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www.etasr.com Nguyen et al.: Cutting Parameter Optimization in Finishing Milling of Ti-6Al-4V Titanium Alloy under … 

 

Cutting Parameter Optimization in Finishing Milling 

of Ti-6Al-4V Titanium Alloy under MQL Condition 

using TOPSIS and ANOVA Analysis 
 

Van Canh Nguyen 

Department of Manufacturing Technology 
Faculty of Mechanical Engineering 

Hanoi University of Industry 

Hanoi, Vietnam 
nguyenvancanh@haui.edu.vn  

Thuy Duong Nguyen 

Department of Machine Tool and Tribology 
School of Mechanical Engineering 

Hanoi University of Science and Technology 

Hanoi, Vietnam 
duong.nguyenthuy@hust.edu.vn  

Dung Hoang Tien 

Department of Manufacturing Technology 
Faculty of Mechanical Engineering 

Hanoi University of Industry 

Hanoi, Vietnam 
tiendung@haui.edu

 

 

Abstract-Titanium and its alloys give immense specific strength, 

imparting properties such as corrosion and fracture resistance, 

making them the right candidate for medical and aerospace 
applications. There is a wide range of engineering applications 

that use titanium alloys in a variety of forms. The cost of these 

alloys is slightly higher in comparison to other variants due to the 

problematic extraction of the molten process. To reduce costs, 

titanium alloy products could be made by casting, isothermal 

forging, radial swaging, or powder metallurgy, although these 

techniques require some kind of finishing machining process. 
Titanium and its alloys are difficult to machine due to skinny 

chips leading to a small cutting tool-workpiece contact area. The 

thermal conductivity of titanium alloys is too low and the stress 

produced is too large due to the small contact area, which results 

in very high cutting temperatures. This paper deals with the 

experimental study of the influence of the Minimum Quantity 

Lubricant (MQL) environment in the milling of Ti-6Al-4V alloy 

considering the optimization of surface roughness and production 

rate. Taguchi-based TOPSIS and ANOVA were used to analyze 

the results. The experimental results show that MQL with 

vegetable oil is successfully applied in the milling of Ti-6Al-4V. 

The research confirms the suitability of TOPSIS in solving the 

Multiple Criteria Decision Making (MCDM) issue, by choosing 
the best alternative at Vc=120m/min, fz=0.065mm/tooth, and 

ap=0.2mm, where the surface roughness and material removal 

rate are 0.41µm and 44.1492cm
3
/min respectively. Besides, 

ANOVA can be used to predict the best parameters set in the 

milling process based on the regression model. The parameters 

predicted by ANOVA analysis do not coincide with any 
implemented parameters. 

Keywords-surface milling; surface roughness; Taguchi-based 

TOPSIS; titalium alloy; Ti-6Al-4V; MCDM; MQL 

I. INTRODUCTION  

According to the thermophysical properties at elevated 
temperatures, titanium alloy Ti-6Al-4V is considered as the 
best material to manufacture parts in medical or euro space 
industry [1, 2]. However, machining Ti-6Al-4V is complicated 
because the temperature is usually very high in the contact area 
between the workpiece and the cutting tool [3–9]. To reduce 
cutting heat, Metalworking Fluids (MWFs) have been selected 
as the most common solution [10]. Due to the harmful effects 
of WMF to the operator’s health and environment, reducing 
MWF consumption is always considered. In this aspect, dry 
machining and Minimum Quantity Lubricant (MQL) are two of 
the most effective alternatives. For the past 20 years, many 
publications have confirmed the effectiveness of using MQL 
metalworking in general and Ti-6Al-4V machining in 
particular. Authors in [11] researched the role of MQL 
condition in tool wear and surface quality in turning process 
with an uncoated cutting tool. The research showed the 
encouraging results where the MQL environment leads to the 
significant reducing of tool wear and surface roughness mainly 
through the declining of the temperature in cutting area and the 
change of the interaction between chip-tool and tool-workpiece 
during machining. Authors in [12] studied the grinding of Ti-
6Al-4V titanium alloy and the effects of different lubrication 
conditions on the surface quality. The research showed that 
vegetable oil can be applied in the milling of titanium alloys 
under MQL conditions. Hence, the MQL technique was 
applied in this study work to replace conventional lubricants in 
the milling process. 

Corresponding author: Thuy Duong Nguyen 



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Authors in [13] carried out a study research to apply a 
Multiple Criteria Decision Making (MCDM) approach for 
enhancing University accreditation process. The results showed 
that MCDM is suitable to solve multi response optimization 
problems. Taguchi-based techniques, namely TOPSIS, 
MOORA, VIKOR, COPRAS, etc. have been often used to 
solve MCDM problems with high accuracy. Authors in [13, 14] 
used the TOPSIS method to solve the MCDM problem. These 
researches show that TOPSIS could be applied to find the best 
alternative easily and quickly. The problem here is that the 
TOPSIS or other Taguchi-based technique can help finding the 
best solutions from the conducted experiments only. This 
means that this method cannot help predicting or finding the 
exact optimum parameters set. To come over this disadvantage, 
new methods can be applied, for example Genetic Algorihm or 
combinations of some of the conventional methods. Authors in 
[7] used statistical and soft computing techniques to determine 
the optimum surface roughness in the milling of Ti-6Al-4V. 
Their results show that the RSM model could be applied in 
predicting the optimum surface roughness value in the milling 
of titanium alloys. However, the predictive result given by 
Artificial Neural Networks (ANNs) is more accurate than by 
the Response Surface Method (RSM). 

Authors in [15] applied an experimental model to optimize 
and predict the effect of the cutting tool on surface roughness 
and geometrical characteristics in the drilling of H13 steel. The 
Evolutionary Multiple Attribute Optimization algorithm was 
employed to find the optimum parameters set. NSGA-ІІ (Non-
dominated Sorting Genetic Algorithm) method was developed, 
and the regression functions were considered to find the 
optimum of surface roughness. The successful optimization 
results are consistent with the experimental findings, and 
ultimately the optimal set of cutting parameters can be chosen 
by machining operators according to the application. The study 
also showed that increased cutting speed and liquid coolant 
intensity decline surface quality. By contrast, the rising of 
cutting depth, tool diameter, and feed rate led to better surface 
quality. Many other studies showed that MQL and vegetable 
oil are suitable for machining titanium alloy surfaces. The 
machining of titanium alloys is a major research topic. The 
challenge is mainly the cost, due to the very high price of the 
material and the cutting tools leading usually to a reduced 
number of experiments. In this case, using the Taguchi design 
method of an experiment is addressed as one of the best 
solutions [16]. The Technique for Order Preference by 
Similarity to Ideal Solution (TOPSIS) effectively identifies the 
best alternative quickly. Authors in [17] succeeded in applying 
an MCDM model to find the optimum shot-peening parameters 
set. Authors in [18] were successful in multi-objective 
optimization on surface quality optimization and MRR in the 
face milling of AISI 304 steel. The results show that a 
significant influence of all milling parameters on the MRR and 
both the feed-rate and the depth of cut have a significant effect 
on the cutting force. In the current work, information entropy is 
performed to derive the objective weights of the evaluation 
criteria. An entropy-based TOPSIS is employed to rank the 
alternatives in order of preference and then choose the best 
solution that conforms to the decision maker’s idea [19, 21] 

II. RESEARCH METHODOLOGY 

A. Optimization Issues 

Surface roughness and production rate are two standard and 
essential criteria that must be considered in machining. 
Improving surface quality leads to reduced Material Removal 
Rate (MRR). So, finding the best solution to balance surface 
roughness and production rate is a critical issue. In this study, 
two primary responses, including the arithmetical mean 
roughness (Ra) and specific Material Removal Rate (MRR), are 
optimized simultaneously using the entropy-based TOPSIS 
model. The average roughness value is calculated as: 

�� =
����������	���
����

�
    (1) 

where Rai is the arithmetic roughness at the i-th position. 

The production rate is the amount of material removed per 
time unit and is determined by: 

MRR =
�.��.��

����
    (2) 

where MRR is the production rate in cm
3
/min, ap is the depth 

of cut in mm, w is the width of cut in mm, and vf is feed speed 
in m/min. 

For the milling process, the cutting parameters, including 
cutting speed (Vc), depth of cut (ap), and feed rate (vf) can be 
considered as inputs. The values of cutting parameters are 
chosen by the suggestions of the cutting tool’s manufacturer 
and the recommendations of any mold manufacturers. The 
variance factor data are shown in Table I. In this study, the 
MQL is fixed at 150ml/h flow rate and 2MPa air pressure. The 
experiment is performed in 5-axis CNC Machine DMG 
DMU50 (Germany), and the surface roughness results were 
measured with the Mitutoyo Surftest JS-310 (Japan). 

TABLE I.  THE VALUE SET OF CUTTING PARAMETERS 

No. Parameter Symbol Unit 
Level 

-1 0 1 

1 Cutting Speed Vc m/min 120 210 300 

2 Feed fz mm/tooth 0.02 0.06 0.10 

3 Depth of cut ap mm 0.1 0.5 0.9 

 

The optimizing issue is described below. The study's 
approach uses the MCMD method for selecting the best 
solution for minimizing surface arithmetic roughness (Ra) and 
maximizing the production rate (MRR). 

TABLE II.  EXPERIMENTAL DATA 

Run Vc fz ap Ra MRR 

1 60 0.03 0.2 0.281 5.42 

2 60 0.065 0.4 0.336667 1.08 

3 60 0.1 0.6 0.737333 16.25 

4 90 0.03 0.4 0.328 21.67 

5 90 0.065 0.6 0.321333 10.83 

6 90 0.1 0.2 0.506667 2.17 

7 120 0.03 0.6 0.358667 32.5 

8 120 0.065 0.2 0.411667 43.33 

9 120 0.1 0.4 0.635667 16.25 
 



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B. Multi-Response Optimization Framework 

The TOPSIS method was presented in [22, 23], and its 
steps are: 

Step 1:  Given a set of alternatives, � = ���|� = 1,2, . .��, 
and a set of criteria,  � ! "|# � 1,2, . .$% , where  
& � !'�"|� � 1,2, . .�,# � 1,2,…$%  denotes the set of 
performance ratings and ) � !)"|# � 1,2,. .$% is the set of 
weights. The information table I=(A, C, X, W) can be 
represented as shown in Table III.  

TABLE III.  THE INFORMATION TABLE OF TOPSIS 

Alternative C1 C2 … Cm 

A1 x11 x12 … x1m 

A2 x21 x22 …  

…
 

…
 

 

…
 

…
 

An xn1 xn2 … xnm 

W w1 w2 … wm 

 

Step 2: Calculating the normalized rating by [20, 21, 24-
28]: 

*�" � +,-.∑ 0+,-� 12,3�
, � � 1,2 …$;# � 1,2…�   (3) 

Step 3: Calculating the weighted normalized rating by: 

5�"0'1 � )"*�"0'1, � � 1,2…�;# � 1,2…$    (4) 
Step 4: Calculating a positive ideal point (PIS) and a negative 

ideal point (NIS) by: 

PIS � �� � �5��0'1,59�0'1,…,5:�0'1� �	!<max� 5�" 0'1|# ∈
A�B,<min� 5�"0'1|	# ∈ A9B|	� � 1,2…�%    (5) 

		NIS � �F � �5�F0'1,59F0'1,…,5:F0'1� �	!<min� 5�" 0'1|	# ∈
A�B,<max� 5�"0'1|	# ∈ A9B	|	� � 1,2…�%    (6) 

where J1 and J2 are the benefit and non-benefit criteria 
respectively. 

Step 5: Calculating the separation from the PIS and the NIS 
among alternatives using the Euclidean distance, which is given 
as: 

G�∗ � .∑ I5�"0'1 J 5"�0'1K9:"L� ,    � � 1,2,…�     (7) 

G�F � .∑ I5�"0'1 J 5"F0'1K9:"L� ,    � � 1,2,…�    (8) 
Step 6: Determining the similarities to the PIS by the 

formula: 

 �∗ � M,
N

<M,∗�M,NB
, � � 1,2,…�    (9) 

where  �∗ ∈ O0,1Q		∀� � 1,2,…�. 
Step 7: Arranging PIS0 �∗1 and choosing the best and the 

worst alternatives according to their ranking. In this study, the 
weight set in (4) would be replaced by a new set, which is 
determined by entropy, given as in the following step. 

Step 8: Calculating the entropy by: 

S" � J �TU0:1 ∑ I*�". ln<*�"BK:�L� , � � 1,2,…$;# � 1,2,…�   (10) 
Then the objective weight for each criterion can be 

determined as: 

)" � W �FX-∑ 0�FX-1Y-3� Z , # � 1,2,…�    (11) 
III. EXPERIMENTAL PROCEDURE 

In this work, the titanium alloy Ti-6Al-4V is selected, and 
the five-axis milling center DMG DMU50 is used for the 
machining experiment. The experimental workpiece and 
machine are shown in Figures 1 and 2. The surface roughness 
value was measured 3 times at 3 different positions for each 
experiment by a Mitutoyo Surftest JS-310. The average value 
is shown in Table IV. 

 

  
Fig. 1.  Experimental set-up. 

 
Fig. 2.  Workpiece specimen. 

IV. RESULTS AND DISCUSSION 

A. Optimization using Entropy-based TOPSIS 

Step 1: The given selected responses are arranged in the 
information table of TOPSIS according to Table IV. 

TABLE IV.  TOPSIS EXPERIMENTAL INFORMATION 

Alternative Ra MRR 

A1 0.281 5.42 

A2 0.336667 1.08 

A3 0.737333 16.25 

A4 0.328 21.67 

A5 0.321333 10.83 

A6 0.506667 2.17 

A7 0.358667 32.5 

A8 0.411667 43.33 

A9 0.635667 16.25 

 

Step 2: The given responses are transformed to non-
dimensional form by (3). The result is presented in Table V. 

Step 3: The weigh set is calculated using entropy by (10) 
and (11). The summarized results are shown in Table VI. 



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TABLE V.  THE NON-DIMENSIONAL FORM 

Alternative 
Conversion vector 

r1 r2 

A1 0.204 0.085 

A2 0.244 0.017 

A3 0.534 0.254 

A4 0.238 0.339 

A5 0.233 0.169 

A6 0.367 0.034 

A7 0.260 0.509 

A8 0.298 0.678 

A9 0.460 0.254 

TABLE VI.  ENTROPY WEIGHT SET 

e1 e2 

2.6831 5.1092 

w1 w2 

0.2906 0.7094 

 

Step 4: The weighted normalized rating is calculated by (7), 
using an entropy weight set. The result is shown in Table VII. 

Step 5: The best and the worst solutions are determined 
using (5) and (6). The result is shown in Table VIII. 

Step 6: PIS and NIS are calculated among the alternatives 
by (7) and (8). 

Step 7: PIS ( "∗1 can be derived according to (9). 
Step 8: PIS ( "∗1 is arranged and the best and the worst 

alternatives are selected (Table IX). 

TABLE VII.  ENTROPY WEIGHTED NORMALIZED RATING 

Alternative v1 v2 

A1 0.0591 0.0602 

A2 0.0709 0.0120 

A3 0.1552 0.1804 

A4 0.0690 0.2406 

A5 0.0676 0.1202 

A6 0.1066 0.0241 

A7 0.0755 0.3608 

A8 0.0867 0.4810 

A9 0.1338 0.1804 

TABLE VIII.  BEST AND WORST SOLUTIONS 

 Ra MRR 

A
+
 0.059148495 0.011989059 

A
-
 0.155203335 0.481005487 

TABLE IX.  THE RANKING OF THE ALTERNATIVES 

Alternative v1 v2 S
+
 S

-
 C

*
 Ranking 

A1 0.0591 0.0602 0.4317 0.0482 0.1004 7 

A2 0.0709 0.0120 0.4765 0.0117 0.0240 9 

A3 0.1552 0.1804 0.3006 0.1939 0.3921 4 

A4 0.0690 0.2406 0.2554 0.2288 0.4725 3 

A5 0.0676 0.1202 0.3713 0.1086 0.2263 6 

A6 0.1066 0.0241 0.4595 0.0490 0.0964 8 

A7 0.0755 0.3608 0.1442 0.3492 0.7077 2 

A8 0.0867 0.4810 0.0686 0.4698 0.8727 1 

A9 0.1338 0.1804 0.3014 0.1842 0.3794 5 

According to Table IX, the A8 is the best alternative, with 
Ra and MRR values of 0.41166µm and 43.33 respectively. The 
worst is A2 with Ra value at 0.336667 µm. The production rate 
accounted for was 1.08 cm

3
/min. The value of surface quality 

in A8 alternative is worse than in A2, but its MRR is about 40 
times higher. 

V. ANOVA ANALYSIS 

In Table X we can see the SNR versus Vc, fz, ap (smaller is 
better). Table X and Figure 3 illustrate that in the milling of the 
titanium alloy Ti-6Al-4V under MQL conditions, the feed rate 
value impacts significantly on surface roughness, followed by 
the effect of cutting speed Vc. On the other hand, the influence 
of depth of cut ap on the surface quality is fuzzy.  

TABLE X.  RESPONSE TABLE FOR SIGNAL TO NOISE RATIOS 

Level Vc fz ap 

1 7.710 9.872 8.214 

2 8.483 9.009 7.691 

3 6.850 4.163 7.138 

Delta 1.633 5.709 1.076 

Rank 2 1 3 

 

 
Fig. 3.  Main effects signal to noise ratios. 

TABLE XI.  SOLUTION RANKING BY ANOVA ANALYSIS 

Solution Vc fz ap MRR fit Ra fit 
Composite 

desirability 

1 120 0.03 0.6 44.1492 0.369511 0.897796 

2 120 0.03 0.2 33.2325 0.334549 0.819577 

3 120 0.065 0.6 36.6512 0.411079 0.775842 

4 120 0.03 0.4 30.7508 0.351432 0.770634 

5 120 0.065 0.2 26.7734 0.370215 0.699454 

6 120 0.065 0.4 24.5508 0.389908 0.650340 

7 90 0.03 0.6 18.8877 0.312368 0.626507 

8 90 0.065 0.6 14.1041 0.344462 0.515162 

9 60 0.03 0.6 13.4869 0.329394 0.512360 

TABLE XII.  ERROR OF CALCULATED AND ANOVA RESULTS 

 
Calculated values Predicted values Error 

MRR 43.330 44.1492 1.856% 

Ra 0.4116667 0.369511 10.24% 

 

Multi-response optimization is performed by the ANOVA 
tool in MiniTab, and the result is presented in Figure 4. The 



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ANOVA analysis gives similar results. Its best solution is at 
0.32µm of surface roughness and 34.3078cm

3
/min MRR, while 

the predicted results are 0.41 and 43.33 respectively (Table 
XIII). 

 

 
Fig. 4.  Multiple response optimization analysis results. 

TABLE XIII.  ANOVA AND TOPSIS MULTI OPTIMIZATION RESULTS 
COMPARISON 

 
Best solution set determined by 

TOPSIS ANOVA 

Vc (m/m) 120 120 

fz (mm/tooth) 0.065 0.03 

ap (mm) 0.2 0.6 

Ra (µm) 0.41 0.32 

MRR (cm
3
/min) 43.33 34.30 

 

VI. DISCUSSION 

The results in Table IX confirm that TOPSIS is the right 
tool for multiple responses in milling Ti-6Al-4V. Multi-
response optimization analysis with TOPSIS and ANOVA 
tools in Minitab showed relatively similar best choice results. 
TOPSIS shows the A8 alternative at Vc=120m/min, 
fz=0.065mm/tooth and ap=0.2 as the best parameters set, where 
Ra=0.412µm and production rate accounts for 43.330cm

3
/min. 

Meanwhile, for ANOVA analysis, the most optimal choice is 
Ra=0.36µm, MRR=44.1492cm

3
/min. The analytical results in 

Table X show that the difference between these two methods is 
1.856% in MRR and 10.24% in roughness. 

Noticeable, TOPSIS helps selecting the best one out of 9 
experimental options only, which means that the set of 
parameters of cutting mode is one of the implemented 
parameter sets, whereas the ANOVA allows the prediction of 
the best cutting parameters based on the experimental data. In 
this case, the optimal set of parameters is predicted to be 
(Vc=120 m/min, fz=0.03 mm/tooth, and ap=0.6mm). This 
predicted parameter set does not coincide with any 
implemented parameters. This study shows that combining 
TOPSIS and ANOVA analysis could be applied to approve the 
multiple optimization of the cutting process.  

VII. CONCLUSION 

The current work aimed at optimizing the cutting 
parameters in the milling of Ti-6Al-4V under MQL 
condictions. TOPSIS method and ANOVA analyis were 
performed and the following findings of this research should be 
considered: 

• MQL with vegetable oil is successfully applied in the face 
milling of Ti-6Al-4V.  

• The impact of feed rate on surface roughness is significant. 
Increasing feed rate or cutting speed lead to rising 
production rate (MRR) but reduce the quality of surface 
roughness. 

• The best solution chosen by TOPIS is (Vc=120m/min, 
fz=0.065mm/tooth, and ap=0.2mm), where the surface 
roughness and the material removal rate are 0.41µm and 
44.1492 cm

3
/min respectively.  

• The best solution predicted by MiniTab is (Vc=120m/min, 
fz=0.03mm/tooth, and ap=0.6mm), where the surface 
roughness is 0.32µm and the material removal rate is 
34.4cm

3
/min.  

• The TOPSIS model can be applied to find the best 
parameters set in the milling of Ti-6Al-4V. This model can 
be used in different machining processes or materials.  

• ANOVA analysis by software can be used to predict and 
find the best alternative of the milling process based on the 
regression model. The parameter set predicted by ANOVA 
analysis does not coincide with any implemented 
parameters. 

ACKNOWLEGEMENT 

The authors appreciate the assistance from the Hanoi 
University of Industry for the support in the research process. 

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AUTHOR PROFILES 

 

Van Canh Nguyen is a lecturer at the Department of Manufacturing 

Technology, Faculty of Mechanical Engineering, Hanoi University of 

Industry. He is a PhD candidate, and his research work focuses on the multiple 

optimization of metal cutting process under minimum quantity lubricant.  

 

Thuy Duong Nguyen is a PhD in the Department of Machine Tool and 

Tribology, School of Mechanical Engineering, Hanoi University of Science 

and Technology. Her research focuses on the effects of friction and tribology 

on machine parts. 

 

Dung Hoang Tien is an associate professor at the Department of 

Manufacturing Technology, Faculty of Mechanical Engineering, Hanoi 

University of Industry. His research work focuses on multi-optimization, 

addaptive machining, and micro-machining.