MEV


 

 

J. Mechatron. Electr. Power Veh. Technol 07 (2016) 87-92 
 

Journal of Mechatronics, Electrical Power, 
and Vehicular Technology 

 
e-ISSN:2088-6985 
p-ISSN: 2087-3379 

 

 

 

www.mevjournal.com 
 

© 2016 RCEPM - LIPI All rights reserved. Open access under CC BY-NC-SA license. doi: 10.14203/j.mev.2016.v7.87-92. 
Accreditation Number: (LIPI) 633/AU/P2MI-LIPI/03/2015 and (Ministry of RTHE) 1/E/KPT/2015. 

FUEL CONSUMPTION AND CO2 EMISSION INVESTIGATION  
OF RANGE EXTENDER WITH DIESEL AND GASOLINE ENGINE 

 
Bambang Wahono a, b,*, Arifin Nur b, Achmad Praptijanto b, Widodo Budi Santoso b, 

Suherman b, Zong Lu c 
a Graduate School of Mechanical Engineering, University of Ulsan 

Ulsan, San 29, Mugeo2-dong, Nam-gu, Ulsan, 44610, Republic of Korea  
b Research Centre for Electrical Power and Mechatronics, Indonesian Institute of Sciences,  

Komplek LIPI, Jl. Sangkuriang, Gd. 20. Lt. 2, Bandung 40135, Indonesia 
c Brother Industries, Ltd. 

15-1 Naeshiro-cho, Mizuho-ku, Nagoya, 467-8561, Japan 
 

Received 11 October 2016; received in revised form 7 November 2016; accepted 8 November 2016 
Published online 23 December 2016 

 

Abstract 
Range extender engine is one of the main components of the range-extended electric vehicle (REEV) and 

together with a generator to extend the mileage of the electric vehicle. The main component of REEV is an electric 
motor, battery, and generator set that consist of generator and engine. In this study, we compared two models of 
REEV performance with two different types of the engine by simulation. Single cylinder 499 cc gasoline engine and 
single cylinder 667 cc diesel engine are chosen as the object of this research especially relating to the utilization of 
the fuel consumption and CO2 emissions when fitted to an electric vehicle. The simulation was conducted by using 
AVL Cruise software and performed by entering the data, both experiment and simulation data, on all the main 
components of REEV. This simulation was performed in Japan 08 driving cycle. Based on the simulation, fuel 
consumption is reduced up to 35.59% for REEV with single cylinder diesel engine 667 cc compared to REEV with 
single cylinder gasoline engine 499 cc. The reduction of CO2 emissions from REEV with single cylinder 499 cc 
gasoline engine compared to REEV with single cylinder 667 cc diesel engine up to 30.47%. 

 
Keywords: range extender engine; performance; diesel; gasoline; AVL Cruise. 

 
I. INTRODUCTION 

Energy efficiency and emission are the most 
important aspects in the development of vehicle 
technology. In many types of research related to 
the energy and vehicle, many researchers give 
more attention to these aspects. Some countries 
have done a large number of studies with these 
focuses such as China [1, 2], US [3, 4], Portugal 
[5], UK [6], India [7] and etc. They do this type 
of research because of its great effects. The 
vehicle emission affects the air quality, health, 
and climate in the world [8]. On the other hand, 
based on the WHO research, the emission of the 
vehicle is responsible for the death of people 
accounted up to seven million per year [9]. With 
respect to energy efficiency, transportation has 
become the largest sector which needs fuel 

approximately 90% of the total energy 
consumption needed [10]. On the other hand, oil 
resources have been rapidly running out and 
expected to be completely depleted within 50 
years [11]. 

Based on this situation, researchers in the 
world are required to conduct research that is 
able to reduce fuel consumption and decrease 
vehicle emissions. One of the latest technologies 
that have been developed is the electric car. But 
an electric car has some disadvantages such as 
limited mileage and expensive batteries. To solve 
this problem, a range extender technology has 
been developed. The range extender is a 
technology that uses a small engine installed in a 
series configuration with a generator in the 
electric car. The car is called the range-extended 
electric vehicle (REEV). Although this 
technology still has emission, but the number is * Corresponding Author.Tel: +6222-2503055 E-mail: bambangwahono80@yahoo.co.id, bamb053@lipi.go.id 

http://dx.doi.org/10.14203/j.mev.2016.v7.87-92


B. Wahono et al. / J. Mechatron. Electr. Power Veh. Technol 07 (2016) 87-92 
 

 

88 

relatively low because it works only when 
needed to charge the batteries. The main drive of 
REEV is the battery. The range extender is 
mounted in a car to increase the mileage of 
electric cars. 

Similar researches have been conducted by 
researchers from several vehicles companies and 
research institutes such as AVL that develop a 
range extender with 2-cylinder engine with a 
power of 15 kW. This engine has a compact size 
but its emission is still high, and furthermore, the 
maintenance cost is also high [12]. The other 
researcher also developed a range extender from 
the fuel cell. The advantages of this range 
extender engine are able to produce lower noise, 
vibration, and emissions. The disadvantage of 
this range extender engine is high production cost 
[13]. 

This paper is focused on the investigation of 
range extender engine with 1 cylinder gasoline 
engine 499 cc and 1 cylinder diesel engine 667 cc, 
especially relating to the utilization of the fuel 
consumption and CO2 emissions by using a 
simulation system of the vehicle. The goal of this 
research is to understand the comparison of the 
performance and CO2 emission of the range 
extender engine by two types of engine on 
minimal engine capacity. This study is the 
continuation of the previous research that has 
been published previously [14]. In the previous 
research, some of the gasoline engines were 
compared to get the best performance and 
emission of the range extender engine. Based on 
this research, the performance and CO2 emission 
of the engine will be well understood and the 
result can be used as a reference to build the real 
engine and optimization of the energy balance 
that can be applied in an electric vehicle 
especially in the electric vehicle developed in 
LIPI. 

 
II. SIMULATION OF RANGE-

EXTENDED ELECTRIC VEHICLE 
In this study, range-extended electric vehicle 

(REEV) was chosen as the model. The 
components were all the same, it was only the 
engine that makes the difference in the two 
models. In this simulation, two engine models are 
used, i.e. the single cylinder 499 cc gasoline 
engine was compared against the single cylinder 
667 cc diesel engine. The vehicle system 
simulation was performed by AVL Cruise and 
Japan 08 driving cycle was chosen as road 
condition characteristic. The details of electric 
vehicle size and specification of motor generator 
component are shown in Table 1 and Table 2. 

The engine parameters used to investigate as 
the object on REEV modelling by AVL Cruise 
are shown on Table 3. The basic configuration of 
range extended electric vehicle (REEV) is shown 
in Figure 1. Range extended electric vehicle have 

 

Table 1. 
Basic Parameter of electric vehicle 

Parameter Range Extended 
Electric Vehicle 

Fuel Diesel, Gasoline 
Frontal area 1.97 (m2) 
Dynamic rolling radius 301 (mm) 
Final drive transmission ratio 4.266 
Battery model WB-LYP200AHA 

 
Table 2. 
Motor generator specification 

Type  GKN AF-130 
Max speed 8,000 rpm 
Nominal torque  170 Nm 
Peak torque @20 s 400 Nm 
Nominal output power 80 kW 
Peak output power @20 s 150 kW 
Peak efficiency 95.10% 
Dimension (L x D)  110 x 300 mm 
Weight 30.5 kg 

 
Table 3. 
Engine specification 

Type  Gasoline 
499 cc 

Diesel 
667 cc * 

Model - Hatz 1D81 
Cylinder/valve 1/4 DOHC 1/2 OHC 
Bore x stroke (mm)  86 x 86 100 x 80 
Max torque (Nm/rpm) 27.3/3,500  32.6/2500  
Max power (kW/rpm) 10.54/4,000 10.21/3000 
Maximum speed (rpm) 6,000 3,600 
Stroke 4 4 
Inertia moment 0.35 0.51 
Fuel system EFI DI 
Fuel Gasoline Diesel 
Heating value (kJ/kg) 43,500 43,100 
*Based on experiment 

 

 
Figure 1. REEV drive train configuration 



B. Wahono et al. / J. Mechatron. Electr. Power Veh. Technol 07 (2016) 87-92 
 

 

89 

some main components i.e. range extender that 
consists engine and generator in a series 
configuration, battery, and electric motor. In this 
study, we used two models of engine to 
investigate the performance of REEV i.e. a single 
cylinder 499 cc gasoline engine with maximum 
power 10.54 kW and a single cylinder 667 cc 
direct injection diesel engine with maximum 
power 10.21 kW. The model of the generator is 
AF 130 synchronous-axial flux with a maximum 
speed of 8,000 rpm and nominal output power is 
80 kW [15]. The series configuration was chosen 
to minimize engine power capacity when the 
battery capacity drops to 30% of its capacity, the 
combustion engine starts the on mode to supply 
the battery by rotating the AF 130 generator. On 
this phase, the HPEVS AC 20 electric motor is 
powered by the battery that is charged by the AF 
130 generator. The generator itself, in turn, was 
pulled by the combustion engine that is managed 
by the battery management system (BMS). The 
model of the battery was LiFeYPO4 type lithium-
ion batteries with 200 Ah/3.2 V, arranged in a 
series configuration consist of 30 unit of batteries 

[16]. The model of the electric motor is HPEVS 
AC-20 96 V 650 A, AC induction motor with a 
Curtis controller [17]. The weight values of two 
models vehicle are given in Table 4. 

In this research, the model of REEV was built 
in the AVL Cruise vehicle simulation. The model 
of REEV is shown in Figure 2. All data from the 
main components of REEV and others data for 
the vehicle were input to the AVL Cruise. In this 
study, the Japan 08 driving cycle was used to 
represent the driving condition congested with 
city traffic, idling periods, frequently alternating 
acceleration and deceleration. Japan 08 driving 
cycle was chosen due to stop and go road 
condition. This Japan 08 driving cycle has been 
frequently used for emission measurement and 
fuel economy determination, both of gasoline or 
diesel vehicles. The mode of this driving cycle is 
shown in Figure 3. 

In this research, two types of engine were 
modelled to determine the performance of the 
best model of range-extended electric vehicle. 
Maps of the engine performance came from the 
data that were collected through the experiment 
at various speeds in an internal combustion 
engine laboratory at LIPI and the simulation by Table 4. Weight for each component 

Parameter 

REEV with 1 
cylinder 
gasoline engine 
499 cc 

REEV with 1 
cylinder 
diesel engine 
667 cc 

Curb weight (kg) 873.0 873.0 
Engine weight (kg) 53.0 105.0 
Electric machine weight (kg) 27.2 27.2 
Battery weight (kg) 237.0 237.0 
Generator weight (kg) 30.5 30.5 
Load (kg) 263.0 263.0 
Gross weight 1,483.7 1,535.7 
 

 
 

Figure 2. REEV model in AVL Cruise 

 

 
Figure 3. Japan 08 driving cycle 



B. Wahono et al. / J. Mechatron. Electr. Power Veh. Technol 07 (2016) 87-92 
 

 

90 

using AVL Boost to get the maximum torque, 
brake specific fuel consumption (BSFC) maps 
and motoring torque at full or partial throttle in 
each engine. Table 3 shows the specifications of 
each internal combustion engine. The full load 
torque output of each internal combustion engine 
was input into AVL Cruise, as shown in Figure 4. 

 
III. RESULT AND DISCUSSION 

In this simulation, it was assumed that the 
energy stored in the battery when the vehicle 
started to run was 90% of SOC as an initial 
charge and the vehicle would not run until the 
battery capacity was down to 30%. Range 
extender engine was used as one of the main 
components of REEV with the engine speed of 
3000 rpm both in diesel engine and gasoline 
engine. The term of the range extender is used in 
order to describe that the engine is used to extend 
the operational range of the electric vehicle until 
the EV find the nearest EV charging point. 

The engine used as the range extender will be 
off as long as there is enough energy in the 
batteries and will be activated when the total 
batteries capacity which is called as the state of 
charge (SOC) drops to 35%. The range extender 
system will still be active until the batteries are 
charged up to 48% SOC. The simulation results 
based on Japan 08 driving cycle of the REEV 
vehicle conducted with road range, fuel 
consumption and emissions of the two systems 
are shown in Table 5. Since the REEV is 
configured on a series system that means the 
engine is only propulsing the generator to 
generate the electricity for charging the batteries, 
then the batteries supply the energy to the electric 
motor, therefore it can be concluded that the 
engine should have enough energy to rotate the 
generator on it maximum rotation. The engine 
will only work when the SOC value dropped to 
35%. On Figure 5, it can be seen that the single 
cylinder 499 gasoline engine is running harder to 
rotate the generator for charging the batteries. As 
the effect, the gasoline engine is always on and 

automatically increases the fuel consumption. 
The fuel consumption of REEV with a single 
cylinder gasoline engine 499 cc is 3.54 L/100 km, 
while the REEV with single cylinder diesel 
engine 667 cc is 2.28 L/100 km. This is because 
the REEV with a single cylinder diesel engine 
667 cc have enough power to propulse the 
generator which charges the batteries that is 
controlled by battery management system (BMS).  

The diesel engine is working only when 
needed while the gasoline engine is running 
continuously to charge the batteries. After the 
engine is activated, the generator works and 
transmits the energy to the batteries. An REEV 
with a single cylinder diesel engine 667 cc is fast 
to increase the battery capacity up to 48%, so 
automatically the vehicle is powered by the 
batteries. The mode is repeated. This is different 
if compared with the REEV with a single 
cylinder gasoline engine 499 cc. In this 
condition, the REEV with a single cylinder 
gasoline engine 499 cc was unable to increase the 
SOC, due to lack of power to rotate the 
generator. Although the maximum power output 
of 499 cc gasoline engine is higher than 677 cc 
diesel engine but by modelling it shows that the 
continuous output power of the REEV with a 
single cylinder diesel engine 667 cc is higher 
than REEV with single cylinder gasoline engine 
499 cc. 

The continuous power output of the engine 
single cylinder diesel 667 cc that can be 
transmitted to rotate the generator up to 10.04 
kW while the continuous power output of the 
range extender engine with a single cylinder 
gasoline engine 499 cc is 8.22 kW. This happens 
due to the lower torque generated by the gasoline 
(27.3 Nm/3,500 rpm) engine, while the torque of 
the diesel engine is 32.5 Nm/3,000 rpm (max 
32.6 Nm/2,500 rpm). As the effect, the range 
extender engine with a single cylinder diesel 667 
cc is easier to increase the SOC value of  the 
batteries. This condition has a relation with the 
CO2 emission of range extender engine. The 
difference of the fuel consumption of each 
vehicle model also affects the CO2 emissions 
produced. It can be seen in Table 3 that CO2 

 
 

Figure 4. Full load torque output of engine 

 

Table 5. 
Performance of two vehicle model in Japan 08 driving cycle 

Parameter 

REEV with 1 
cylinder 
gasoline engine 
499 cc 

REEV with 1 
cylinder 
diesel engine 
667 cc 

Model - Hatz 1D81 
Fuel consumption of 
engine (L/100 km) 3.54 2.28 

CO2 (g/km) 86.11 59.88 
 



B. Wahono et al. / J. Mechatron. Electr. Power Veh. Technol 07 (2016) 87-92 
 

 

91 

emission of the RE with a single cylinder diesel 
667 cc is lower than the RE with a single cylinder 
gasoline 499 cc. In addition, the increasing of 
CO2 emissions of the RE with a single cylinder 
gasoline 499 cc is also caused by the prolonged 
use of a range extender engine when the batteries 
capacity is down to its limit. 

To increase the value of SOC from 35% to 
48% of batteries capacity requires operation up to 
30 minutes for a single cylinder diesel engine, 
while the RE with a single cylinder gasoline 499 
cc operates continuously until the fuel is 
depleted. As the effect, CO2 emission of the RE 
with a single cylinder gasoline 499 cc is 30.47% 
higher than the RE with a single cylinder diesel 
667 cc. The operating condition of each range 
extender engine is shown in Figure 5. Figure 6 
and Figure 7 show the characteristics of the range 

extender engine operation mode related to battery 
SOC curve versus operational range (distance). 
In addition, these two figures also show the 
engine output power versus operational range 
(distance). For the RE with the diesel engine that 
is shown in Figure 6, the generator set was 
operated temporarily to charge the battery, when 
the battery capacity was enough to power the 
electric motor then the generator set will be shut 
off. In addition for Figure 6, it can be observed 
that the minimum power that should be supplied 
to the vehicle to follow the road characteristic 
based on the Japan 08 driving cycle is about 
10.04 kW. While Figure 7 shows the minimum 
power that should be supplied to the vehicle to 
follow the operational characteristic based on the 
Japan 08 driving cycle is about 8.22 kW. It is 
shown by the flatted dash line when the SOC 
falls to 35%. When this event occurred, it means 
the operational range of the electric vehicle 
becomes unlimited depend on diesel or gasoline 
fuels. This condition induces the generator set 
working as a range extender on the electric 
vehicle as known as REEV. Since the generator 
works in optimum conditions, the advantages of 
the range extender engine on the electric vehicle 
can be achieved. 

Based on this simulation, the REEV model 
with the RE single cylinder diesel engine 667 cc 
gave the best performance on fuel consumption 
and CO2 emission for range extender application. 

 
IV. CONCLUSION 

The simulation model of range-extended 
electric vehicle (REEV) was built using AVL 
Cruise software piloting a Japan 08 driving cycle. 
The diesel engine is better than gasoline engine if 
applied as a component of the range extender if 
the optimum rotation of generator is relatively 
low. The major factor that influences the engine 
ability to increase the battery capacity is torque 
rather than power at same optimum rotation for 
the generator. Based on the weight of the engine 
simulation and inertia moment of the engine, we 
found that there is not much effect the 
operational range of the REEV. Based on the 
simulation, the range-extender electric vehicle 
with a single cylinder diesel 667 cc appeared as 
the best choice when running on Japan 08 driving 
cycles. The performance characteristics of range 
extended electric vehicles can be predicted for 
further system development. A comprehensive 
study for building a better understanding of range 
extender systems for an electric vehicle is 
necessary to understand the compatibility of each 
component and characteristic of the range-
extender electric vehicle. 

 
Figure 5. SOC of two vehicle model simulated over Japan 08 
driving cycle 

 
Figure 6. SOC, engine speed, and engine power in REEV 1 
cylinder 667 cc simulated over Japan 08 driving cycle 

 
Figure 7. SOC, engine speed, and engine power in REEV 1 
cylinder 499 cc simulated over the Japan 08 driving cycle 



B. Wahono et al. / J. Mechatron. Electr. Power Veh. Technol 07 (2016) 87-92 
 

 

92 

ACKNOWLEDGEMENT 
This research is supported by Competitive 

Research Grant 2015, provided by Indonesian 
Institute of Sciences. The author would like to 
thank all member of Internal Combustion Engine 
Laboratory, Indonesian Institute of Sciences for 
their assistance in collecting data in internal 
combustion engine experiment. 

 
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	I. Introduction
	Simulation of Range-Extended Electric Vehicle
	III. Result and Discussion
	IV. Conclusion
	Acknowledgement
	References