482/uumfd.532535 
 
 
 
NUMERICAL INVESTIGATION OF THE SPRAY 
CHARACTERISTICS IN AN OUTWARDLY-OPENING 
PIEZOELECTRIC GASOLINE INJECTOR FOR DIFFERENT 
AMBIENT CONDITIONS 
 
 
*
İbrahim TAŞ   
**
Mehmet İhsan KARAMANGİL  
 
 
 
Received: 26.02.2019  ; revised: 02.05.2019; accepted: 10.05.2019 
 
 
Abstract: In this study, the spray characteristics of an outwardly-opening injector have been investigated 
numerically. Numerical analyses are carried out by taking temperature and pressure statuses of the 
internal combustion engine in cold temperature operations into consideration. The effects of these 
parameters on the evaporation rate, penetration, spray morphology, angle of the fuel spray and the Sauter 
Mean Diameter were key issues to be addressed. N-heptane fuel was used and the Kelvin-Helmholtz / 
Rayleigh-Taylor breakup model was adopted. The analyses were performed in the comprehensive 
environment of Fluent software. It was observed that the results complied with experimental data taking 
part in literature. Consequences demonstrated that increasing the ambient pressure intensified vortex 
formation, decreased penetration and increased fuel cone angle by forming a more compact fuel bundle. 
In addition, it was ascertained that the effect of the temperature parameter on the evaporation was less 
effective than the pressure parameter. 
Keywords: spray atomization and characteristics, mixture formation, hollow cone spray, KH-RT 
Farklı Ortam Koşullarında Dışa Doğru Açılan Piezoelektrik Benzin Enjektöründe Püskürtme 
Karakteristiklerinin Sayısal Olarak İncelenmesi 
 
Öz: Bu çalışmada, dışa doğru açılan bir enjektörün püskürtme karakteristikleri nümerik olarak 
incelenmiştir. Soğukta ilk çalıştırmada içten yanmalı motorun sıcaklık ve basınç durumları dikkate 
alınarak nümerik analizler yapılmıştır. Bu parametrelerin buharlaşma hızı, penetrasyon, püskürtme 
morfolojisi, yakıt püskürtme açısı ve Sauter Ortalama Çapı üzerindeki etkileri ele alınmıştır. N-heptan 
yakıtı kullanılmış ve Kelvin-Helmholtz / Rayleigh-Taylor ayrılma modeli benimsenmiştir. Analizler, 
Fluent yazılımı ile kapsamlı olarak gerçekleştirilmiştir. Sonuçların literatürde yer alan deneysel verilerle 
uyum içinde olduğu görülmüştür. Artan ortam basıncı vorteks oluşumunu şiddetlendirmiş, yakıt nüfuziyet 
derinliğini azaltmış ve daha kompakt bir yakıt demeti oluşturarak yakıt püskürtme açısını azaltmıştır. 
Ayrıca, sıcaklık parametresinin buharlaşma üzerindeki etkisinin basınç parametresinden daha az etkili 
olduğu tespit edilmiştir. 
Anahtar Kelimeler: püskürtme atomizasyonu ve karakteristiği, karışım oluşumu, içi boş koni püskürtme, 
KH-RT 
 
 
                                                          
*  Departmant of Automotive Engineering, Faculty of Technology, Pamukkale University, 20160, Turkey   
**Departmant of Automotive Engineering, Faculty of Engineering, Bursa Uludag University, 16059, Turkey 
   Correspondence Author: İbrahim TAŞ (itas@pau.edu.tr) 
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1. INTRODUCTION 
The transformation of the internal combustion engines from larger to smaller volumes has 
been necessitated due to increasing concern of fossil fuel issues stemming from the oil crisis in 
1970. The fact that the oil-based fuels used by the internal combustion engines are not unlimited 
has led authorities to conduct serious researches in order to increase the efficiency in defiance of 
decreasing engine volumes. What is more, by 1990, lower fuel consumption and lower rate of 
emission release have become a legal requirement. As an ideal alternative to the solution of this 
problem, gasoline direct injection (GDI) engines have emerged. The performance of these 
engines increases while reducing fuel consumption. Particularly, spray-guided GDI engines 
reduce emissions and fuel consumption while increasing engine performance. In gasoline direct 
injection engines, the formation of the mixture plays a major role in fuel consumption, 
emissions and engine performance (V. Basshuysen, 2009; Stiesch, 2003; Baumgarten, 2006). 
The air-fuel mixture is poor due to the lack of evaporation in port spray gasoline engines; 
hence, the mixture is required to be enriched a little. The GDI engine operating in stratified 
charging mode produces a cleaner exhaust gas than it is the case with port injection gasoline 
engines (Dahlander et al., 2008). The production of clean exhaust gas in the direct fuel injection 
spark-ignition engines depends directly on the quality of combustion. The quality of the 
combustion depends on many characteristics of the engine such as combustion chamber and 
piston shape, spark plug and injector position, particularly adequate composition of the fuel-air 
mixture with each other (V. Basshuysen, 2009; Stiesch, 2003; Baumgarten, 2006). 
In order to benefit from the superior characteristics of GDI engines, some problems should 
be avoided. The most important of these problems is that a flammable mixture is formed around 
the spark plug at the time of combustion. It is difficult to form a flammable mixture around the 
spark plug in the cylinder. The shape of the fuel spray sent into the cylinder and towards to 
spark plug is particularly important in cold conditions. However, due to some outstanding 
features of the outwardly-opening type injector which is the subject of this study, it can 
overcome this challenge.  
This injector has many outstanding features. These superior properties can be listed as 
shorter penetration depth, smaller Sauter Mean Diameter, reproducibility of spray, multiple 
injections capability and faster response time. Due to these features, the most modern direct-
injection gasoline engines use outwardly-opening type injectors. 
In modern GDI engines, numerical modeling and imaging techniques are extensively used 
to figure out fuel atomization and mixture formation. Thanks to the enhancement of computer 
performances and the development of multidimensional computational fluid dynamics (CFD) 
techniques, the CFD method has become a more efficient and efficient tool to investigate the 
formation of the mixture and the spraying process. Several different CFD models have been 
developed to explain the process of fuel atomization and breakup.  
In real-world applications, comprehensive model calibration works are carried out to 
provide proper estimates of decomposition and disintegration for different nozzles under various 
operating conditions. 
Over the last thirty years, many researchers have done countless studies to fully understand 
the mechanism of breakup of the liquid fuel spray in the combustion chamber.  
With an outwardly-opening piezoelectric injector, they have experimentally studied the 
spray characterization for the cold start conditions of the engine. The spray pressure, ambient 
pressure and temperature in the constant volume combustion chamber (CVCC) and then 
examined the variation in spray velocity and penetration. Also, they performed multiple 
injections in a single cycle and observed changes in spray morphology (Dahlander et al., 2008). 
Wang (2019) performed the injection of an externally opened piezoelectric driven injector 
used in direct gasoline injection engines, numerically and experimentally, with the help of the 
commercially accessible computational fluid dynamics software STAR-CD. In their study, 
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while the fuel temperature was 293 K, they evaluated the robustness of the disintegration 
models at two different ambient pressures, 1 and 10 bar. 
Das and Lim (2017) conducted physical experiments in a constant-volume combustion 
chamber to determine the effect of ambient pressure and temperature on spray characterization 
using n-heptane fuel under actual operating conditions of a diesel engine. With ANSYS 
FORTRE, they conducted high-pressure jet splitting using KH-RT atomization model. They 
used the k-epsilon turbulence model to simulate turbulence occurring during the formation of 
the mixture.  
Skogsberg et al. (2007) investigated the spray formation and atomization properties of a 
piezoelectric energized injector known as having A-nozzle geometry. A high-speed video 
camera was used with Phase Doppler Anemometry (PDA) to identify the basic mechanisms, 
droplet sizes and velocities of spray formation. Then, in order to examine these mechanisms in 
detail, Planar Mie Scattering and Planar Laser Source Fluorescent (LIF) were used. The systems 
used for the research changed various boundary conditions such as ambient pressure and 
temperature in the CVCC used in carrying out the experiments and also experimentally 
examined various injection strategies. They also compared the piezo- energized injector with a 
multi-hole solenoid driven injector. 
Sim et al. (2016) conducted experimental and numerical studies with an externally opened 
piezo-energized injector. They observed string-like structures at the time of spraying and 
revealed the missing aspects of the widely used disintegration models. Because the nozzle 
geometry in the injectors is not well known, they mentioned the importance of estimating the 
first drop diameter value in modeling studies. In contrast to previous studies suggesting that the 
first droplet diameter may be equal to the diameter of the injector or needle lift, they have 
proposed a calculation model for the first droplet diameter value. They also proposed a new 
modeling technique for more accurate simulation of string-like structures in numerical modeling 
of fuel fraction. 
Shi et al. (2008) performed an experimental and numerical study for a GDI engine with 
equipped an outwardly-opening cone type injector. In their research, were carried out in a 
pressurized chamber in spray characterization experiments by using a Mie scattering technique 
and PDA measurement. In the absence of evaporation, the fuel temperature was initially kept at 
-10  C and the temperature of the conditioned room were kept constant at 20  C and they 
carried out the experiments with various fuel types. They have obtained spray contours, droplet 
diameter, and velocity for the various injector and ambient pressures. 
The aim of the study was to examine the spray properties of the hollow cone type injector 
opened to the outside by considering the ambient pressure and temperature at the start of the 
engine in the cold. The effect of ambient pressure and temperature on spray penetration, fuel 
spay angle and Sauter Mean Diameter (SMD) was investigated. In the literature, experimental 
studies have been presented for the cold start situation but no numerical studies have been 
conducted. Therefore, this study was made to cover this the deficit in the literature. In addition, 
in our study, it is distinguished from other studies by numerically investigating how piezo 
triggered injectors used in gasoline engines are affected by ambient conditions under cold 
working conditions. Numerical studies with ANSYS Fluent software were validated using the 
experimental results and then numerical results of the parameters were compared. 
2. MATERIALS AND METHODS 
2.1. Spray Modeling 
Computer-aided engineering software, which is used by researchers and experts, has 
become widespread with the rapid development of computational capabilities of computers and 
mathematical modeling based calculation methods and methods in science and engineering. 
Ansys Fluent software, which is widely used in spray modeling studies, was also used in this 
study.  
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The lack of gasoline and derivative mixtures of the fuel to be used in experimental studies 
increases the reproducibility and reliability of the experiments. In the simulation studies, n-
heptane fuel was chosen because of the fact that it does not exhibit unstable properties in fuel 
blends and all chemical and thermodynamic properties are known. The physical properties of n-
heptane fuel are given in Table 1 (Das, 2017). Air is used as the ambient gas. The ambient gas 
(air) is from the database of the Fluent software. The air consists of carbon dioxide (CO2), 
nitrogen (N2), oxygen (O2) and water vapor (H2O). However, carbon dioxide and water vapor 
were not included in the analysis because they were negligible. The air is also considered as the 
ideal gas. 
 
Table 1.  Physical features of n-heptan fuel (Das, 2017) 
Fuel Properties N-heptan 
Density at 15  3 (kg/m ) 684 
Formula       
Hydrogen (weigth %) 16.1 
Carbon (weigth %) 83.9 
Kinematic Viscosity (cSt) 0.51 
Cetan Number 56.3 
 
The k-ε turbulence model from the Reynolds-Averaged Navier-Stokes (RANS) based 
renormalization group (Realizable) has been used for calculations in numerous research studies 
in the literature. In addition, liquid parcels (droplet groups) are included in the gas phase 
calculation area and Lagrangian discrete parcel method is used for spray modeling (Sim et al., 
2016).  
The hybrid fragmentation model consists of combining at least two different disintegration 
models. The main idea in the development of hybrid fragmentation models comes from more 
accurate modeling of primary and secondary atomization. For this reason, Kelvin-Helmholtz / 
Rayleigh-Taylor (KH-RT) atomization model was used for numerical calculations. This model 
has been developed to model the deterioration of fuel at high injection pressure as in diesel 
engines. This atomization model is also preferred because of high spray pressures in modern 
gasoline engines up to 350 bar. This atomization model deals with atomization in two stages, 
while the KH model for the primary atomization model provides a solution in the region near 
the injector nozzle and with the RT model for the secondary atomization model (Beale and 
Reitz, 1999; Lefevre and McDonell, 2017). A schematic representation of this atomization 
model is shown in Figure 1 (Ansys 18.1 Fluent Tutorials, 2019). For more detailed information, 
see (V. Basshuysen, 2009; Stiesch, 2003; Baumgarten, 2006; Kim et al., 2008; Rotondi and 
Bella, 2006). 
As can be seen from eq. (12), the high pressure causes an increase in the droplet velocity. 
The increased droplet velocity results in an increase in the number of Weber (We) in  
eq. (1). This results in more severe fragmentation.  
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Figure 1: 
Schematic representation of KH-RT breakup model (Ansys 18.1 Fluent Tutorials, 2019) 
 
In the following equations Vr  is the relative velocity between the ambient gas and the 
droplet velocity and the droplet diameter is r, also here, f and g indices indicate fuel and ambient 
gas, respectively.   
 
        
    (1) 
 
 
√   
   (2) 
   
 
    
     (3)   
 
 
   (4) 
√   
 
      (       )(      
   )
      (5) 
 (                )
 
   
   
 (               )
   [ ]   (6)  (   )(         )
 
The model's critical droplet radius    and breakup time     
           (7) 
 
        
     (8)       
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where the KH breakup model constant    is taken as equal to 40 as recommended by Lee 
and Park. For more detailed information, see article (Lee and Park, 2002). 
As the farther away from the injector nozzle, the Rayleigh-Taylor (RT) disintegration 
process takes place. In the process of RT fragmentation the droplet diameter    should be 
greater than the wavelength of     the fastest growing wave. The relationship between these 
two variables is expressed by the equation given below. 
 
          (9) 
 
where the     is from 0.1 to 1.0. 
 
  
    √  (10)   (     )
       
   
 [  (     )]
 √ (11)     
 √       
 
2.2. Validation                 
In the determination of the coefficients related the KH-RT fragmentation model, i.e. the 
calibration of the injector, the experimental study in the literature has been utilized. The 
boundary conditions, injector spray and ambient pressure of the tests are 200 and 5 bar, 
respectively (Şentürk, 2015). For the time to inject the injector and the time taken for the 
images, the values in the Şentürk (2015) study were accepted as reference. These values are 
1000 and 700 microseconds, respectively (Şentürk, 2015). 
The spray angle determination in boundary conditions according to Bosch norms is 
described as follows. At the maximum needle opening, an arc is drawn which will be tangent to 
5 mm below the needle upper surface. The drawn arc is intersected with the edges of the fuel 
cloud. The arc radius is considered as the fuel beam angle. For more details on how to perform 
other measurements of the spray cloud characteristic, see (Şentürk, 2015). 
 
 
Figure 2: 
Comparison of simulation and experimental result 
 
As a result of validation studies for the current experimental work, the breakdown model 
constants and ambient test conditions are given in Table 2 and Table 3, respectively. 
 
 
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Table 2. KH-RT atomization model parameters 
Parameters Value 
KH-RT - 
   0.61 
    0.10 
   0.50 
   40 
   5 
 
 
Figure 3: 
Comparison of experimental data and simulation results according to the depth of penetration 
(Experimental data were obtained from Zheng, 2013.) 
 
In addition, the penetration depth, which is one of the important characteristics of the fuel 
spray, is widely used in calibration studies. Figure 4 shows the change in the penetration depth 
of the spray cluster depending on time. In the calibration studies carried out with KH-RT  
breakup model constants given in Table 2, experimental results and numerical results are 
observed to be in harmony. 
2.3. Outwardly-Opening Injector 
The outward-opening hollow cone type injectors used in GDI engines respond precisely and 
very fast even at high operating pressures. As shown in Figure 3, the needle is opened out and 
the needle lift amount is maximum 35   and the needle diameter is 4 mm (Mathieu et al., 
2010). By controlling the needle lift and energized times, the mass flow of the fuel exiting the 
injector is controlled. In order to calculate the flow rate of the fuel according to the mass fuel 
flow formula, it is necessary to know the fuel discharge rate, density and the cross-sectional area 
of the injector. 
 
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 (        )
       √  (12)   
 
The theoretical velocity value can be obtained by writing the Bernoulli Equation between 
the combustion chamber (   ) and the injector pressure (    ) to calculate the output velocity. 
The actual velocity (    ) can be obtained by multiplying the theoretical velocity by the injector 
discharge rate. The discharge coefficient (  ) varies between 0.7 and 0.78 according to number 
of (Sim et al., 2016). In this study, the C was taken as 0.75. D
 
 
Figure 4: 
Schematic representation of the outward opening hollow cone 
 
In numerical spray modeling studies, the initial SMD value is as important as the correct 
estimate of the minimum injector output speed. The initial SMD value of the injector was 
determined to be equal to 90% of the maximum needle lift amount (Sim et al., 2016).  
The injector was energized over 1000  s and fuel injection continued during this time. 
Evaporation and fuel bundle distortion is increasing gradually as spraying continues. This 
makes it difficult to carry out the specified measurements. Therefore, when measuring the 
velocity vectors and the spray cone angle, images will be taken after 700  s after the start of 
spraying. 
2.4. Mesh Structure and Boundary Conditions of Simulation 
While this geometry was generated, the combustion chamber volume of the internal 
combustion engines and the spray injected during the fuel injection were determined to be so 
large that they could not come into contact with the combustion chamber walls. In the 
simulation studies, a cylindrical geometry with a diameter of 80 mm and a height of 55 mm was 
determined for the calculation domain. If this domain is designed to be larger than what is 
required, the calculation domain increases so the calculation time increases. Therefore, the most 
appropriate sizing process has been performed (Huang and Lipatnikov, 2011). 
If the spray point is started on the surface in the full top plane of the cylinder, there is a 
convergence problem during the solution. Therefore, the injection point is inside the calculation 
area with a cylindrical volume and is thought to be 5 mm below the top of the cylinder center 
(Huang and Lipatnikov, 2011). Also, the injector body is not included in the calculation volume. 
Therefore, it is not modeled for the spraying point. The type and size of the mesh structure is 
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Cut Cell and 1.5 mm, respectively. The total number of elements is 85692. The visual 
representation of the calculation volume is given in Figure 4. 
 
a. b. 
 
Figure 5: 
Calculation domain and injection point; 
a. Isometric view     b. Left view 
 
For the simulation boundary conditions, the injector pressure was kept constant at 350 bar 
and the pressure and temperature of the environment where the fuel was sprayed was changed. 
Simulation boundary conditions are given in Table 3. 
 
Table 3. Boundary conditions for simulation  
Variables Value 
Ambient Pressure (bar) 5, 10, 15, 20 
Ambient Temperature (K) 243, 253, 263, 273, 283, 293, 303, 313 
 
These parameters are chosen in order to determine the effect of the engine on the fuel-air 
mixture condition, spray characterization and shape during extreme cold climate/weather 
conditions or in environments with these atmospheric conditions.  
3. RESULTS AND DISCUSSION 
3.1. Effect of Ambient Temperature on SMD 
The fuel droplets interact with the ambient as they move through the ambient and the 
aerodynamic forces begin to influence the fuel particles due to the relative speed between the 
droplet and the surrounding and this enforce the fuel particles to deformation. If a sufficiently 
large force affects the fuel particle, the fuel droplets begin to disintegrate. The shattered large 
fuel droplets produce smaller fuel particles. The ratio of the total volume of these fuel particles 
to the total surface area, which is known as the SMD, indicates that atomization of the spray has 
improved.  
As can be seen from Figure 5, while the ambient pressure was kept constant, increasing the 
ambient temperature allowed the SMD to tend to shrink. Increasing the ambient temperature 
allows the fuel particles to get more energy so that the evaporation of the fuel becomes easier 
and the average diameter decreases. Şentürk (2015), reported that the SMD diameter value for 
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piezo energized injector is 10-15   . In addition, Iyer et al. (2004) presented similar results for 
the SMD diameter of 14.3   . 
 
Figure 6: 
Effect of ambient temperature on SMD 
3.2. Effect of Ambient Pressure on SMD 
The effect of ambient pressure on the droplet diameter indicated that the increase in ambient 
pressure caused the aerodynamic forces to increase. Increasing the pressure of the environment 
causes more intensive environmental conditions. Fuel means that droplets will be subject to 
more severe degradation as a result of contact with the site-intensive environment. As it is 
understood from Figure 6, the atomization intensity increases with the increasing pressure at the 
same ambient temperature and thus the SMD value decreases. 
 
Figure 7: 
Effect of ambient pressure on SMD 
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3.3. Effect of Ambient Temperature and Pressure on Spray Penetration 
The farthest distance that fuel can travel in the cylinder is of great importance in terms of 
both fuel air mixture and unburned hydrocarbon (UH) and soot emissions. It is not desirable for 
the fuel discharged from the injector to hit the cylinder walls or the piston plate. This affects 
hydrocarbon household emissions. On the other hand, it is desirable for fuel particles leaving 
the injector to reach sufficiently distant distances. For the fuel air mixture to be sufficiently rich 
in the vicinity of the spark plug, the fuel must reach an appropriate amount in this region. If the 
proper fuel-air mixture does not occur in the vicinity of the spark plug occurs event that is 
known as misfiring. In other words, the unburned fuel is removed from the cylinders and the 
unburned hydrocarbon emissions are increased. For these reasons, the spraying efficiency is of 
great importance in the formation of the mixture (V. Basshuysen, 2009; Dahlander et al., 2008; 
Dong et al., 2013; Park et al., 2002). 
At increased ambient pressure, the fuel delivery rate of the injector is reduced due to a 
decrease in the difference between the ambient pressure and the injector pressure. This is given 
in eq. (12). In addition to the decrease in velocity, the increase in the ambient density increases 
the intensity of the aerodynamic forces which strengthen the splitting. With the increase of the 
fraction, the fuel droplets are separated into smaller pieces and rapidly evaporate by drawing 
energy from the environment. Reduces the momentum of the droplet with the decrease in speed 
and the stronger evaporation of the droplets. 
More severe vortices in the fuel bundle that interacts with the environment more violently. 
In this way, the kinetic energy of the fuel bundle turns into the rotation and the spray depth is 
reduced. The results of this situation are given in Figure 7 (Kim et al., 2008; Schmid, 2012; Das, 
2008; Stiehl et al., 2013; Migliaccio et al., 2017).  
 
 
 
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1 
4 
2 3 
   
a. e. i.  
   
b. f. j. 
 
  
g. 
c. k. 
 
  
h. 
d. l. 
 
Figure 8: 
Velocity vector based on ambient pressure and temperature 
a. 5 bar 243 K, b. 10 bar 243 K, c. 15 bar 243 K, d. 20 bar 243 K, e. 5 bar 263 K, f. 10 bar 263 
K, g. 15 bar 263 K, h. 20 bar 263 K, i. 5 bar 283 K, j. 10 bar 283 K, k. 15 bar 283 K, l. 20 bar 
283 K 
The fuel spray form can be investigated by dividing into 4 zones as shown in Figure 7. The 
velocity vectors in each region are shown in Figure 7a-1 for different ambient pressures and 
temperatures. (1) is the region forming the hollow cone through the needle. (2) shows the vortex 
region formed in the opposite direction at the fuel spray tip due to the air resistance. (3) is the 
vortex formed by the stream moving in direction 4. (4) is the flow region from the center to the 
needle.  
In Figure 7a-7d, at 243 K constant temperature and different ambient pressures (5 bar, 10 
bar, 15 bar and 20 bar), the velocity values of the fuel spray in the direction of the arrow “1” 
were 66.6 m/s, 59.6 m/s, 55.3 m/s and 53.1 m/s, respectively. The increased ambient pressure 
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reduced the fuel spray speed in direction 1. Similarly, in Figure 7i-7l at 283 K constant 
temperature and different ambient pressures (5 bar, 10 bar, 15 bar and 20 bar), the velocity 
values of the fuel spray in the direction of the arrow “1” were 68.9 m/s, 61.1 m/s, 57.0 m/s and 
54.2 m/s, respectively. As the temperature increase decreases the density of the environment, 
there has been a slight increase in the velocity. Speed vectors of other regions (2, 3 and 4) can 
be investigated from graphics. 
Figure 8 shows that the spray penetration decreases with increasing ambient pressure at the 
same temperature. On the other hand, there was an increase in spray penetration with increasing 
temperature at the same ambient pressure. An increase in ambient temperature will result in a 
decrease in the density of gas, provided that the amount of the gas and the ambient pressure 
remain the same. The decrease in density will reduce the resistance forces acting on the fuel 
particles, so it will be difficult to disintegrate the fuel. As the bundle of non-fractured fuel can 
reach more distant points, an increase in spray depth occurs (V. Basshuysen, 2009; Stiesch, 
2003; Baumgarten, 2006; Schmid, 2012). 
 
Figure 9: 
Effect of ambient pressure and temperature on spray penetration 
 
3.4. Effect of Ambient Temperature and Pressure on Evaporation Rate 
The boiling point of liquids such as fuels varies depending on the environment pressure. 
Increasing ambient pressure is expected to increase with boiling point and a decrease in 
evaporation percentage. However, the increase in ambient pressure allows the viscous forces to 
be more effective. Thus, the process of disintegration is easier and the percentage of evaporation 
has increased. In addition, this situation decreases the value of SMD and hence also affects the 
quality of the mixture formation (Sim et al., 2016). 
As can be seen from the graph in Figure 9, the evaporation rate increased with increasing 
temperature. In addition, evaporation became more effective by increasing the ambient pressure. 
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Figure 10: 
Effect of ambient temperature and pressure on evaporation rate 
Another point is that if the vertical axis is followed in the horizontal axis for any constant 
temperature in Figure 9, the pressure increases and the effect on evaporation is higher. For 
example, for a constant temperature of 303 K, at 5 bar, 10 bar, 15 bar and 20 bar ambient 
pressures, the evaporation rates are 0.97, 1.13, 1.49, 2.25 respectively. The difference between 
the given values is increasing and this shows the greater role of evaporation in ambient pressure. 
3.5. Effect of Ambient Temperature and Pressure on Spray Morphology 
The image shown in Figure 10 is arranged according to the spray penetration and with the 
increasing ambient pressure, the spray cloud appears to be compact in a narrower volume. The 
compactness of the fuel cloud allows the formation of a fuel-air mixture in a narrower area 
(Park et al., 2002). 
If Figure 10 is carefully examined, the distance between the region where the spraying 
begins (where the blue color) and the point where the fuel cloud reaches (where the red color 
here) is reduced depending on the increased ambient pressure. In addition, the vortex regions of 
the spray bundle were agglomerated with increasing ambient pressure. With increasing ambient 
pressure, the larger amount of the fuel bundle is encapsulated in this ellipse. For example, in the 
images indicated by (a), (b), (c), (d), the ambient temperature is the same and the pressures are 
5, 10, 15, 20 bars in order. On the other hand, the increase in the ambient temperature was not 
as effective as the pressure on the compacting of the fuel cloud. The ambient pressures in the 
images indicated by (a), (e), (i) are the same and the temperatures are 243 K, 263K, 283 K, 
respectively (Iyer et al., 2004; Park et al., 2002; Schmid et al., 2010).  
 
 
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(a) (e)  (i) 
   
(b) (f)  (j)  
   
(c) (g)  (k)  
   
(d) (h) (l) 
 
Figure 11: 
Spray tip penetration and change of droplet diameters depending on ambient pressure and 
temperature 
a. 5 bar 243 K, b. 10 bar 243 K, c. 15 bar 243 K, d. 20 bar 243 K, e. 5 bar 263 K, f. 10 bar 263 
K, g. 15 bar 263 K, h. 20 bar 263 K, i. 5 bar 283 K, j. 10 bar 283 K, k. 15 bar 283 K, l. 20 bar 
283 K  
  
Figure 10 shows that the droplet diameters increase with the increase of ambient pressure in 
the regions shown with black circles. This increased the possibility of the droplets colliding with 
each other because the pressure in the environment increased and the fuel cloud became more 
compact. This explains that droplets in these regions (black circular region) have a larger 
diameter (Schmid, 2012; Oh et al., 2012). On the other hand, while the end portions of the large 
vortices have small droplet diameters, the droplet diameters of the sprayer end regions (the area 
shown in the blue circular) are larger (Schmid, 2012). 
 
 
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4. CONCLUSION 
In this study, calibration studies of a piezo-triggered gasoline injector with 350 bar spray 
pressure and A-nozzle geometry were investigated numerically with Ansys Fluent software. 
Using the parameters of this injector, the effect of ambient pressure and temperature on the 
spray shape, Sauter Mean Diameter (SMD), spray depth and evaporation rate were investigated. 
Results of the study: 
 
1) The Sauter Mean Diameter (SMD) is reduced while the ambient temperature and 
pressure increase. 
 
2) With the increase of ambient pressure, it decreased the speed of the fuel leaving the 
injector and thus reduced the amount of penetration. 
 
3) As expected, increasing the ambient temperature, the rate of evaporation increased, but 
the increase in ambient pressure was found to be more effective on the evaporation rate. 
 
4) The fuel cluster has become more compact when the ambient pressure is increased. This 
increased the probability of collision of the droplets in the lower vortex region of the fuel 
bundle. For this reason, an increase in the diameters of the fuel droplets in the region has been 
observed, and also the diameters of the fuel droplets in the vortex end zone have increased. 
 
5) The temperature parameter does not show a significant change on the fuel cluster shape. 
 
 
Nomenclature 
 
   Discharge coefficient Greek symbols 
P Pressure  
V Velocity   hollow cone angle 
r Radius   surface tension  
D Diameter    wavelength 
Re Reynolds number   density 
T  Taylor number   time 
We Weber number   dynamic viscosity 
Z Ohnesorge number  
 Subscript 
  
 0 initial 
 c critical  
 ch chamber 
 d  droplet 
 g  gas 
 l liquid 
 inj  injection 
 noz nozzle 
 r relative (gas–liquid) 
 KH Kelvin-Helmholtz 
 RT Rayleigh-Taylor 
 
 
 
200 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
 
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