Prediction of surface roughness in turning machine by taguchi method


Al-Qadisiyah Journal For Engineering Sciences,         Vol. 8……No. 3 ….2015 
 

 

326 

 

 

 

 

 

 

PREDICTION OF SURFACE ROUGHNESS IN TURNING 

MACHINE Using TAGUCHI METHOD  

 

Dr.Abbas Fadhil Ibrahim 

 abbasfadhel_2006@yahoo.com 

Received 16 October 2014        Accepted 18 May 2015 

 

ABSTRACT 

This paper investigates the effect of process parameters (approach angle, nose radius, cutting speed and 

feed rate) on surface roughness in turning machine. The experiments was conducted based on 

Taguchi’s L8 orthogonal array and assessed with analysis of variance and signal to noise ratio. 

According to this, it was observed that surface roughness correlates negatively with nose radius and 

positively with approach angle. The ability of the independent values to predict the dependent values 

was 95.1% for mean. Minimum surface roughness was predicted as 4.207 μm with approach angle 5°, 

nose radius 1.5mm, cutting speed of 455 rpm and feed rate of 0.19 mm/rev. From analysis of variance 

ANOVA, the feed rate was the most significant parameter for minimum surface roughness, cutting 
speed was next significant parameter for minimum surface roughness, then nose radius, while 
approach angle was the last.  

 

Keywords: Surface roughness, turning, taguchi method, ANOVA, nose radius. 

 

 التنبؤ بالخشونة السطحية في عملية الخراطة باستخدام طريقة تاكوجي
 

  الخالصة:

، نصف قطر مقدمة الحد القاطع، سرعة القطع ومعدل  االقترابيهدف البحث على التعرف على تاثير اعتبارات التشغيل مثل )زاوية 

ومصفوفة عمو ية يتم تقييمها مع   8L عتما  على تاووجي اجريت باالاالختبارات  التغذية( على الخشونة السطحية في عملية الخراطة.

تحليل التباين ونسبة االشارة الى الضوضاء. طبقا" الى هذا يالحظ ان الخشونة السطحية ترتبط سلبيا" مع نصف مقدمة الحد القاطع 

 7.2.4% . ان اقل خشونة سطحية متنبأة وانت..59وايجابيا" مع زاوية االقتراب. قابلية القيم المستقلة على التنبؤ بالقيم المعتمدة وانت 

 5... ورة بالدقيقة و معدل تغذية  799ملم،سرعة قطع  9.. رجة ،نصف قطر مقدمة حد قاطع  9مايكرومتر مع زاوية اقتراب 

لثاني الذي يؤثر من تحليل التباين وان معدل التغذية هو االوثر تأثير ألقل خشونة سطحية ,سرعة القطع وانت هي المتغير اة.ملم/ ور

على اقل خشونة سطحية , ومن ثم نصف قطر مقدمة الحد القاطع, بينما زاوية االقتراب وانت االخيرة من ناحية التأثير على الخشونة 

 ..السطحية.

..............................................................................................................,..............................      

 

 



Al-Qadisiyah Journal For Engineering Sciences,         Vol. 8……No. 3 ….2015 
 

 

327 

 

1- INTRODUCTON:  

Metal cutting is one of the most significant manufacturing processes in the area of material removal 

[Chen, 1997]. Black defines metal cutting as the removal of metal from a workpiece in the form of 

chips in order to obtain a finished product with desired attributes of size, shape, and surface roughness 

[Black, 1979]. Turning is the processes used to remove material to produce specific products of high 

quality. Among various process conditions, surface finish is central to determining the quality of 

workpiece [Shin, 1995] .The tool edge geometry has an important influence on the process parameters, 

such as the cutting forces, distributions of temperature and stresses on the tool face and the chip 

morphology. These effects in turn affect the changes in chip flow, machined surface integrity, tool 

wear resistance, and tool life [Yen, 2004]. 

The various angles in a single-point cutting tool have an important function in machining operations. 

Cutting-edge angles affect chip formation, tool strength and cutting forces to various degrees [Jones, 

1999]. Cutting condition in a machining operation consist of cutting speed, feed rate and depth of cut. 

The effects of cutting speed and feed rate on the surface roughness are different with deferent change 

in cutting condition and materials [Shin, 1995, Hatem, 2011]. The surface roughness depending upon 

the cutting condition, essentially the cutting speed, the change of cutting speed give different results 

with increasing the cutting speed leads to improvement in the surface finish of turning process. The 

second factor which effected upon the surface roughness is feed rate, because of the elastic and plastic 

deformation on the surface layer reducing the feed rate helps to a chive a better surface quality. While 

the change in the depth of cut gives a less effect on the surface roughness, than on the cutting speed 

and feed rate [Shin, 1995, Kalpakjian, 2006, Groover, 2002]. The tool nose radius is very critical part 

of the cutting edge since it produces the finished surface, if the nose is made to a sharp point the finish 

machined surface will usually be unacceptable and the life of the tool will be short[Mccauley, 2000]. If 

other factors such as the work material, the cutting speed, and cutting fluids are not considered large 

nose radius will give better surface finish and will permit a faster feed rate to be used [Trent, 1984]. 

Avery large nose radius can often be used but a limit is some times imposed because the tendency for 

chatter to occur is increased as the nose radius is made larger prove that most cutting conditions , 
experimental and theoretical (Ra) values mach very well, except at low value of feed .Also one of the 
structural modes of the machine tool – workpiece system is excited by cutting forces initially away 
surface finish left during the previous revolution in turning is removed during the succeeding 

revolution which also leaves a wavy surface owing to structural vibrations[Shather, 2009]. Taguchi 

method has been widely used in engineering analysis, and is a powerful tool to design a high quality 

system. Moreover, Taguchi method employs a special design of orthogonal array to investigate the 

effects of the entire machining parameters through small number of experiments. The array forces all 

experimenters to design almost identical experiments [Brar, 2011].  

In the present research determination the effect of process parameters approach angle and nose radius 

for cutting tool, cutting speed and feed rate for turning machine on surface roughness in turning 

machine and then predict for surface roughness by using taguchi method. 

   

2. EXPERIMENTAL PROCEDURE: 

 2.1 Material: 

The workpiece used in this work was made of stainless steel with dimensions of 150mm length and 

40mm width. The chemical compositions are shown in table 1. 



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328 

 

2.2 Machine: 

The experiment was performed by using a Turning Machine model (Harrison M300) as shown in 

Figure 1. 

  

2.3 Cutting tool:  

The cutting tool was made of carbide, used with different approach angle (Table 2); this carbide has 

triangle shape and used three carbides insert with deferent nose radius (Table 2) as shown in Figure 2. 

                                            

2.4 Process parameters: 

The machining parameters, such as approach angle, nose radius, cutting speed and feed rate were 

varied to determine their effects on the surface roughness with fixed depth of cut at 1mm. The 

experiments were designed to study the effects of these parameters on response characteristics. Table 2 

shows the various levels of process parameters. 

 

3- ANALYSIS BY TAGUCHI METHOD: 

The experiments were planned by using the parametric approach of the Taguchi’s Method. The 

response characteristic data was provided in Table 3. The standard procedure to analyze the data based 

on S/N ratio, as suggested by Taguchi, was employed. The average values of the S/N Ratio of the 

quality/response characteristics for each parameter at different levels were calculated from 

experimental data. The response parameters (surface roughness), are of “smaller is the better” type of 

machining quality characteristics; hence the S/N ratio for these types of responses was given by 

equation (1) [Gupta, 2011]. 

 









 



n

i

i
y

n
NS

1

2
)(

1
log10/       ;        i=1, 2,………n                                    (1) 

 

Where n: number of reading test. 

          yi: output variable value (Ra). 

 

3.1 Taguchi orthogonal array: 

One of the basic elements of Taguchi method is Orthogonal Array (OA). To select an appropriate 

orthogonal array for the experiments, the total degrees of freedom need to be computed. The degrees of 

freedom are defined as the number of comparisons between process parameters that need to be made to 

determine which level is better and specifically how much better it is [Gupta, 2011]. There is minimum 

number of experimental trials required in orthogonal array, so it is more efficient in handling large 

number of factor variables than traditional factorial design. Additionally, the orthogonal array allows 

determination of the contribution of each quality influencing factor [Tongchao, 2010]. In the present 

research, the standard Taguchi orthogonal array of L8 (4
1 

x 2
3
) has been employed. 

 



Al-Qadisiyah Journal For Engineering Sciences,         Vol. 8……No. 3 ….2015 
 

 

329 

 

 3.2 Analysis of variance ANOVA: 

The ANOVA is used to investigate the statistical significance of the process parameter affecting the 

response. Therefore, the factor that has more percentage contribution in the process will be identified 

in analysis. The ratio between the variance of the process parameter and of the error called as F test 

determines whether the parameter has a significant effect on the quality characteristic. The larger F-

value has more effect on the performance characteristics [Chomsamutr, 2012]. ANOVA table obtained 

using Minitab program. 

 

4- RESULTS AND DISCUSSION: 

Table 3 represents the experimental results of various response Characteristics according to Taguchi L8 

mixed orthogonal array. Surface roughness for each experiment is measured using portable surface 

finish tester. Various response characteristics, namely, Ra in micrometers. The average (mean) of these 

characteristics and S/N ratio (in decibels) are shown for each characteristic. The R Square pieces (the 

ability of the independent values to predict the dependent values) is 95.1% for mean (surface 

roughness). 

The main purpose of the analysis of variance (ANOVA) is to investigate and indicate the designed 

parameters, which significantly affect the quality characteristic. In the analysis, the sum of the square 

deviation is calculated from the value of S/N ratio by separating the total variability of S/N ratio for 

each control parameter. 

This analysis helps to find out the relative contribution of finishing parameter in controlling the 

response of this process. The “P%” value (percent of contribution) in Tables 4 and 5 shows the 
effectiveness of each parameter toward influencing the related response characteristics within the 

specified range. From Table 4, it is concluded that the feed rate (parameter D) is the most significant 

parameter for minimum Ra. cutting speed (parameter C) is next significant parameter for minimum Ra 
, then nose radius (parameter B), while approach angle (parameter A) was the last. 

From Table 5, it is concluded that the cutting speed (parameter C) is the most significant parameter for 

maximum S/N ratio. Feed rate (parameter D) is next significant parameter for maximum S/N ratio, 

then nose radius (parameter B) , while approach angle (parameter A) was the last. 

Figures 3and 4 shows the plot of the means of the surface roughness and the means of S/N ratio. It is 

clear that the optimal parametric combination for minimum Ra is A1 B2 C1 D2, i.e., at 5° approach 

angle, 1.5mm  nose radius, 355 rpm cutting speed and 0.19mm/rev feed rate. It is suggested that the 

parametric combination within the considered range as mentioned above give lowest surface roughness 

height Ra for finishing of workpiece. 

 

5- CONCLUSIONS:         

The main conclusions deduced from the present work can be summarized as follows: 

1- The ability of the independent values to predict the dependent values) is 95.1% for mean. 

2- The feed rate (parameter D) is the most significant parameter for minimum Ra. 

3- The cutting speed (parameter C) is the most significant parameter for maximum S/N ratio. 



Al-Qadisiyah Journal For Engineering Sciences,         Vol. 8……No. 3 ….2015 
 

 

330 

 

4- The optimal parametric combination for minimum Ra is A1 B2 C1 D2, i.e., at 5° approach angle, 
1.5mm  nose radius, 355 rpm cutting speed and 0.19mm/rev feed rate. 

5- The optimal parametric combination for S/N is A1 B2 C1 D2, i.e., at 5° approach angle, 1.5mm 
nose radius, 355 rpm cutting speed and 0.19mm/rev feed rate. 

 

6- REFERENCES: 

 

[1]. Brar B.S., Walia R.S., Singh V.P., Singh Mandeep , “Development of a robust abrasive flow 

machining process setup”, National Conference on Advancements and Futuristic Trends in Mechanical 

and Materials Engineering ,2011. 

 

[2]. Christopher Mccauley (Machinery’s Hand book Guide 26) ,2000. 

 

[3]. Ding Tongchao, Zhang Song, Wang, Yuanwei and Zhu, Xiaoli, “Empirical Models and Optimal 

Cutting Parameters for Cutting Forces and Surface Roughness in Hard Milling of AISI H13 Steel”, 

International Journal Advanced Manufacturing Technology, Volume: 51, Issue: 1, Pages: 45-55, 2010. 

 

[4]. E.M.TRENT (metal cutting) second edition , 1984. 

 

[5]. Gupta, A., Singh, H. and Aggarwal, A., “Taguchi-fuzzy multi output optimization (MOO) in high 

speed CNC turning of AISI P-20 tool steel”, Expert Systems with Applications, Volume: 38, Issue: 6, 

Pages: 6822-6828, 2011. 

 

[6]. Huda Hatem, “Study the Effect of Cutting Conditions for turning process on the Machined 

Surface”, Nahrain University, College of Engineering Journal (NUCEJ) Vol.14 No.1, pp.61-66, 2011. 

 

[7]. J. C. Chen and R. A. Smith., "Experiment Design and Analysis in Understanding Machining 

Mechanisms , Journal of Industrial Technology, vol. 13, No. 3, pp. 15-19, 1997. 

 

[8]. J. T. Black, " Flow stress model in metal cutting , Journal of Engineering for Industry, vol. 101, 

No. 4, pp. 403-415, 1979. 

 

[9]. K. Chomsamutr and S. Jongprasithporn, “Optimization Parameters of Tool Life Model using the 

Taguchi Approach and Response Surface Methodology”, IJCSI International Journal of Computer 

Science Issues, Volume: 9, Issue 1, no. 3, Pages: 120-125, 2012. 

 

[10]. M. P. Groover, "Fundamentals of Modern Manufacturing", Lehigh University, second Edition, 

2002. 

 

[11]. Nigel Jones, "'intelligent' tooling make its presence felt", Machinery and Production Engineering, 

157, 3980: pp. 28-30, 1999. 

 

[12]. Saad Kariem Shather, “Studying The Effect of Tool Nose Radius on Workpiece Run Out and 

Surface Finish”,Eng.&Tech. Journal,vol.27,No.2,2009. 

 



Al-Qadisiyah Journal For Engineering Sciences,         Vol. 8……No. 3 ….2015 
 

 

331 

 

[13]. Serope kalpakjian, "Manufacturing Engineering and Technology", fifth edition, 2006. 

 

[14]. Y. C. Shin and S. A. Coker, "Surface Roughness Measure by Ultrasonic Sensing for in Process 

Monitoring", Journal of Engineering for industry, vol. 117, pp. 439, 1995. 

 

[15]. Y.C. Yen, A. Jain, T. Altan, “A finite element analysis of orthogonal machining using different 

tool edge geometries,” J. Mater. Process. Technol., vol. 146, pp. 72-81, February, 2004. 

 

 

 

 

Table (1): Chemical compositions of workpiece. [AISI] 

 

Element Cr% Ni% P% Mn% C% Fe% 

Weight 11.5 0.03 1.0 0.5 0.15 Remain 

 

 

 

Table (2): Process Parameters at Different Levels 

 

No. Parameter Level 1 Level 2 Level 3 

 
Level 4 

 

1 Approach angle(degree) A    5 10 15 20 

2 Nose radius (mm)   B 0.5 1.5 / / 

3 Cutting speed (rpm)   C 355 455 / / 

4 Feed rate (mm/rev) D 0.16 0.19 / / 

 

  

Table (3): The L
8 

(4
1
x2

3
) OA (Parameters Assigned) with experimental results of various  response 

Characteristics. 

No A B C D Ra1(µm) Ra2(µm) Ra3(µm) S/N Ra 

Mean(µm) 

Ra 
Predict(µm) 

1 5 0.5 355 0.16 4.32 4.65 4.56 -13.0877 4.51 4.41125 

2 5 1.5 455 0.19 3.98 4.33 4.05 -12.3038 4.12 4.21875 

3 10 0.5 355 0.19 5.25 5.41 4.64 -14.1697 5.10 5.19875 

4 10 1.5 455 0.16 4.87 4.96 5.77 -14.3463 5.11 5.10125 

5 15 0.5 455 0.16 5.01 5.42 5.50 -14.5090 5.31 5.40875 

6 15 1.5 355 0.19 5.32 5.10 5.09 -14.2716 5.17 5.07125 

7 20 0.5 455 0.19 5.29 5.22 5.48 -14.5364 5.33 5.23125 

8 20 1.5 355 0.16 5.12 4.78 4.77 -13.7910 4.89 4.98875 

 

 

 



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Table (4): Analysis of Variance for mean Taguchi Orthogonal Array (TOA) 

 

Source  Degrees 

of 

Freedom 

DF 

Sum of 

Squares 

SS 

Mean 

Sum of 

Squares 

SS 

Mean 

Square 

MS 

F value 

(MS /error) 

Percent of 

Contribution 

P 

A 3 1.07345 1.07345 0.357817 5.84 0.293 

B 1 0.11520 0.11520 0.115200 1.88 0.401 

C 1 0.00500 0.00500 0.005000 0.08 0.823 

D 1 0.00125 0.00125 0.001250 0.02 0.910 

Residual Error 1 0.06125 0.06125 0.061250   

Total 7 1.25615     

 

  

 

 

 

 

Table (5): Analysis of Variance for SN ratios Taguchi Orthogonal Array (TOA) 

                 
Source  Degrees 

of 

Freedom 

DF 

Sum of 

Squares 

SS 

Mean 

Sum of 

Squares 
SS 

Mean 

Square 

MS 

F value 

(MS /error) 

Percent of 

Contribution 

P 

A 3 3.64678 3.64678 1.21559 5.59 0.299 

B 1 0.38238 0.38238 0.38238 1.76 0.411 

C 1 0.00561 0.00561 0.00561 0.03 0.899 

D 1 0.01025 0.01025 0.01025 0.05 0.864 

Residual Error 1 0.21743 0.21743 0.21743   

Total 7 4.26246     

 

 

 

 

 

 

 

 

 

 

 

 



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Figure (1): Turning Machine model (Harrison M300) 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure (2): Holder and insert 

 

 

 

 



Al-Qadisiyah Journal For Engineering Sciences,         Vol. 8……No. 3 ….2015 
 

 

334 

 

 

2015105

5.2

5.0

4.8

4.6

4.4

1.50.5

455355

5.2

5.0

4.8

4.6

4.4

0.190.16

A

M
e

a
n

 o
f 

M
e

a
n

s

B

C D

Main Effects Plot for Means
Data Means

 
 

Figure (3): Main effects Plot for means 

 

 

2015105

-12.5

-13.0

-13.5

-14.0

-14.5

1.50.5

455355

-12.5

-13.0

-13.5

-14.0

-14.5

0.190.16

A

M
e

a
n

 o
f 

S
N

 r
a

t
io

s

B

C D

Main Effects Plot for SN ratios
Data Means

Signal-to-noise: Smaller is better
 

 

Figure (4): Main effects Plot for signal to noise ratios