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Al-Khwarizmi Engineering Journal,Vol. 1

 
Experimental Study of the Effect of 

Emissions 

Miqdam T. Chaichan*          
*Energy and Renewable Energies Technology Center

**Department of 

(Received 27

https://doi.org/10.22153/kej.2017.11.001

 
Abstract 
 

The present study investigated the impact of fuel kind on the emitted emissions at 

types of available fuels in Iraq were tested. The tests conducted 

of 82, premium gasoline with an octane number of 92, and M20 (consist of 20% methanol and 80% 

gasoline). The 2 liters Mercedes-Benz engine 

The results showed that engine operation at idle speed emits hi

The produced emission levels depend highly on fuel type. 

lower emissions level except for noise

showed high levels of emitted CO, CO2
near zero levels for most of the idle speeds for the tested fuels.
 
Keywords: Idle period, engine speed, M20, NOx, CO, HC, noise.

 
1. Introduction 
 

The climate change and the greenhouse 

became known to all as the causes of 

phenomena are well known also. The burning of 

fossil fuels produce many pollutants the 

environment and in its contamination

Combustion of gasoline fuel in spark ignition 

engine is one of the most used fossil fuel. As the 

gasoline automotives increased profoundly

since 2003 to become more than 4.5 million cars

with an increment level of 17.5% yearly [2].

About 38% of it concentrated in Baghdad the 

capital with about 1.75 million vehicles

The Iraqi environment especially Baghdad i

much polluted and highly sensitive to pollutants 

due to subsequent wars and dust storms

as, due to fossil fuels burning [4]. Besides 

trucks and heavy construction equipment

Khwarizmi Engineering Journal,Vol. 13, No. 1, P.P. 1- 12 (2017) 

Experimental Study of the Effect of Fuel Type on the Emitted 

Emissions from SIE at Idle Period 
 

          Khalil I Abaas**        Bashar A Mohammed
Energy and Renewable Energies Technology Center/ University of Technology

**Department of Mechanical Engineering/ University of Technology 

*Email: 20185@uotechnology.edu.iq 

**Email: kh195814@yahoo.com 

 
27 January 2016; accepted 2 November 2016) 

https://doi.org/10.22153/kej.2017.11.001 

investigated the impact of fuel kind on the emitted emissions at the idling period. Three 

tested. The tests conducted on ordinary gasoline with 

octane number of 92, and M20 (consist of 20% methanol and 80% 

Benz engine was used in the experiments. 

that engine operation at idle speed emits high levels of CO, CO2, HC, NOx and noise. 

ed emission levels depend highly on fuel type. The premium gasoline (ON=92) represents the 

lower emissions level except for noise at all idling speed. Adding methanol to ordinary gasoline (ON=82) 

2, HC compared with premium gasoline. Emitted NOx emissions were

near zero levels for most of the idle speeds for the tested fuels. 

Idle period, engine speed, M20, NOx, CO, HC, noise.   

The climate change and the greenhouse effects 

became known to all as the causes of these 

are well known also. The burning of 

e many pollutants the 

environment and in its contamination [1]. 

gasoline fuel in spark ignition 

engine is one of the most used fossil fuel. As the 

profoundly in Iraq 

4.5 million cars 

with an increment level of 17.5% yearly [2]. 

bout 38% of it concentrated in Baghdad the 

vehicles [3].  

The Iraqi environment especially Baghdad is 

to pollutants 

wars and dust storms, as well 

[4]. Besides to cars, 

trucks and heavy construction equipment, about 

15000 shared electrical generators

compensate the lack of the grid electricity.

Hundreds of thousands of small wattage 

generators preserve in Iraqi citizen houses. 

Besides, the power generation in Iraq depends 

highly on heavy oils that emitted very high levels 

of soot and carbon depositions [5]

Idling, which means operating the 

automotive’s engine without loading it or the 

clutches are in disengaged condition. The engine 

speed at idling ranges between 800 and 1500 rpm. 

The engine idle speed increases with using 

accessories like air conditioning, which is an 

essential device for Iraqis in summertime

drivers use idling for many purposes as w

the car engine up in the cold morning, waiting for 

someone, parking, and waiting at checkpoints. 

Iraqi citizens are familiar with the last one that 

takes a long time from their traveling period 

reached hours in sometimes [7]

  
Al-Khwarizmi 

  Engineering  
Journal 

on the Emitted 

r A Mohammed*** 
University of Technology 

idling period. Three 

ordinary gasoline with an octane number 

octane number of 92, and M20 (consist of 20% methanol and 80% regular 

, HC, NOx and noise. 

gasoline (ON=92) represents the 

ordinary gasoline (ON=82) 

Emitted NOx emissions were 

shared electrical generators are operating to 

the grid electricity. 

Hundreds of thousands of small wattage electric 

generators preserve in Iraqi citizen houses. 

, the power generation in Iraq depends 

highly on heavy oils that emitted very high levels 

[5].  

Idling, which means operating the 

loading it or the 

clutches are in disengaged condition. The engine 

speed at idling ranges between 800 and 1500 rpm. 

eases with using 

air conditioning, which is an 

essential device for Iraqis in summertime [6]. The 

drivers use idling for many purposes as warming 

the car engine up in the cold morning, waiting for 

someone, parking, and waiting at checkpoints. 

are familiar with the last one that 

long time from their traveling period 

]. The checkpoints 


Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
2 

 
spread all over Baghdad streets increased the cars 

idle time without knowing its hazards. 

Idling results in poor air quality, as the streets 

choked with cars and trucks, emit an enormous 

amount of harmful emissions. The emitted NOx 

and volatile organic compound, during the idle 

period, reacts with sunlight to form ozone that 

built, especially in long and hot days, to produce 

smog. Smog is a damaged material, as it is a lungs 

irritant, attack Asthmatics patients. Idling poses a 

threat to the drivers as the pollutants 

contaminations increased inside the driving 

cabinet more than outside it. Those drivers 

exposed to elevated health risks as lung cancer. 

Also, at idling period the noise pollution increased 

can raise heart rates, blood pressure, and levels 

hormones stresses [8 - 10]. 

Many researchers studied this phenomenon 

and confirmed its damages to climate, health and 

human morality. KeL (2008) proposed Least 

Squares Support Vector Machines (LS-SVM) 

build up a model for engine idling. The study 

aimed to produce optimal ECU that can 

automatically define the user behaviors. The 

results gave good agreements with actual test 

results and showed enhancement in engine idling 

performance [10]. Wong (2009) introduced a 

novel modeling approach for engine idle 

operation. The study results predicted good 

agreement with the practical tests [11]. 

Sharma (2011) tested the resulted benefits 

from operating engine at idle mode with an ultra-

lean burn. For this purpose, the authors used 

hydrogen as a fuel. The results indicated 

significant improvements in the emitted emissions 

[12]. Gharib (2012) used a robust controller for a 

vehicle based on quantitative feedback theory to 

control engine at idle speed. After reviewing 

various designs the required one used. Tracking 

problems simulation technique used to achieve 

successful design. The simulation results 

indicated proper behavior by the designed 

controller in idling operation [13].   

Nordin (2013) measured organic aerosol mass 

concentrations of gasoline engine operated at idle 

speed. The study found the emitted aerosols 

similar to that measured in the urban environment 

that gives an indication of the high hazards of 

petrol engine idle operation [14]. Pirs (2014) 

tested the exhaust emissions sent out by a gasoline 

automobile fueled with E85 (gasoline-ethanol 

blend). The tests conducted to assess the effect of 

fuel additive on engine idle speed emissions. The 

results showed that NOx reduced while CO and 

HC increased with using E85 compared with 

conventional gasoline [15]. 

The present study aims to measure and 

evaluate the impact of the idle period on the 

emitted pollutants. Three types of fuels used in the 

study; two of them conventionally employed in 

Iraq, they are normal gasoline (ON=82) and 

premium gasoline (ON=92). The third fuel was 

M20 (80% gasoline (ON=82) and 20% methanol), 

which recommended as an alternative fuel to the 

low octane number Iraqi gasoline by many 

researchers [16- 18].   

 
2. Experimental Setup 
2.1. Materials 

 
Two gasoline fuels were used in this study. 

The first one is the ordinary gasoline with octane 

number (ON) =82, and the second the premium 

type with ON=92. Also, 20% methanol with 

purity of 99.92% added to ordinary gasoline 

(ON=82) with 80% volume to form M20. Iraqi 

conventional gasoline characterized by its low 

octane number and high content of sulfur and 

lead. The properties of tested fuels were measured 

in Al-Doura Refinery Laboratory-Baghdad. Table 

1 represents the tested fuels properties.    

 
2.2.  Tests Apparatus 
 

A Mercedes-Benz with two liters displacement 

volume spark ignition engine used in the present 

study. The four strokes engine is water cooled and 

has four cylinders. The engine coupled to a 

hydraulic dynamometer to measure the brake 

torque (This facility was not used due to the 

absence of its need). Fig. 1 shows the tests rig, 

and Table 2 lists the used engine technical 

specifications. 

 
2.3.  Exhaust Gas Pollution Analyzing 
 

A gas analyzer type HG-550 (Fig. 2) was 

utilized to quantify the exhaust gas discharges 

(CO, CO2, HC, and NOx). This instrument created 

by Hephzbah Co. Ltd at 16/10/2013, the 

calibration sheet took from the industrial facility 

assessment sheet. A sound pressure level meter 

sort SL-4010 (Fig. 3) supplied with an amplifier 

sort 4615was used to quantify the general sound 

pressure levels. The instrument was calibrated by 

a standard calibrator sort pisto-telephone 4220. 

 
Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
2.4.  Error Analysis 
 

The measurement accuracy in trial 

examinations is urgent in deciding the outcomes 

sensibility or not. The error sources are 

characterized by calibrating the measuring 

hardware. All the engine measuring devices were 

calibrated, and the uncertainty levels in the study 

were estimated. Table 3 demonstrates the 

adjustment precision of the measuring 

instruments.  

The calculated uncertainty in the present study 

was less than 5% in all estimations. The trials 

irregular mistakes minimize in the tests by 

repeating the tests three times. These trials results 

reported more than 95% certainty for every tested 

condition. 

 
Table 1,  

properties of gasoline and methanol fuels.  
Property Gasoline Methanol 

Chemical formula 
various CH3OH 

Oxygen content by mass [%] 0.00 50.00 

Density at NTP [kg/l] 0.74 0.796 

Lower heating value [MJ/kg] 43.12 20.09 

Volumetric energy content [MJ/l] 31.70 15.80 

Stoichiometric AFR [kg/kg] 14.70 6.40 

Energy per unit mass of air [MJ/kg] 42.60 19.85 

Research octane number 89-95 108.90 

Motor octane number 85 88.60 

Boiling point at I bar [ºC] 25-215 64.60 

Heat of vaporization [kJ/kg] 180-350 1160.00 

Reid vapor pressure [psi] 7.00 4.60 

 
Fig. 1. The experimental rig of SI engine. 

 
Fig. 2. The gas analyzer type HG-550 used in 

the tests. 

 
        Fig. 3. The sound pressure level meter type 

SL-4010used in the tests. 


Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
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Table 2,  

The main technical specifications of the engine. 

Item specification  

Engine 4-cylinder-inline engine 

(four-stroke) 

Displacement 2 liters 

Fuel System Carburetor 

Cooling Water 

 
Table 3,  

Measurement type and accuracy for present study. 

Measurement accuracy 

Engine speed 

measurement 

±1.3% 

Sound pressure level 

measurement  

±1.09% 

Exhaust gases 

concentrations 

measurement 

±0.82% 

Exhaust gas 

temperature 

measurement 

± 0.67 

 
2.5. Tests Procedure 
 

The engine was left to warm by running for 

several minutes until the cooling water, and 

lubricant oil reached 75°C. In all tests, the engine 

was not loaded. The engine left to run at idle 

speeds of 800, 1000, 1200 &1500 rpm. The 

concentrations of the emitted emissions CO2, CO, 

HC, NOx, and noise measured every 5 minutes. In 

each test, the measuring period limited to 20 

minutes. This time considered because achieving 

an idling time in this size is possible in Baghdad 

city practical life and other Iraqi areas due to the 

spread checking points and traffic strangulations. 

The resulted emissions from three idling speeds 

were selected for practical comparison. These are 

800 rpm where it is considered as idling speed for 

cars that do not use accessories. Also, 1000 rpm 

as an idling speed was chosen for new engines 

with the drivers using air conditioning while 1500 

rpm selected as the higher idle speed for a car 

engine with using the accessories. 

 
3. Results and Discussions 
 

CO produced from incomplete combustion, 

and it is a very dangerous and poisonous gas. Fig. 

4 A, B, and C represent the emitted CO through 

the idling period at variable engine speeds for the 

tested fuels. For ordinary and excellent gasoline 

the minimum concentrations were at the least 

values when the engine runs at 800 rpm, as Fig. 4 

A shows. The methanol high heat of evaporation 

needs high combustion chamber temperature, 

which is not available at 800 rpm. CO 

concentrations were increased with increasing 

idling speed higher than 800 rpm while for M20 

reduced with this increment. In A and B cases 

increasing engine idling speed means increasing 

the consumed fuel at low combustion chamber 

temperatures that caused incomplete combustion. 

In constraint, in case C, increasing idling speed 

which increased the combustion chamber 

temperature, enhanced methanol evaporation and 

as a result reduced CO concentrations. Fig. 4 D, 

E, and F indicate that the lower CO concentrations 

came out with premium gasoline burning for the 

three compared speeds. At 800 rpm, the emitted 

CO from ordinary gasoline and methanol was 

higher by 127.39% and 256.47% in relation to 

premium gasoline. At 1000rpm, the emitted CO 

from ordinary gasoline and methanol was higher 

by 46.63% and 54.67% compared to excellent 

gasoline. 

 
Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
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Fig. 5 represents the CO2 concentrations for 

variable engine speeds through the tested idle 

period. Fig. 3. A & B are similar to the Fig 4 A & 

B where CO2 levels at the lower value when the 

engine runs at 800 rpm. In Fig 5 C, CO2 

concentrations are higher than the other emitted 

values with other idle speed except for 1350 rpm. 

The oxygen existence in the methanol structure 

enhances the combustion and increases CO2. Fig 5 

D, E and F show that premium gasoline emitted 

lower CO2 concentrations compared to the other 

fuel at all the studied idling speeds as it did with 

CO2. This result indicates that premium gasoline 

is more useful for health and environment except 

for its lead content where the Iraqi gasoline has a 

high level from this poisonous material. At 800 

rpm, the emitted CO2 from ordinary gasoline and 

methanol was higher by 90.71% and 138.24% 

compared to premium gasoline. At 1000 rpm, the 

emitted CO from ordinary gasoline and methanol 

was higher by 41.51% and 47.63% compared to 

excellent gasoline.   

Fig. 4. the idling time effect on emitted CO for tested fuels at variable engines speeds. 

  
Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
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Fig. 6 shows the effect of idle speed on emitted 

HC for the tested period intervals. From the 

figures A, B & C, HC concentrations are in the 

lowest values at 1500 rpm for all fuels. However, 

the concentrations values varied largely as 

ordinary gasoline emitted 250 ppm HC at the 

lowest value while premium gasoline emitted 25 

ppm. Figures D, E, and F, compare between the 

emitted HC at three idling speeds. The figures 

shows high HC concentrations with M20 

operation, which indicates the hazard from using 

this alternative at idle speed whatever it was. At 

800 rpm, the emitted HC from regular gasoline 

and methanol was higher by 82.01% and 220.11% 

compared to premium gasoline. At 1000 rpm, the 

emitted HC from ordinary gasoline and methanol 

was higher by 53.24% and 71.80% compared to 

premium gasoline. 

 
Fig. 5. the idling time effect on emitted CO2 for tested fuels at variable engines speeds. 

  
Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
7 

 
Fig. 7 represents the emitted NOx for the 

studied cases. NOx concentrations are very low 

and reach zero sometimes at idle speed except for 

1350 and 1500 rpm for regular gasoline and M20. 

When premium gasoline is used the resulted NOx 

are zero for all the tested idle speeds. Figure D, E, 

and F, represent the comparison between the 

emitted NOx for the used fuels. The emitted NOx 

at 800 and 1000 rpm are zero for the three fuels 

while at 1500 rpm the emitted NOx increased for 

M20 and ordinary gasoline. Until now, all the 

emitted emissions from excellent gasoline are 

better than the resulted from other fuels. 

 
Fig. 6. the idling time effect on emitted HC for tested fuels at variable engines speeds. 

 
Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
8 

 
Noise radiated from the engine through the 

intake and exhaust strokes, and from the 

fluctuations in components of the engine. Most of 

the engine noise generated by the combustion 

process, while others caused by friction, 

unbalanced components, and cooling fans. A 

higher noise level exists at lower frequencies as in 

idling speed case. Fig. 8 shows lower noise levels 

at high idling speeds for the tested fuels. At 

medium and higher speeds the noise pressure 

waves interfere with each other’s causing lower 

noise levels. Figures D, E, and F, clarify that M20 

has the lower noise values for the tested speeds. 

The M20 has lubricating facilities better than the 

other fuels that manage it to produce lower noise 

at all the tested idle speeds. At 800 rpm, the 

produced noise from ordinary and excellent 

gasoline was higher by 7.19% and 1.24% 

compared to methanol. At 1000 rpm, the resulted 

noise from ordinary and excellent gasoline was 

higher by 2.19% and 1.43% compared to 

methanol. 

 
Fig. 7. The idling time effect on emitted NOx for tested fuels at variable engines speeds. 

  
Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
9 

 
4. Conclusions 
 

The engine operation at idle speed produces 

regular emissions (CO, CO2, HC, NOx and noise) 

with hazard levels. The present study confirms 

that these levels depend highly on fuel type. From 

the three tested fuels the premium gasoline 

(ON=92) represents the lower emissions. Adding 

methanol for ordinary gasoline (ON=82) showed 

bad emitted emissions trends for CO, CO2, HC 

which were at high levels compared with 

premium gasoline. The high methanol 

temperature of evaporation causes fuel 

evaporation difficulties for parts of the fuel, which 

increases the previous mentioned emissions. 

Emitted NOx was near zero levels for most of the 

idle speeds for the tested fuels. Engine noise 

reduced with increasing idle speed. Also, M20 

showed the lowest noise levels compared to other 

ones. 

 
Fig. 8. The idling time effect on emitted Noise for tested fuels at variable engines speeds. 


Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
10 

 
Notation 

 
BTDC  Before top dead center 

CO  Carbon monoxide 

CO2  Carbon dioxide 

dB  Decibel 

EGR  Exhaust gas recirculation 

HC  unburned hydrocarbon 

IT  Injection timing 

NOx  Nitrogen oxides 

 
5. References 
 

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(EGR) and injection timing effect on 

emitted emissions at idle period, Al-

Khwarizmi Engineering Journal, vol.10, 

No. 4, pp: 33-44, 2014.  

[2] Kgabaar net, Do you know how many 
cars in Iraq, 20-1-2015. Available at: 

http://www.khabaar.net/index.php/permal

ink/45944.html  

[3] Alaalem report, A scan 112 cars for every 
thousand Iraqi citizens and 65 cars for 

each one paved street. 19-11-2013. 

Available at: 

http://www.alaalem.com/programs/pdf/u

pload/irq_2002244289.pdf 

[4] Kazem A A, Chaichan M T & Kazem H 
A, Effect of dust on photovoltaic 

utilization in Iraq: review article, 

Renewable and Sustainable Energy 

Reviews, vol. 37, September, pp: 734-

749, 2014. 

[5] Al-Waeely A A, Salman S D, Abdol-
Reza W K, Chaichan M T, Kazem H A 

and Al-Jibori H S S, Evaluation of the 

spatial distribution of shared electrical 

generators and their environmental 

effects at Al-Sader City-Baghdad-Iraq, 

International Journal of Engineering & 

Technology IJET-IJENS, vol:14, No:2, 

pp: 16-23, 2014. 

[6] Chaichan M T & Faris S S, Practical 
investigation of the environmental 

hazards of idle time and speed of 

compression ignition engine fueled with 

Iraqi diesel fuel, International J for 

Mechanical and Civil Eng., vol. 12, No. 

1, pp: 29-34, 2015. 

[7] Nie, J., Beyea J, Bonner M.R., Han D, 
Vena J.E., Rogerson P, Vito D, Muti P, 

Trevisan M and Freudenheim J.L., 

Environmental exposure to traffic 

polycyclic aromatic hydrocarbons 

(PAHs) and risk of breast cancer, 

American Association for Cancer 

Research Annual Meeting, Anaheim, CA, 

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[8] Raaschou-Nielsen O, Hertel O, Thomsen 
B.L. and Olsen J.H., Air Pollution from 

Traffic at the Residence of Children with 

Cancer." American Journal of 

Epidemiology, 2001, 153, 5: 433-443. 

[9] Johnson, M., S. Duncan, and S. 
McConnell. Startup and Idle Emissions 

Analysis of a 2009 VW Jetta Using 

PEMS SemtechD, ICES2012-81170. 

Presented at ASME 2012 Internal 

Combustion Engine Division Spring 

Technical Meeting, Torino, Italy, May6–

9,2012.  

[10] KeL, Pakkin W, Lapmou T, Hangcheong 
W, Engine idle speed system calibration 

and optimization using aquares support 

vector machine and general algorithem, 

F2008-SC-008. 

[11] Wong P K, Tam L M, Li K, and Vong C 
M, Engine idle-speed system modeling 

and control optimization using artificial 

intelligence, Proc. IMechE Vol. 224 Part 

D: J. Automobile Engineering, 55-72, 

2009. 

DOI: 10.1243/09544070JAUTO1196 

[12] Sharma R, Dennis P, Manzie P, Nesic D 
and Brear M, Real time model predictive 

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engines: experimental results, Preprints 

of the 18th IFAC World Congress Milano 

(Italy) August 28 - September 2, 2011. 

[13] Gharib M R, Moavenian M, A New 
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Speed Condition,  Journal of Basic and 

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6604, 2012. 

[14] Nordin E. Z., Eriksson A. C., Roldin P., 
Nilsson P. T., Carlsson J. E., Kajos M. 

K., Hellen H., Wittbom C., Rissler J., 

L¨ondahl J., Swietlicki E., Svenningsson 

B., Bohgard M., Kulmala M., Hallquist 

M., and Pagels J. H., Secondary organic 


Miqdam T. Chaichan                          Al-Khwarizmi Engineering Journal, Vol. 13, No. 1, P.P. 1- 12(2017) 

 
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aerosol formation from idling gasoline 

passenger vehicle emissions investigated 

in a smog chamber, Atmos. Chem. Phys., 

13, 6101–6116, 2013 

doi:10.5194/acp-13-6101-2013 

[15] Pirs V, Gailis G, Regulated emissions 
from spark ignition engine adapted for 

use of E85 fuel, Engineering for Rural 

Development, Jelgava, 29.-30.05.2014 

[16] Chaichan M T, Practical measurements 
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[17] Chaichan M T, EGR effect on 
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