Journal of Mechanical Engineering Science and Technology ISSN 2580-0817 

Vol. 7, No. 1, July 2023, pp. 87-95  87 

                 DOI: 10.17977/um016v7i12023p087 

Effect of Temperature Variations of Corn (Maize) Oil Biodiesel on Torque 

Values and Thermal Efficiency of Diesel Engines 

Suardi*, Rodlian Jamal Ikhwani, Ade Putri Rezki Aulia  

Department of Naval Architecture, Kalimantan Institute of Technology, Balikpapan, 76127, Indonesia  

*Corresponding author:suardi@lecturer.itk.ac.id 

Article history: 

Received: 19 Pebruary 2023 / Received in revised form: 5 May 2023 / Accepted: 7 June 2023  

Available online 28 June 2023 

ABSTRACT  

The trend of consumption of hydrocarbon fuels in Indonesia, which is increasing every year, is not 

accompanied by the amount of production, which is decreasing. Alternative fuels to reduce dependence on 

hydrocarbon fuels. One form of alternative fuel is biodiesel, which is made from corn (maize) oil. Corn oil 

itself, if processed, can be an option for clean and environmentally friendly energy option and that is the 

main objective of this research is to determine the performance of biodiesel corn oil on diesel engines. The 

method used in this study is an experimental method where corn oil biodiesel is tested directly on a testing 

machine. The data from the test results will be used to find the torque and thermal efficiency values so that 

the engine performance values for each fuel variation can be identified. The results of the study obtained the 

engine performance value, namely the highest torque was on diesel oil fuel 4.57 N.m. The highest thermal 

efficiency value achieved at the B30 fuel sample at a temperature of 60 °C with the thermal efficiency of 

17.4%. With these results, it can be concluded that engine performance with corn oil fuel can be used as an 

alternative fuel to replace hydrocarbon fuel. 

Copyright © 2023. Journal of Mechanical Engineering Science and Technology. 

Keywords: Biodiesel, corn (maize) oil, temperature, thermal efficiency, torque value  

I.  Introduction

Indonesia ranks 14th as a country with the level of consumption of fossil fuels in the 

world, with a total consumption of 1,470,000 barrels per day, while Indonesia's total oil 

production is 692,000 barrels per day [1]. According to a source from the Minister of Energy 

and Mineral Resources of Indonesia, Indonesia's oil reserves will only last for the next 9.5 

years [2]. This has prompted the government to encourage research on environmentally 

friendly fuels such as biodiesel. Biodiesel is an environmentally friendly fuel source that can 

be an alternative to fossil fuels [3]. As a country with a tropical climate, Indonesia makes its 

soil fertile for various kinds of plants, one of which is corn, which can be processed into corn 

oil biodiesel. Indonesia's corn production data for 2020 reaches 22,500,000 tons [4], while 

the total world corn oil production is 3,189,137 tons, and Indonesia is capable of producing 

around 7,417 tons [5]. 

Various kinds of research related to biodiesel have been carried out, some of which is 

the production of biodiesel from waste cocking oil (WCO), whose research results state that 

the use of WCO biodiesel does not harm engine performance [6]. Studies of the potential of 

algae [7] and the potential of animal oil to become biodiesel indicate that animal oil with a 

mixture of up to B60 can provide a good thermal efficiency value for the engine as well as 



88   Journal of Mechanical Engineering Science and Technology                       ISSN 2580-0817 

                                               Vol. 7, No. 1, July 2023, pp. 87-95 

Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

a low emission value compared to fossil fuels [8]. Biodiesel production from pome (palm 

oil milf effluent) results good engine performance values compared to diesel fuel [9]. The 

research that uses corn oil (maize) also gives good performance values for diesel engines 

[10]. Research states that one tonne of corn kernels contains as much as 0.5 to 0.6 sugar, 

which can be converted into bioethanol, a clean raw material for biodiesel production [11]. 

All of these studies show that biodiesel can be used as an alternative fuel that is 

environmentally friendly, renewable, low in emissions, and able to answer concerns about 

the oil crisis that is already in sight. 

The viscosity of biodiesel fuel is its primary characteristic worth emphasizing. A study 

shows that the viscosity of biodiesel is higher than that of diesel fuel. The viscosity of diesel 

fuel is in the range of 2.5 – 3.2 cSt at 40 °C, while biodiesel is 1.3 – 6 cSt [12]. Another 

study states that the viscosity value of biodiesel, especially Palm Oil Mill Effluent (POME), 

is 4.98 cSt higher than the viscosity of diesel fuel, namely 1.8 – 4.1 cSt, which affects the 

value of engine performance [13]. The more biodiesel added to diesel fuel will also increase 

the viscosity of the fuel. The high viscosity makes the fuel transfer pump work harder, and 

the fuel pick-up process will not be perfect. To make the engine not work harder, the fuel 

viscosity must remain within the ASTM standards D445 [14]. The viscosity of biodiesel can 

be reduced by increasing the temperature of the fuel [14] so that biodiesel safe to apply to 

the engine. 

In terms of engine performance, biodiesel can provide good performance, but that does 

not mean that biodiesel is a perfect and flawless fuel. In a study that tested the effect of using 

biodiesel on diesel engines used in fishing boats, the torque and power generated by engines 

with biodiesel fuel (B30) are slightly lower when compared to diesel fuel. In addition, the 

use of B30 makes the properties of changing engine lubricating oil. The results of the study 

stated that iron and aluminum metal content was found in the lubricating oil at 0.7% and 

19.8%, respectively. Chromium content was also found in the same sample. It also found 

cases of loosened piston rings and journal bearings experiencing wear [15]. The International 

Maritime Organization (IMO), an agency under the auspices of the United Nations, has set 

a target of reducing world carbon emissions by 40% in 2030 and 70% in 2050 [16]. By 

looking at the facts about the urgent need for new energy to replace hydrocarbon fuels and 

efforts to make the environment cleaner from bad pollution, the main purpose of this research 

is to test the performance of biodiesel corn oil directly on diesel engines. 

II. Material and Methods 

The method used in this research is an experimental method of testing fuel samples 

directly on the engine. Similar research has also been carried out by converting waste 

cooking oil (WCO) into biodiesel, the results of which also provide good performance value 

for the engine, especially in terms of saving fuel consumption by around 45% [17]. Corn oil 

samples were prepared in three variations with turpentine oil, namely 30%, 50%, and 70%. 

The results obtained were that at full load, corn oil was able to provide a greater thermal 

efficiency value of 15% compared to using 100% hydrocarbon fuel [18]. The fuel samples 

used were pure diesel, B30 with a temperature variation of 50 °C, and B30 with a temperature 

variation of 60 °C. After the density and viscosity values of the fuel are known, then proceed 

to the next stage, namely testing on a test machine. B30 fuel with two temperature variations 

was tested on diesel engines. The data taken during engine testing includes voltage, current, 

fuel consumption, and time of fuel consumption. 

The specifications of the diesel engines used in this study can be seen in Table 1. 



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Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

Table 1. The specifications of engine [9],[10]. 

Engine Model Yanmar TF 75/85 Series 

Type of Engine 

No of Cylinder 

Displacement 

Continuous Power 

Compression Ratio 

Specific Fuel Consumption (SFC) 

Volume per injection 

TF 85MH 

1 Cylinder 4 Stroke 

493 cc 

7.5 Kw/2200 rpm 

1:18 

171 gr/HP h 

0.07 mL 

 

Engine tests were carried out on direct diesel engines with engine specifications 

according to Table 1 with variations of pure diesel fuel (without biodiesel mixture), B30 

with a temperature variation of 50 °C, and B30 with a temperature variation of 60 °C. Data 

collection was carried out in testing diesel motors, which aims to determine the performance 

of diesel motors. The data taken during the trial included voltage, current and time values. 

This test uses 20 ml of fuel for each variation, starting from setting the engine speed to 1000 

rpm, with a variety of loading from 1000 watts to maximum load (4000 watts). After the 

data was obtained in the form of current, voltage, and time values, calculations were carried 

out based on the formula previously described to obtain values for power (kW), specific fuel 

consumption (kg.kW.h), torque (N.m), and thermal efficiency (%). The machine testing 

scheme can be seen in Figure 1. 

 

 
Fig. 1. Schematic diagram of experimental engine set-up [19] 

 

III. Results and Discussions 

The research stage that must be carried out was to make a fuel sample that will be tested 

on a diesel engine. The sample is B30, a mixture of 30% corn oil and 70% diesel fuel. These 

samples were then made in two temperature variations, namely 500 C and 600 C. The two 

fuel samples were then tested for their viscosity and density values. Table 2 shows the 

density and viscosity values of biodiesel fuel according to PT Pertamina. 

 

 



90   Journal of Mechanical Engineering Science and Technology                       ISSN 2580-0817 

                                               Vol. 7, No. 1, July 2023, pp. 87-95 

Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

Table 2. Biodiesel specifications [20] 

Characteristic Unit Min value Max value Methods 

Density gr/ml 0.815 0.88 ASTM D4052/1298 

Viscosity Cst 2 5 ASTM D445 

 

 

Fig. 2. Fuel samples. a) Pure diesel oil, b) Corn (Maize) oil B30 

 

   

               a)        b)         c) 

Fig. 3. a) B30 temperature measurement, b) testing the density of B30 using a pycnometer, c) 

testing the viscosity of B30 using a viscometer 

 

Figure 2 shows two fuel samples, namely pure diesel oil and B30, while Figure 3a shows 

the process of measuring the temperature of the previously heated B30 fuel. Figure 3b shows 

the process of testing the density of the fuel using a pycnometer, and Figure 3c shows the 

process of testing the viscosity of the B30 fuel sample with a temperature variation of 50 C 

and 60 C. The results of testing the viscosity and density of the fuel can be seen in Table 3, 

which shows that the density and viscosity values of B30 fuel are not included in the standard 

fuel determined by PT Pertamina, according to Table 2. 

Table 3. Density and viscosity of B30 biodiesel with temperature variations of 50 °C and 60 °C. 

Pertamina Standard Biosolar (B30) Biodiesel Corn Oil B30 

Characteristic Unit Min Value Max Value Temp.(oC) Result Methods 

Density gr/ml 0.815 0.88 
50 0.92 ASTM 

D4052/1298 60 0.91 

Viscosity Cst 2 5 
50 6.2 

ASTM D445 
60 5.8 

B30 (Corn 

(Maize) oil 30% 

and Pertamina 

Dex 70% 

 

Pure diesel oil 

(Pertamina Dex) 

 



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Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

1. Engine Performance Testing 

The engine test is carried out to determine the resulting engine performance value based 

on the variation of the fuel used. The data obtained in the engine testing process were used 

to find the value of power, torque, SFC, and engine thermal efficiency. Table 4 shows the 

engine test result data. 

 

Table 4. Engine test result data in four load conditions 

Fuel 
Load 

(watt) 

V 

(Volt) 

A 

(Ampere) 

Time 

(s) 

V 

(Volt) 

A 

(Ampere) 

Time 

(s) 

V 

(Volt) 

A  

(Ampere) 

Time 

(s) 

750 rpm 1000 rpm 1250 rpm 

Diesel 

Oil 

1000 72.2 3.26 308 112.4 3.37 211 138.1 3.47 165 

2000 65.5 3.29 224 88.6 3.42 166 78.9 3.48 146 

3000 53.5 3.45 210 63.2 3.68 162 58.3 4.17 144 

4000 40.4 4.5 190 51.8 4.94 155 50.1 5.88 138 

B30  

50 °C 

1000 72.8 2.03 348 115.7 2.43 260 149.5 2.95 233 

2000 68.5 2.68 302 104.6 2.75 205 94.7 3.24 209 

3000 59.7 3.02 298 75.7 3.07 165 65.2 4.32 162 

4000 45.9 3.68 280 60 3.68 141 54.4 4.34 140 

B30  

60 °C 

1000 66.5 3.18 357 114.2 2.76 232 140 2.97 166 

2000 62 3.22 322 88.6 3.46 220 88.2 3.52 155 

3000 54.5 4 267 66.5 3.86 214 61 4.34 152 

4000 39.36 4.45 289 52.3 5.33 183 49.5 5.74 146 

 

2. Performance Analysis of Diesel Engine 

After testing the engine and obtaining the value of voltage, current, and time of fuel 

consumption, it can be determined the value of torque, SFC, and the value of thermal 

efficiency. 

Comparative Analysis Between Torque and Load 

One of the commonly used engine performance parameters is torque. The torque itself 

indicates the quality of the fuel. Whether it can provide a large torque value or not, the 

greater the torque affect the engine power. Figure 4 shows a graph of the ratio of torque to 

load with a variety of fuels, namely diesel without heating, B30 with a temperature of 50 

°C, and B30 with a temperature of 60 °C at 750 rpm where the largest value is diesel fuel 

without heating at a load of 1000 watts with the torque value is 3.75 N.m. The smallest value 

is found in the B30 fuel with a temperature of 50 °C at a load of 1000 watts with a torque 

value of 2.36 N.m. Figure 4 shows the ratio of torque to load with a variety of fuels, namely 

diesel without heating, B30 with a temperature of 50 °C, and B30 with a temperature of 60 

°C at 1000 rpm. The largest value is diesel fuel without heating at a load of 1000 watts with 

the torque value is 4.52 N.m, while the smallest value is found in the B30 fuel with a 

temperature of 50 °C at a load of 4000 watts with a torque value of 2.64 N.m. Figure 4 also 

shows the ratio of torque to load with various fuels, namely diesel without heating, B30 with 

a temperature of 50 °C, and B30 with a temperature of 60 °C at 1250 rpm, where the largest 

value is diesel fuel without heating at a load of 1000 watts with the torque value is 4.57 N.m, 



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Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

while the smallest value is found in the B30 fuel with a temperature of 50 °C at a load of 

4000 watts with a torque value of 2.25 N.m. 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

 

 

 

Fig. 4. Graph of torque vs load based on a variation of speed  

 

Figure 4 shows the lowest average torque value found in the B30 fuel variation with a 

temperature of 50 °C at 750 rpm and 1000 rpm, so the power generated is also quite low. 

However, at 1250 rpm, the torque value has increased at a load of 1000 watts to 3000 watts. 

The average highest torque value is found on pure diesel fuel without heating at 750 rpm, 

1000 rpm, and 1250 rpm at minimum load. Then, the B30 fuel with a temperature of 60 °C 

produces the highest torque value at 1000 rpm at maximum load. This affects the power 

generated is greater. 

Comparative Analysis of Thermal Efficiency vs Power 

Figure 5 shows the comparison of thermal efficiency to the load with a variety of fuels, 

namely diesel without heating, B30 with a temperature of 50 °C, and B30 with a temperature 

of 60 °C at 750 rpm where the largest value is found in the B30 fuel with a temperature of 

60 °C at a load of 1000 watts with a thermal efficiency value of 0.128%. The smallest value 

is found in diesel fuel without heating at a load of 4000 watts with a thermal efficiency value 

of 0.058%. 



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Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

Figure 5 shows the comparison of thermal efficiency to the load with a variety of fuels, 

namely diesel without heating, B30 with a temperature of 50 °C, and B30 with a temperature 

of 60 °C at 1000 rpm, where the largest value is found in diesel fuel without heating at a 

load of 1000 watts with a thermal efficiency value of 13.5%, while the smallest value is 

found in the B30 fuel with a temperature of 50 °C at a load of 4000 watts with a thermal 

efficiency value of 5.3%. It also shows the comparison of thermal efficiency to load with a 

variety of fuels, namely diesel without heating, B30 with a temperature of 50 °C, and B30 

with a temperature of 60 °C at 1250 rpm. The largest value is found in the B30 fuel with a 

temperature of 50 °C at a load of 1000 watts with a thermal efficiency value of 17.4%, while 

the smallest value is found in the B30 fuel with a temperature of 50 °C at a load of 4000 

watts with a thermal efficiency value of 5.6%. 

 

 

 

Fig. 5. Graph of thermal efficiency vs load based on a variation of speed  

IV. Conclusions 

The results of this study indicate that with variations in the mixture of diesel oil and corn 

oil (Maize) fuel, it can be used as an alternative fuel to reduce dependence on hydrocarbon 



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Suardi et al. (Effect of Temperature Variations of Corn Oil Biodiesel on Efficiency of Diesel Engines) 

fuels. Variations in temperature between B30 at 50 °C and 60 °C affects the viscosity and 

density values of the fuel. The higher the fuel temperature, the more values and density 

increase. B30 fuel at 50 °C and 60 °C have the viscosity value of 6.2 cSt and 5.8 cSt, 

respectively. The density of B30 at 50 °C and 60 °C are 0.92 gr/ml and 0.91 gr/ml, 

respectively. The performance value on the B30 at 60 °C indicates the highest torque of 4.75 

N.m, and a thermal efficiency value of 17.4% is obtained. 

Acknowledgment 

I express my high appreciation to all parties who have helped in this research until the 

end. I hope this research can help other researchers develop alternative energy for engines 

in the future. 

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