Performance of the Ethanol Fueled Four-Stroke Engine by using the
Pressured Air Tubes and the Electric Fuel Pumps
Hedy Priyatno
1
, Hary Wibowo
1
, Anak Agung Putu S
1
, Parabelem Tinno Dolf Rompas
2
, Ellyawan
Setyo Arbintarso
1
1
Department of Mechanical Engineering, IST AKPRIND, Yogyakarta, Indonesia
2
Department of Informatic Engineering, Universitas Negeri Manado, Manado, Indonesia
ellyawan@akprind.ac.id
Keywords: Fuel Motor, Ethanol, Pressured Air Tube, Electric Fuel Pump.
Abstract:
This study presents the engine performance resulted from the use of ethanol fuel for a four-stroke
fuel motor with a fuel injection system using pressurized air tubes and an electric fuel pump.
Increase in the number of motorized vehicles has increased fuel consumption. This can increase
gas pollutants that pollute the air. So that it is necessary to convert the use of fuel oil to an
alternative fuel that is environmentally friendly and renewable, one of this is ethanol. Tests are
carried out at 4000 rpm to 7000 rpm at 1000 rpm intervals and data retrieval in the form of
torque, power and fuel consumption. The results have shown that at 4000 rpm to 5000 rpm
engine speed using a pressurized air tube there is a 40% increase in torque from the original 5
N.m to 7 N.m. Engine speed of 5000 rpm to 7000 rpm, torque and power produced using a
pressurized air tube is greater than that of an electric fuel pump. Using pressurized air tubes
increases power and specific fuel consumption (SFC) as engine speed increases
.
1 INTRODUCTION
In Indonesia, lately there are frequent fluctuations in
the supply and price of fuel oil (BBM). Data from
the 2013 oil and gas statistics center PT. Pertamina,
conveyed by the managing director, Indonesia's
crude oil production continued to experience a
fluctuating decline from 1977 to 2014, while
consumption continued to increase. This causes PT.
Pertamina as a state-owned enterprise (BUMN)
engaged in oil and gas production in Indonesia must
import crude oil to meet national fuel needs.
Indonesia's crude oil production is currently 65% of
the total national demand while the remaining 35%
is imported (Hardadi, 2015). This imbalance
between production and consumption will have an
impact on fluctuations in fuel supply and prices in
Indonesia. In the past 4 years, from 2013 to 2016,
there were 8 times changes in fuel prices on the
market. Factors that cause fuel consumption in
Indonesia are significant increase in the number of
motorized vehicles and the lack of use of renewable
energy. While fossil fuels or petroleum are fuels that
are non-renewable, we must start looking for
substitute fuels.
The use of fossil fuels also affects the negative
impacts on the environment that cause global
warming (Kartika and Kristanto, 2013). The issue of
global warming which is a world issue current
encourages several countries to implement go-green
and renewable energy-based technologies in all
industrial sectors, especially the automotive
industry. So to overcome this we have to look for
alternative fuels of many types and abundant and
environmentally friendly, one of which is ethanol.
The use of ethanol as a fuel for gasoline engines
(Otto) has been known since Henry Ford invented
the vehicle in 1896. After the exploration and
exploitation of petroleum began to be carried out by
humans, fuel oil became the main and preferred fuel
for gasoline vehicles (Otto). Although oil fuels
dominate the use of gasoline motors, ethanol has
become an alternative for the following reasons: (1)
Oxygenated Octan Booster as a substitute for
Tertiary Methyl Butyl Ether (MTBE) which is
allegedly having a bad impact on the environment,
Priyatno, H., Wibowo, H., Putu S, A., Rompas, P. and Arbintarso, E.
Performance of the Ethanol Fueled Four-Stroke Engine by using the Pressured Air Tubes and the Electric Fuel Pumps.
DOI: 10.5220/0009006400610066
In Proceedings of the 7th Engineering International Conference on Education, Concept and Application on Green Technology (EIC 2018), pages 61-66
ISBN: 978-989-758-411-4
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
61
(2) decreases exhaust emissions, and (3) reduce
consumption of fuel oil (Setiyawan, 2012).
Global ethanol production for transportation
fuels has tripled in 10 years, from 17 billion litres in
2000 to 86.9 billion litres in 2010, so that the total
production of ethanol can be used as an alternative
energy source to overcome fuel scarcity. The fuel
system is a system that is very important and very
influential on the performance of the motor fuel. On
gasoline fuel and air motorcycles must be able to
mix well before being burned by sparks from spark
plugs. The fuel system has the main function of
storing and distributing fuel and clouding fuel before
it is inserted into the cylinder (Rahmadi, 2012).
The application of the Electronic Fuel Injection
(EFI) system technology is expected to reduce
exhaust emissions, produce maximum power and
increase fuel efficiency (Nugraha, 2007). The engine
used in this study will be applied as a car drive
Kalisahak 28 that is energy-efficient cars fuelled by
ethanol with the concept of city car. This car is used
for energy-efficient vehicle competition where the
vehicle must travel as far as possible by using
energy to a minimum (more distance less energy) in
accordance with the slogan of the Shell Eco Marthon
Asia competition.
2 METHODS
The study process begins with preparations for the
condition of the 4 cylinder fuel motor (Pardede and
Sitorus, 2013; Sulistyo, 2011) that is not single
cylinder which will be tested using ethanol fuel and
pressurized air tube with a fuel injection system
(fuel injection). The test carried out a comparison of
the use of the pressurized air tubes with the electric
fuel pumps in the fuel injection system against the
performance of the engine produced. Engine
performance observed in this test is torque, power,
fuel consumption, and fuel efficiency.
The measurement of torque and power uses a
dynamometer and measurement of fuel consumption
using a measuring burette with a capacity of 25 ml
and a stopwatch as a timer. Retrieval of these data is
carried out at the same time.
The data collection procedures that will be
carried out are as follows:
1. Using a Pressurized Air Tube
a. Raise the motorcycle (Table 1 and Figure 1) over
the dynamometer (Figure 2) and tie it so it
doesn't move forward or backward.
b. Install the engine speed sensor on the coil cable.
c. Refuel the 100 ml transparent tank to the
maximum limit.
d. Install all components of the pressurized air tube
system according to Figure 3 and set the pressure
of the injector tube to 3.2 bar.
e. Adjust the engine speed so that it works at 4000
rpm.
f. Calculate the time for 20 seconds when the
machine is working on a specified rotation.
g. Turn off the engine.
h. Save the test results data that appears on the
Laptop.
i. Filling the fuel to the maximum limit of the tank
with a burette so that the difference in fuel
consumption used for 20 seconds in millilitres is
recognized.
j. After all test data is obtained, and then repeat the
testing procedure for engine speed from 5000 to
7000 rpm with multiples of 1000 rpm.
Figure 1: Flowchart of process study.
2. Using an Electric Fuel Pump
a. Raise the motorcycle (Table 1 and Figure 1) over
the dynamometer (Figure 2) and tie it so it
doesn't move forward or backward.
b. Install the engine speed sensor on the coil cable.
c. Filling in a measuring cup that uses the electric
fuel pump (Figures 4 and 5) with a volume of ±
800 ml until the component of the fuel pump is
submerged.
d. Turn on the engine and adjust the engine speed
to 4000 rpm.
EIC 2018 - The 7th Engineering International Conference (EIC), Engineering International Conference on Education, Concept and
Application on Green Technology
62
e. Calculate the time for 20 seconds when the
machine is working on a specified rotation.
f. Turn off the engine.
g. Save test result data that appears on the monitor
screen.
h. Remove the fuel pump from the measuring cup,
then fill the measuring cup with fuel using a
burette until the initial volume so that the
difference in fuel consumption is used for 20
seconds in millilitres.
i. After all test data is obtained, and then repeat the
testing procedure for engine speed from 5000 to
7000 rpm with multiples of 1000 rpm.
Table 1: Motorcycle engine test specification of Yamaha
Mio J (PT. Yamaha Indonesia Motor Mfg., 2018)
Item Standard
Engine type
4 stroke, 2 Valve SOHC,
single cylinder
Diameter x stroke
54,5 x 57,9 mm
(modification)
Cylinder volume 135 cc
Compression 13 : 1(modification)
Inlet Valve diameter 25 mm
Outlet valve
diameter
21 mm
Fuel system Fuel Injection, Single
Injector Type Indirect Injector, 4 hole
Throttle Body
Single, *Std (Yamaha Mio
Soul GT)
Fuel Injector Sensor *Std (Yamaha Mio J)
Electronic control
unit (ECU)
*Std (Yamaha Mio J)
Ignition system
Transistor Control Ignition
(digital), Busi.
Cooling system Air
Transmission
system
Automatic Sprocket
Starter system
Electric Starter & Kick
Starter
Fuel pump
Electrical Pump, (Yamaha
Mio J).
Testing of the engine performance used the
pressurized air tubes (Figure 3) as a substitute for the
function of the electric fuel pump on the fuel
injection system (Figures 4 and 5). A series of air
tubes made of modified plastic bottles and added
pressure regulator to regulate the pressure to the
injector.
The fuel mass flow rate (Cengel and Boles,
1989) used equation (1) for calculation of the
specific fuel consumption where fuel volume (
) in
millilitre, ρ
(fuel specific weight) in kg/m
3
, and t
(time) in sec.
=
ρ
(1)
s =
(2)
Figure 1: Sample of test (motorcycle of Yamaha
MIO J).
Figure 2: Dynamometer.
Performance of the Ethanol Fueled Four-Stroke Engine by using the Pressured Air Tubes and the Electric Fuel Pumps
63
The specific fuel consumption (Cengel and
Boles, 1989; Moran and Saphiro, 200)) in equation
(2) is calculated for using the pressurized air tubes
and the electric fuel pump respectively where the
power (Ne) in kW.
Figure 3: Components of pressurized air tubes.
Figure 4: Electronic fuel pump system.
Figure 5: Fuel delivery scheme in electronic fuel
pump system.
3 RESULTS AND DISCUSSION
Table 2 shows the effect of engine speed on torque,
power, and fuel consumption by using pressurized
air tubes for 20 seconds. Engine speed up to 5000
rpm, torque increases but after that the torque starts
to decrease and fuel consumption continues to
increase. Whereas power is increasing steadily with
increasing engine speed and fuel consumption.
When after 5000 rpm engine speed, torque begins to
decrease due to the influence of pressurized air tubes
that can reduce fuel when unused (Susilo and
Nugroho, 2012).
Table 2: Effect of engine speed on torque, power and fuel
consumption using pressurized air tubes.
Engine
Speed
(rpm)
Time
(sec)
Electric Fuel Pump
Torque
(Nm)
Power
(kW)
Fuel
Consump
tion
(ml)
Idle 20 0.00 0.00 3.00
4000
20
6.00 2.50 5.50
5000
20
5.95 3.10 9.10
6000
20
6.10 3.85 10.20
7000
20
5.25 4.10 23.50
Table 3: Effect of engine speed on torque, power and fuel
consumption using electric fuel pump.
Engine
Speed
(rpm)
Time
(sec)
Pressurized Air Tube
Torque
(Nm)
Idle
20 0.00 0.00
1.40
4000
20 5.00
2.10 4.30
5000
20 7.00
3.70 8.30
6000
20
6.15
4.00
14.80
7000
20
5.90 4.25 17.90
Table 3 shows the effect of engine speed on
torque, power, and fuel consumption using an
electric fuel pump. At an engine speed of 4000-7000
rpm, torque fluctuates while power and fuel
consumption increase respectively. The torque
fluctuates due to the use of an electric fuel pump that
functions to make fuel more economical, cleaner
exhaust gas, and more perfect combustion of fuel
and air (Hidayat, 2012).
Figure 3 shows a comparison of the specific fuel
consumption between the use of pressurized air
tubes and an electric fuel pump. Specific fuel
consumption increases in the use of pressurized air
tubes, while in the use of electric fuel pumps, it
fluctuates. At engine speeds of up to 5000 rpm and
EIC 2018 - The 7th Engineering International Conference (EIC), Engineering International Conference on Education, Concept and
Application on Green Technology
64
7000 rpm, the use of compressed air tubes is more
economical fuel consumption compared to the use of
electric fuel pumps. That's because the air pressure
given by the use of pressurized air tubes is lower
than the use of electric fuel pumps. In contrast, at
6000 rpm engine speed, the use of electric fuel
pumps is more economical than the use of
pressurized air tubes. That is because the air pressure
provided by the electric fuel pump is lower than the
use of pressurized air tubes. In principle, both uses
function to regulate the fuel entering the combustion
chamber according to the working conditions of the
engine (KMHE, 2016).
Figure 3: Comparison of specific fuel consumption
using pressured air tube and fuel pumps.
Based on the results obtained in Table 2, Table
3, and Figure 3, it can be explained that the
performance of the four stroke motor which uses
pressurized air tubes is more efficient in consuming
ethanol fuel than the use of electric fuel pumps,
especially at 4000 rpm engine speed, 5000 rpm and
7000 rpm.
4 CONCLUSIONS
The performance of the engine produced by using
the pressurized air tubes at engine speed of 4000
rpm to 5000 rpm increase torque of 40% and
decrease at engine speed of 5000 rpm to 7000 rpm.
Increased power and specific fuel consumption
followed by increase engine speed. The use of
electric fuel pumps for engine speed of 4000 rpm is
more powerful than the use of pressurized air tubes.
At engine speed of 5000 rpm to 7000 rpm where
torque and power generated by using the pressure air
tube is greater than that of an electric fuel pump. At
6000 rpm engine speed, the use of electric fuel
pumps is more fuel efficient than pressurized air
tubes. The performance of the 4 stroke fuelled
ethanol engine is better by using the pressurized air
tubes as a whole than by using the electric fuel
pumps.
ACKNOWLEDGEMENTS
The authors wish to thankful to head of engine
laboratory, IstAkprind Yogyakarta who helped in the
studi.
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Application on Green Technology
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