MEV


 

 

Journal of Mechatronics, Electrical Power, and Vehicular Technology 9 (2018) 49–56 

 

Journal of Mechatronics, Electrical Power, 

and Vehicular Technology 
 

e-ISSN: 2088-6985  

p-ISSN: 2087-3379  

 

 

www.mevjournal.com 
 

 

 

doi: https://dx.doi.org/10.14203/j.mev.2018.v9.49-56 

2088-6985 / 2087-3379 ©2018 Research Centre for Electrical Power and Mechatronics - Indonesian Institute of Sciences (RCEPM LIPI).  

This is an open access article under the CC BY-NC-SA license (https://creativecommons.org/licenses/by-nc-sa/4.0/).  

Accreditation Number: (LIPI) 633/AU/P2MI-LIPI/03/2015 and (RISTEKDIKTI) 1/E/KPT/2015. 

Thermal efficiency and emission characteristics  

of a diesel-hydrogen dual fuel CI engine at various loads condition 
 

Yanuandri Putrasari a, b, *, Achmad Praptijanto a, Arifin Nur a, Widodo Budi Santoso a,  

Mulia Pratama a, Ahmad Dimyani a, Suherman a, Bambang Wahono a, b,  

Muhammad Khristamto Aditya Wardana a, b, Ocktaeck Lim c 
a Research Centre for Electrical Power and Mechatronics, Indonesian Institute of Sciences 

Jl. Cisitu No. 154D, Bandung 40135, Indonesia 
 b Graduate School of Mechanical Engineering University of Ulsan 

Mugeo-dong, Nam-gu, Ulsan 44610, South Korea 
c School of Mechanical Engineering University of Ulsan 

Mugeo-dong, Nam-gu, Ulsan 44610, South Korea 

 

Received 25 October 2018; received in revised form 10 December 2018; accepted 12 December 2018 

Published online 30 December 2018 

 

 

Abstract 

Efforts to find alternative fuels and reduce emissions of CI engines have been conducted, one of which is the use of diesel-

hydrogen dual fuel. One of the goals of using hydrogen in dual-fuel combustion systems is to reduce particulate emissions and 

increase engine power. This study investigates the thermal efficiency and emission characteristics of a diesel-hydrogen dual fuel 

CI engine at the various loads condition. The hydrogen was used as a secondary fuel in a single cylinder 667 cm3 diesel engine. 

The hydrogen was supplied to intake manifold by fumigation method, and diesel was injected directly into the combustion 

chamber. The results show that the performance test yielding an increase around 10% for the thermal efficiency value of diesel 

engines with the addition of hydrogen either at 2000 or 2500 rpm. Meanwhile, emission analyses show that the addition of 

hydrogen at 2000 and 2500 rpm lead to the decrease of NOx value up to 43%. Furthermore, the smokeless emissions around 0% 

per kWh were occurred by hydrogen addition at 2000 and 2500 rpm of engine speeds with load operation under 20 Nm. 

©2018 Research Centre for Electrical Power and Mechatronics - Indonesian Institute of Sciences. This is an open access 

article under the CC BY-NC-SA license (https://creativecommons.org/licenses/by-nc-sa/4.0/).  

Keywords: dual-fuel hydrogen; hydrogen engines; diesel-hydrogen; diesel-hydrogen efficiency; diesel-hydrogen emissions. 

 

 

I. Introduction 

The use of alternative fuels in internal combustion 

engine [1][2][3] can reduce dependence on petroleum-

based fuels, where this is a step forward to maintain the 

security and availability of energy sources. In this study, 

hydrogen was used as additional fuel in a conventional 

diesel engine to replace partially diesel fuel that was 

burned in the engine. The engine efficiency and exhaust 

emissions product when hydrogen replaces some 

amount of diesel fuel is the most exciting topic to be 

studied. Previous studies on diesel-hydrogen show that 

the addition of hydrogen is a promising method for 

reducing unwanted exhaust emissions while 

maintaining the engine performance [4][5]. The engine 

operated with the addition of hydrogen may reduce 

NOx over 90% [6], and simultaneously decreases soot 

emission by increasing the hydrogen addition [7][8][9]. 

However, NOx emission increased at higher loads of 

compression ignition engine with hydrogen [10][11]. 

Furthermore, the engine with 17% hydrogen content, 

the hydrogen–diesel–air mixture was stoichiometric 

and provided favorable conditions for generating 

combustion knock [12]. The other study by Calik [13] 

and Syed et al. [14] showed that the addition of 

hydrogen gas further managed the engine vibration 

both with a conventional diesel engine and biodiesel 

blend. 

The autoignition temperature of hydrogen gas is at 

585°C; thus, it requires another autoignition source or 

trigger to burn it in an internal combustion engine. 

Diesel fuel which has autoignition temperature 280°C, 

 

 

* Corresponding Author.  

Tel: +62 821 2013 6976; Fax: + 62 22 250 4773 

E-mail address: yanu001@lipi.go.id; y.putrasari@gmail.com 

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Y. Putrasari et al. / Journal of Mechatronics, Electrical Power, and Vehicular Technology 9 (2018) 49–56 

 

50 

much lower than hydrogen, can be used as a trigger for 

burning hydrogen inside the cylinder of diesel engines 

[15]. This combustion system is also called the "diesel-

hydrogen dual fuel." Diesel with the addition of 

hydrogen provides many advantages both concerning 

performance and emission reduction. This application 

is possible because some of the diesel fuel is replaced 

by hydrogen which has a higher combustion efficiency 

and low hydrocarbon content. 

Many works and studies on diesel-hydrogen have 

been widely reported. The research and development of 

hydrogen engines by Das concluded that hydrogen 

could be used on both gasoline and diesel engines 

without any modification to its systems [16]. In CI 

engines the hydrogen can be used with diesel-hydrogen 

dual fuel model. Therefore, NOx emissions can be 

significantly reduced by monitoring engine conditions 

during operation, for example with a lean combustion 

model or by exhaust gas recirculation (EGR) 

application. 

Adnan et al., have conducted an investigation on a 

single cylinder 406 cm3 direct injection stationary 

diesel engine with the hydrogen addition [17]. In their 

study, the engines were operated at a fixed speed of 

1500 rpm, and hydrogen was injected through the 

intake manifold, while diesel fuel was injected directly 

into the combustion chamber. The engine testing results 

showed an increase in performance up to 16%. 

However, the value of NOx and CO emissions tends to 

increase from 48 to 197 ppm, and 423 to 758 ppm 

respectively. 

Another study on 4-cylinder diesel engines with the 

addition of hydrogen has been carried out by Bari et al. 

[18]. The engine was operated at a constant speed of 

1500 rpm with the addition of hydrogen varying from 

1 to 6%. Meanwhile, an electric generator was 

connected to the engine shaft to manage three 

variations of the load at 19 kW, 22 kW, and 28 kW. The 

test results showed an increase in brake thermal 

efficiency up to 36.3%, fuel savings up to 15.16%, and 

a decrease in HC, CO2, and CO. However, the value of 

NOx emissions continue to rise. 

Miyamoto et al. conducted a study of hydrogen 

addition on a single cylinder diesel engine equipped 

with an EGR system [19]. Diesel fuel was injected into 

the combustion chamber with a common rail fuel 

injection device. The EGR ratio was regulated through 

a valve mechanism, while hydrogen was injected non-

continuously (intermittent) into the inlet air manifold 

using a gas injector.  

The machine was operated at a constant speed of 

1500 rpm. Test results showed that a combination of 

hydrogen addition with slow diesel fuel injection 

contributes to low combustion temperature, resulting in 

a decrease in NOx without raising the remaining 

unburnt fuel. The reduction of smoke due to the 

addition of hydrogen is more significant than without 

hydrogen for the high EGR ratio and slow diesel fuel 

injection time. 

Previous references have discussed the application 

of hydrogen on diesel engine comprehensively. 

However, the engine efficiency and emissions in CI 

engine are very dependent on many factors such as 

energy input, fuel management strategy, combustion 

mode, initial conditions, and variation of loads. 

Furthermore, the effects of various loads including the 

high and low load on the thermal efficiency and 

emissions of CI engine fueled with diesel-hydrogen 

dual fuel have not been explored and discussed in depth 

and complete. Therefore, this paper aims to discuss the 

characterization of diesel-hydrogen dual fuel 

performance and exhaust emissions at 2000 and 2500 

rpm against loading variations, as a new solution to 

overcome the lack information on the effect of various 

loads on diesel-hydrogen dual fuel. The thermal engine 

efficiency, NOx and smoke emissions are the main 

topics presented in this paper. The information 

presented in this paper will be beneficial for researchers, 

academics and practitioners who will utilize hydrogen 

for dual-fuel applications on conventional diesel 

engines with minimum modification. 

II. Materials and methods 

A. Engine testing preparation 

The experiment was conducted by using an engine 

test bed composed of a single cylinder diesel engine 

coupled with an eddy-current dynamometer, the fuel 

balance measurement, NOx meter, smoke meter, and 

pressure and temperature sensors. The eddy current 

dynamometer was used to adjust and measure engine 

speed and loads. Meanwhile, fuel consumption was 

measured by using the fuel balance measurement 

system, and the intake air flow was measured with a 

hotwire anemometer. The combination of a pressure 

transducer, crank-angle sensor, and a data acquisition 

system was used to obtain the data inside of engine 

cylinder during the experiment. The engine 

specifications are shown in Table 1, and the engine 

testing arrangement can be seen in Figure 1.  

B. Testing procedure 

The engine tests were carried out with two engine 

speeds, namely 2000 and 2500 rpm fueled with pure 

diesel and compared with diesel mixed with hydrogen 

addition. Engine loading was varied from 0, 5, 10, 20, 

and 25 Nm. The characteristics of pure diesel and 

hydrogen refer to Bari and Mohammad [18] is shown 

in Table 2.  

Hydrogen was inserted into the combustion 

chamber by the fumigation method using a small tube 

directly into the inlet manifold with a distance of 50 cm 

Table 1. 

Engine specifications 

Parameters Units 

Engine type Naturally aspirated, DI-CI, 4 

stroke, 2 valves  

Number of cylinder / 

configuration 

1 / Vertical 

Displacement volume  667 cm3 

Bore x stroke 100 mm × 85 mm 

Compression ratio 20 : 1 

Maximum torque 28 Nm at 2000 rpm 

Maximum power 11 kW at 3000 rpm 
 



 Y. Putrasari et al. / Journal of Mechatronics, Electrical Power, and Vehicular Technology 9 (2018) 49–56 51 

from the base of the intake manifold. The hydrogen was 

set at a constant flow around 10 litres/minute with a 

pressure of 0.5 bar. Furthermore, some parameters in 

each condition including Indicated mean effective 

pressure (IMEP), fuel consumption, air flow rate, oil 

temperature, exhaust gas temperature, NOx and smoke 

emission values were measured. 

III. Results and discussions 

A. Improvement of thermal efficiency 

Thermal efficiency states the ratio between the 

powers produced to the amount of fuel needed for a 

certain period of engine operation. It is one of the 

factors to analyze the performance of the internal 

combustion engine. Although this paper also focuses on 

the discussion of engine emissions, in this case, it is 

worth mentioning a brief effect of hydrogen addition to 

thermal efficiency closely related to fuel consumption. 

Figures 2 and Figure 3 show the thermal efficiency 

(brake thermal efficiency, BTE) of the CI engine based 

on the loads variation at 2000, and 2500 rpm, refer to 

the diesel consumption only. The occurred thermal 

efficiency patterns for both 2000 and 2500 rpm shows 

similarities. At 2000 rpm the addition of hydrogen 

causes an increase in thermal efficiency at every load 

variation as well as at 2500 rpm. This condition 

happens because a portion of diesel fuel is replaced by 

 

Figure 1. Engine testing diagram 

 

Table 2. 

Characteristics of diesel and hydrogen 

Parameters Unit Diesel  Hydrogen 

Density kg/m3 840 0.082 

Caloric value MJ/kg 42.7 119.81 

Ignition speed m/s 0.3 2.70 

Autoignition temperature °C 280 585 

Carbon residue % 0.1 0.00 

 



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52 

hydrogen which has a high ignition speed (around 3.24 

to 4.40 ms-1). Thus, the hydrogen causes the 

combustion process in the engine combustion chamber 

occurred very rapidly. However, the exact amount of 

the consumed hydrogen cannot be measured. The 

amount of consumed hydrogen can be predicted only 

by the discrepancies of thermal efficiency between 

engine fueled with pure diesel fuel and hydrogen added 

diesel.  

The higher speed of the combustion process will 

produce greater combustion energy that can improve 

the performance of the diesel engine. Referring to the 

results of Adnan [17], the addition of certain amount of 

hydrogen, in the form of gas fuel, to a diesel engine 

mixed with air gives a significant impact on the 

cylinder load during compression and power during a 

combustion explosion. 

B. NOx reduction 

Figure 4 and Figure 5 show NOx emissions against 

loads variation of the CI engines at 2000 and 2500 rpm. 

Both charts show the same pattern, where at low load, 

NOx values are decreases in diesel with the addition of 

hydrogen. At 2000 rpm of engine speed, NOx values are 

decreases with the loads variation from 0, 5, 10, 15, and 

20 Nm by 16%, 33%, 39%, 37%, and 22%, respectively. 

Meanwhile, in the load value around 25 Nm, it tends to 

have no effect of decreasing on NOx value of the diesel 

engine with the addition of hydrogen.  

At engine speed around 2500 rpm, the NOx 

reduction pattern still occurs at the variation of the load 

from 0, 5, 10, 15, and 20 Nm by 35%, 40%, 44%, 35%, 

and 27%, respectively. Also, for 2500 rpm, at an engine 

load around 25 Nm, the increase in NOx value occurs 

by 7%. This NOx reduction pattern is happened because 

at low loads there is an increase in the hydrogen fuel 

fraction. Therefore, the NOx reduce significantly. This 

condition in line with the results of the research 

conducted by Miyamoto [19]. 

C. Smoke emissions reduction 

The various values of smoke density for emissions 

test are shown in Figures 6 and Figure 7. Figure 6 

shows smoke history on the loads variation of diesel 

 

Figure 2. Engine thermal efficiency at 2000 rpm 

 

 

Figure 3. Engine thermal efficiency at 2500 rpm 

 



 Y. Putrasari et al. / Journal of Mechatronics, Electrical Power, and Vehicular Technology 9 (2018) 49–56 53 

and diesel engines with hydrogen at 2000 rpm and 

Figure 7 is at 2500 rpm. By analyzing the two images, 

it can be observed that diesel-hydrogen dual fuel 

operation is a very potent strategy to reduce the massive 

smoke emissions of CI engines.  

For diesel-hydrogen dual fuel operations with 

engine speed around 2000 and 2500 rpm, it can be 

revealed that the smoke emissions are reduced up to 0% 

and even minus at a low load from 20 Nm downwards. 

In other words, diesel-hydrogen dual fuel operations 

produce smokeless combustion. Meanwhile, at engine 

load. Meanwhile, at engine load around 25 Nm, both 

for engine speed around 2000 and 2500 rpm, smoke 

emissions began to appear. The decrease in smoke 

 

Figure 4. NOx at 2000 rpm 

 

 

Figure 5. NOx at 2500 rpm 

 

 

Figure 6. Smoke at 2000 rpm 



Y. Putrasari et al. / Journal of Mechatronics, Electrical Power, and Vehicular Technology 9 (2018) 49–56 

 

54 

value was happened because of the partial replacement 

of diesel fuel by hydrogen inside the combustion 

process. 

Based on Table 2, it is known that hydrogen 

addition in the combustion produces the main 

combustion residue in the form of water vapor only, 

and does not form any particulates. This is due to the 

absence of carbon atoms in hydrogen resulting in a low 

smoke percentage [15]. 

IV. Conclusion 

The performance and emissions tests on 667 cm3, 

single cylinder diesel engines have been carried out 

without or with the addition of hydrogen. Addition of 

hydrogen is carried out by inserting it through the 

intake manifold. From the performance test, it is 

obtained an increase in the value of thermal efficiency 

by adding hydrogen. Meanwhile, from emission tests 

with the addition of hydrogen at engine speed around 

2000 and 2500 rpm, the NOx value decreases from 16 

to 43% in low load condition. Furthermore, the smoke 

emissions content is very clean or smokeless at 2000 

and 2500 rpm with low load condition by a 0% of 

smoke value. This experimental work and extensive 

investigation show some valuable insight and new 

ideas. However, it is necessary to conduct a further 

study such as the application of various injection timing 

of diesel fuel to optimize the efficiency and emissions 

characteristics of the CI engine operated in dual-fueled 

with diesel-hydrogen. 

Acknowledgment 

This research was supported by The Research 

Centre for Electrical Power and Mechatronics-

Indonesian Institute of Sciences (LIPI) in collaboration 

with Smart Powertrain Laboratory-University of Ulsan, 

South Korea. Yanuandri Putrasari acknowledges 

support from the Program for Research and Innovation 

in Science and Technology (RISET-Pro) Ref. No: 

61/RISET-Pro/FGS/III/2017, Indonesian Ministry of 

Research, Technology and Higher Education. 

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