Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
Vol. 1, No 1, July 2017, pp. 9-14  9 

         DOI: 10.17977/um016v1i12017p009 

Factors Affecting the Surface Roughness in Sinking EDM 
Process 

Ahmad Atif Fikri1, a *, Maftuchin Romlie1, Aminnudin1 
1Department of Mechanical Engineering, Faculty of Engineering, Universitas Negeri Malang, Semarang Street No. 5, 

Malang, East Java, Indonesia 
Corresponding author : * atif.fikri.ft@um.ac.id 

 

 
ABSTRACT  

The purpose of this study is to gain insights into the surface quality (smoothness) of sinking EDM 
machining products. Among other non-conventional machining processes, Electrical Discharge Machining 
(EDM) is the most commonly used process. EDM is a machining process that uses electric sparks created 
between a workpiece and a tool (electrode). As a manufacturing process, EDM is used for workpieces 
which have intricate contours and precise dimensions, and works by using electric discharges (sparks) 
applied in a rapid series of repetitive electrical discharges between the two electrodes, separated by a 
dielectric fluid, and subject to an electric voltage. Since the tool tends to wear easily and the mould material 
is very hard and tough, it is necessary to keep within appropriate EDM machining parameters, so that the 
smoothness of the mould lives up to expectations. Therefore, the parameters of sinking EDM process 
should be well established to produce the expected results, i.e. the smoothest surface quality and the 
maximum removal rate. Regarding the electrode materials used, conducting a further experiment is required 
to achieve the appropriate settings of pulse current, on-time, off-time, servo voltage, and gap width. This 
experimental study involved several factors: (a) electrode material, (b) magnitude of current, (c) on-time, 
and (d) quality of surface (smoothness). In this study, the gap between the electrode and the workpiece was 
controlled at a distance of 40 μm, and with an off-time of 5 seconds, the same dielectric fluid, the same flow 
speed and the same dielectric immersion, and using the workpiece (AISI P20M steel). Quantitative 
approaches (t test, one-way, and ANOVA) were applied to analyse the results of comparison test and to 
determine the best parameter in sinking EDM process. 
 
Copyright © 2017Journal of Mechanical Engineering Science and Technology 
All rights reserved 
Keywords: EDM process, Electrode, Surface Roughness 

I. Introduction 
 The development of manufacturing technology is growing rapidly along with the need to 

improve human welfare. Means of transportation such as motorcycles, home appliances, and 
communications devices such as cellular telephone, both made of metal or other materials (plastic 
and composite), are advancing. The development speed has been greatly influenced by the 
availability of supported technology, such as machining, formation, and moulding technology. 

The oldest machining process is the one performed by removing material in the form of chips. In 
metallic materials machining, the most used tools are lathes, freis, saws, grinders, etc, whereas in 
non-metal machining, the process is done by casting, forming, and moulding. Therefore, in mass 
manufacturing industry (casting, forming and moulding), the process of producing moulds, 
particularly the ones made of metal (both ferrous and non-ferrous), should be faster and efficient. - 
The durability of mould is strongly influenced by the mechanical properties of metal as the 
moulding material. Materials that have a high resistance to a wide range of requirements are 
typically made of hard materials but with low machining capabilities. In other words, the production 
capability of the machine is very low, because it is beyond the machine’s capacity to work with 
much stronger cutting tools. Furthermore, workpieces with difficult and intricate contours are no 
longer able to be processed with any conventional machine, or even with the most advanced CNC 
milling machine.  

Non-conventional machines such as chemical machining, electrochemical machining, electrical 
discharge machining, and high energy beam machining, are intended to manufacture products with 
intricate and complex contours. One of the four types of non-conventional machines owned by the 
Department of Mechanical Engineering, Universitas Negeri Malang, is the electrical discharge 
machining (EDM), namely sinking EDM. According to Schey (2009) [1], the surface quality of 

mailto:atif.fikri.ft@um.ac.id


10 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
 Vol. 1, No. 1, July 2017, pp. 9-14 

 Ahmad Atif Fikri et.al (Factors Affecting the Surface Roughness in Sinking EDM Process) 

EDM products is determined by many factors; the surface becomes rougher if the current density is 
higher, the viscosity of the dielectric material is higher, and the frequency is lower. These 
parameters highly depend on the enabled settings in the machine's features. There are various metals 
with different mechanical properties which can be used as a workpiece for intended purposes. 

EDM is capable of handling the mechanical properties of metals, in terms of hardness, tensile 
strength, and toughness under static and dynamic loads. EDM process is used in mould-making, thus 
surface smoothness is prioritised. In conventional machining process, the roughness level is 
determined by the established parameters in the machine’s system and the type of cutting tool used, 
thus the desired degree of smoothness is more achievable. While in EDM process, the factors 
affecting results are very complex, because the metal etching process involves heat generated by 
electric sparks, frequency of current discharge (on-current), level of cathode electrical conductivity 
(cutting tool), dielectric material, and mechanical properties of the workpiece (melting point). 
Dewangan (2010) [2], through his study on the steel AISI P20, concluded that the forming tool 
(cathode) wear was affected by the amount and frequency of current discharge, and the diameter of 
the forming tool. The fact that forming tool wear occurred showed how the factors affecting the 
surface smoothness of the mould were becoming more complex.  

The forming tool materials that can be used in EDM are copper, brass, and graphite. These 
materials are more easily formed using a machine with a simple cutting tool (HSS material), thus the 
desired shape or dimension can be very easily achieved. A research conducted by Kumar et al. 
(2012) [3] found that silver electrode provided a better performance in certain characteristics, but 
was relatively costly. Thus, graphite electrode was preferable in terms of metal removal rate (MRR) 
since its cost was comparatively lower than copper. The EDM machining parameters examined were 
fixed distance control variable between the electrode and the workpiece, positive polarisation 
(electrode connected to the positive pole), and the use of dielectric available in the market. The 
research only focused on volume8 reduction speed, not on surface quality (smoothness). 

A mould is (usually) made of hard solid steel which has an intricate contour and thus very 
difficult to process with a conventional machine. Consequently, the use of non-conventional 
machines, one of which is EDM, is more suitable for mould-making. The value of material removal 
rate and level of surface roughness of sinking EDM products depend on several parameters, such as 
pulse current, on- and off-time, servo voltage, and gap width. The bigger the value of pulse and gap 
width and the smaller the value of off-time and servo voltage, the higher the material removal will 
rate. If the value of pulse and width gap is big, and the value of off-time and servo voltage is too 
small, then the surface of the products will be rough  [4].  

The fact that cutting tool wear occurs and mould material is very hard and tough, denotes that it 
is necessary to utilise appropriate EDM machining parameters so that the surface quality of mould 
lives up to expectations [5]. Therefore, the parameters of sinking EDM process should be well 
established to produce the expected results, i.e. the smoothest surface quality and the maximum 
removal rate. Regarding the electrode materials used, conducting a further experiment is required to 
achieve the appropriate settings of the pulse current, on-time, off-time, servo voltage, and gap width. 
A. Determining Factors in the Ease of EDM Process 

The machining factors affecting the EDM machines differ from the conventional ones. 
Conventional machines rely on the hardness of tools and workpieces, whereas EDM machines 
depend on λ (thermal conductivity) θ (melting point) and ρ (electrical resistivity) [6]. The machining 
time cannot be considered as a parameter for the ease of EDM process because there are many other 
relatively complex factors affecting it, such as adhesion, cavitation, and short-circuiting [6]. 

II. Method 
This experimental study was done to investigate the quality of surface roughness of sinking EDM 

machining products. The variables involved in this study were (a) magnitude of current, (b) forming 
tool materials, (c) length of the current release time and (d) level of roughness. 
A. Tool, Workpiece, And Data Analysis Technique 

Electrode materials used were: (a) copper, (b) brass, and (c) graphite. The workpiece materials 
used were the ones for manufacturing plastic moulds, namely Assab Steel 618 SUPREME, AISI 



ISSN: 2580-0817 Journal of Mechanical Engineering Science and Technology 11 
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 Ahmad Atif Fikri et.al (Factors Affecting the Surface Roughness in Sinking EDM Process) 

P20M Steel (chemical composition: C 12:37%, Cr 2:00%, Mo 12:20%, Mn 1.4%, Si 0.3%, Ni 1.0%, 
and S <a 0.01%). These materials were utilised for injection moulding, extrusion dies, and forming 
tools. 

The forming tool specimen was prepared in the workshop at the Department of Mechanical 
Engineering, Universitas Negeri Malang. The apparatus utilised were an EDM machine (C-TEK 
ZNC-320-50A), a vertical Freis machine for manufacturing forming tools (cathode), a surface 
grinding machine to smooth the workpiece surface, and a roughness measuring tool (Mitutoyo 
Portable Surface Roughness Tester SJ-301P). 

The analysis techniques consisted of (a) descriptive analysis and (b) 4x3x3 ANOVA statistical 
analysis integrated with the assumption tests: (1) the normality of distribution and (2) homogeneity 
of variance. The analysis was performed using a relevant computer programme.  

III. Findings and discussion 
The data obtained from the experiments in this study are presented in Table 1. The results of the 

descriptive analysis are shown in Table 2, and the ones of 4x3x3 ANOVA statistical analysis are 
shown in Table 3. 

Table 1.   Results of Roughness Testing (µm) 

No Electrode Current (A) 
Time On (second) Average 

0.5 1 1.5 2   

1 Copper 

5 3.3 3.6 3.6 3.7 3.3 

10 2.9 3.1 3.2 3.4 2.9 

15 2.1 2.3 2.7 2.9 2.1 

2 Brass 

5 4.3 4.6 4.7 4.9 4.3 

10 3.9 4.2 4.2 4.4 3.9 

15 3.1 3.4 3.7 4.9 3.1 

3 Graphite 

5 8.3 8.6 8.7 8.9 8.3 

10 8.9 8.2 8.2 8.4 8.9 

15 8.1 8.4 7.7 8.9 8.1 

Average 4.54 4.74 4.82 5.24   

Table 2.  Results of Data Analysis 

No Electrode Current (A) Average Median Mode 
Standard 
Deviation 

1 Copper 
5 3.3 3.6 3.6 0.15 
10 2.9 3.15 #N/A 0.180277564 
15 2.1 2.5 #N/A 0.316227766 

2 Brass 
5 4.3 4.65 #N/A 0.216506351 
10 3.9 4.2 4.2 0.178535711 
15 3.1 3.55 #N/A 0.683282518 

3 Graphite 
5 8.3 8.65 #N/A 0.216506351 
10 8.9 8.3 8.2 0.286138079 

15 8.1 8.25 #N/A 0.438035387 

 



12 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
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 Ahmad Atif Fikri et.al (Factors Affecting the Surface Roughness in Sinking EDM Process) 

Table 3.  Results of ANOVA 

Anova: Single Factor       

SUMMARY       

Groups Count Sum Average Variance   

Copper with a current of 5 A  4 14.2 3.55 0.03   

Copper with a current of 10 A 4 12.6 3.15 0.043333   

Copper with a current of 15 A 4 10 2.5 0.133333   

Brass with a current of 5 A 4 18.5 4.625 0.0625   

Brass with a current of 10 A 4 16.7 4.175 0.0425   

Brass with a current of 15 A 4 15.1 3.775 0.6225   

Graphite with a current of 5 A 4 34.5 8.625 0.0625   
Graphite with a current of 10 A 4 33.7 8.425 0.109167   
Graphite with a current of 15 A 4 33.1 8.275 0.255833   

       
       

ANOVA       

Source of Variation SS df MS F P-value F crit 
Between Groups 196.815 8 24.60188 162.6073 8.45E-21 2.305313 
Within Groups 4.085 27 0.151296    

       
Total 200.9 35         

 

 
Fig. 1. The Average Roughness Level of Workpieces with Different Electrode Materials 

The ANOVA test yielded a p-value of 8.45E-21. This value indicates that this research result was 
not obtained by chance but as a result of significantly tested variables. 

Figure 1 illustrates the results of surface roughness testing on workpieces with three different 
materials. The electrode made of graphite had the highest surface roughness value while copper had 
the lowest value. This result appears to be supported by previous research by Mahardika (2007) [6], 
which suggested that there were at least three important factors affecting the EDM machining 
process, i.e. λ (thermal conductivity), θ (melting point), and ρ (electrical resistivity). The detail of 
electrode properties used in this study is presented in Table 4. 

Table 4.  Properties of Electrodes Used in the Experiment 



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 Ahmad Atif Fikri et.al (Factors Affecting the Surface Roughness in Sinking EDM Process) 

No Material λ (W/mK) θ (K) ρ (Ω cm) 
1 Copper 401 1356 0.0000017 
2 Brass 109 1173 0.000007 
3 Graphite 120 3565 0.0007837 

 

 
Fig. 2. Workpiece surface roughness based on current discharge rate 

Graphite has the highest value of electrical conductivity, thus it requires a greater energy to cause 
a spark. As a result, this type of electron will hit the workpiece so strongly that it causes a deeper 
electron penetration, which eventually leads to an increase in roughness of the workpiece. 
Meanwhile, this aforementioned circumstance will not happen in electrodes made of copper and 
brass. 

When it comes to the brass electrode, the energy needed for the electron to jump to the 
workpiece is relatively low because the electrical resistivity of brass is higher than graphite. As a 
result, the electron will hit the workpiece relatively weakly, hence the lower value of roughness. 

Figure 2 shows that in addition to the types of electrodes used, the current discharge rate affects 
the roughness of the workpiece. The higher the current discharge rate is, the higher the discharge 
energy is released [7]. Thus, the beam of electrons will hit the workpiece harder so that the value of 
its surface roughness is higher. 

IV. Conclusions 
Our work has led us to conclude that the types of electrode, the magnitude of current/the amount 

of pulse current, and material removal rate affect the surface roughness of the workpiece. Electrodes 
with properties λ (thermal conductivity), θ (melting point) and ρ (electrical resistivity) would affect 
the level of surface roughness of workpieces. The mechanism of the mechanical properties needs to 
be studied further to obtain information about electron behaviour related to its determining factors. 

References 
[1] J. A. Schey, Introduction to Manufacturing Processes, Yogyakarta: Andi, 2009 
[2] S. K. Dewangan, "Experimental Investigation of Machining Parameters for EDM Using U-  shaped 

Electrode of AISI P20 Tool Steel," Thesis. Department of Mechanical Engineering National Institute of 
Technology Rourkela, Rourkela, 2010. 

[3] N. Kumar, L. Kumar, H. Tewatia and R. Yadav, "Comparative Study for MRR an Die-Sinking EDM 
Using Electode of Copper & Graphite," International Journal of Advanced Technology & Engineering 
Research (IJATER), vol. 2, 2012. 

[4] Suhardjono, "Pengaruh Arc On dan Arc Off Time terhadap Kekasaran Permukaan dan Laju Pembuangan 
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14 Journal of Mechanical Engineering Science and Technology ISSN: 2580-0817 
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[5] F. Han, C. Li, Y. Dingwen and Z. Xiaoguang, "Basic study on pulse generator for micro-edm," The 
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