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Al-Khwarizmi 
Engineering 

Journal 
 

Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, June, (2021) 
P. P. 8-17 

 

 
Prediction of Surface Roughness after Turning of Duplex Stainless 

Steel (DSS) 
 

Osamah F. Abdulateef 
Department of Automated Manufacturing Engineering / Al-Khwairzmi College of Engineering/  

University of Baghdad/ Iraq 
Email: drosamah@kecbu.uobaghdad.edu.iq 

 
(Received 8  December 2020   ; Revised 4 January 2021;  Accepted 19   January 2021) 

https://doi.org/10.22153/kej.2021.01.001 

 

Abstract 
         

Feed Forward Back Propagation artificial neural network (ANN) model utilizing the MATLAB Neural Network 
Toolbox is designed for the prediction of surface roughness of Duplex Stainless Steel during orthogonal turning with 
uncoated carbide insert tool. Turning experiments were performed at various process conditions (feed rate, cutting 
speed, and cutting depth). Utilizing the Taguchi experimental design method, an optimum ANN architecture with the 
Levenberg-Marquardt training algorithm was obtained. Parametric research was performed with the optimized ANN 
architecture to report the impact of every turning parameter on the roughness of the surface. The results suggested that 
machining at a cutting speed of 355 rpm with a feed rate of 0.07 mm/rev and a depth of cut 0.4 mm was found to 
achieve lower surface roughness with,  an increase in the cutting speed and feed rate with the increases of the surface 
roughness. In addition, an increase in the depth of cut was found to reduces the surface roughness. The outcome of this 
study showed that ANN is a versatile tool for prediction of surface roughness and may be easily extended with greater 
confidence to various metal cutting processes.  
 
Keywords: Artificial neural network, cutting depth, cutting speed, feed rate, orthogonal array, taguchi method. 
  

  
1. Introduction 

 
Metal cutting is one of the most commonly 

utilized manufacturing processes, the 
improvement in the performance of these 
processes and productivity based on cutting 
parameters like cutting tool geometry, cutting 
conditions in addition to the tool material and 
workpiece is essential. The surface feature is an 
essential parameter for determining the 
performance of machine tools and parts. 
Therefore, achieving the required surface quality 
is of great importance for the practical behavior of 
mechanical parts. The surface roughness is a 
widely utilized indicator of product quality in 
terms of various parameters such as fatigue life 
improvement, tribological considerations, 
corrosion resistance, etc. Today, particular 
consideration is given to dimensional precision 

and surface finish in every manufacturing industry 
[1]. Thus, it is possible to consider the 
measurement and characterization of the surface 
finish as a predictor of machining efficiency. The 
mechanism of surface roughness creation is very 
dynamic, complex, and process- dependent. 
Variety of factors like cutting fluid, cutting 
parameters, and the hardness of the workpiece 
have been found to affect surface roughness in the 
turning process in different amounts [2].  

Several studies on surface roughness of 
different materials have been performed; the 
optimal cutting conditions are calculated most of 
the time utilizing the “Taguchi method” and by 
combining empirical models with different 
optimization algorithms based on roughness and 
artificial neural network (ANN). Gokkaya and 
Nalbant [3] examined the impact of feed, spindle 
speed, and coating type on surface roughness with 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

9 

various spindle speeds. They finalized that surface 
roughness is inversely commensurate with the 
spindle speed. Nalbant et al. [4] examined the 
prediction of surface roughness considering 
process parameters in the operation of CNC 
turning. To predict the surface roughness, they 
utilized a neural network with regression models. 
They concluded that the estimation of surface 
roughness utilizing neural networks was 
consistent with regression models. The impacts of 
cutting parameters on surface finish when turning 
composite materials utilizing “Taguchi 
experimental design techniques” have been 
studied by Palanikumar and Karthikeyan [5]. 
They concluded that the approach studied may be 
utilized to research the impact of surface 
roughness with a 95 percent confidence level in 
Al/SiC-MMC composites. Javidi et al. [6] 
investigated the impact of feed rate and tool nose 
radius on maximum surface roughness. To 
evaluate optimum cutting conditions utilizing the 
“Taguchi method”, Dave et al. [7] examined 
surface roughness in turned machine parts. They 
concluded that in machining processes, surface 
roughness has a significant effect. Lavanya et al. 
[8] developed a predictive model on the basis of 
“ANN” for the prediction of AISI-1016 surface 
roughness during orthogonal turning with CBN 
insert tool. The experiments of turning were 
performed at various process conditions utilizing 
full factorial design. Feed rate, cutting speed and 
depth of cut, were the input parameters while the 
surface roughness was the output variable. The 
obtained results concluded that ANN is 
dependable method, and it can be easily used to 
various metal cutting processes with higher 
confidence. Kant et al. [9] joined the ANN along 
with a genetic- algorithm (GA) for surface 
roughness prediction and optimization. Vaibhav 
and Sachin [10] investigated boring aluminum 
material on CNC machining taking into account 
spindle speed, feed rate, and depth of cut to get 
minimum surface roughness utilizing the 
"Taguchi method". They suggested that the most 
important parameters for surface roughness are 
depth of cut and spindle speed. Das et al. [11] 
investigated surface roughness in CNC turning 
taking into account feed rate, cutting depth, and 
spindle speed utilizing the "Taguchi method". The 
verification of these parameters was justified by 
utilizing "Taguchi method". Gupta and Kumar 
[12] examined surface roughness and material 
removal rate in turning operation utilizing the 
"Taguchi method", taking into account rake angle 
and nose radius of the tool, feed rate, spindle 
speed, and cutting depth. They finalized that 

surface roughness increases with feed rate. Sonali 
et al. [13] examined optimum machining 
parameters considering surface roughness on 
aluminum 6061. They concluded that feed rate, 
depth of cut, spindle speed, and nose radius had a 
significant effect on surface roughness. Dahbi et 
al.[14] researched turning 2017A aluminum alloy 
utilizing a CNC lathe machine to calculate 
different cutting parameters. Utilizing ANN, they 
investigated the cutting parameters and their 
impact on surface roughness. The formulated 
ANN network founded that the experimental 
result was in near agreement with the predicted 
results. Pawan and Misra [15] suggested an 
enhanced predictive model for DSS turned 
component  surface roughness. The impact of 
different input cutting parameter namely feed rate, 
cutting speed, and approach angle are taken into 
account for the established model. The L9 
orthogonal array on a turning machine with 
analysis of variance were utilized to examine the 
impact of process parameters on surface 
roughness. They concluded that the feed rate was 
the most important factor followed by cutting 
speed and approach angle. Joshy et al. [16] 
performed CNC turning operation on the material 
of aluminum alloy 7075 and the surface roughness 
was conducted by considering machining 
parameters like feed rate, depth of cut, and spindle 
speed. The optimization of the process was carried 
out utilizing “analysis of variance (ANOVA)”. 
The prediction of surface roughness has been 
carried out utilizing the "feed-forward back-
propagation ANN method”. Suresh et al. [17] 
investigated the impact of cutting parameters on 
surface roughness creation in machining of 
Duplex Stainless Steel (DSS) with TiN coated 
carbide tool. Taguchi technique is utilized for 
optimizing the cutting parameters. L27 orthogonal 
array was utilized to conduct the experimental 
trials. The obtained results indicated that the 
surface roughness decreases with increase in 
cutting speed and low feed rate. Elsadek et al. [18] 
applied “ANN” and response surface 
methodology (RSM) predictive tools for 
predicting "surface roughness" on hard- turning of 
AISI H13 hot work steel.  

It is noted from the above literature that many 
studies have been studied for different materials 
utilizing the ANN method to optimize surface 
roughness. Hence, the present study analyzes the 
effects of cutting speed, feed rate, and depth of cut 
on surface roughness Ra by developing ANN 
models during turning of DSS by utilizing an 
uncoated carbide insert tool. Firstly, process 
parameters influencing surface roughness were 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

10 

covered by utilizing the "Taguchi method". The 
experimental results are based on the design of the 
experiment that has subsequently been utilized for 
training the ANN model. Finally, experimental 
confirmations are carried out on the developed 
model, and comparisons are made between 
experimental and predicted results of ANN. 

 
2. Methodology 
2.1 Experimental Procedure 
 

In the present work, the used workpiece 
material is DSS bar of 300 mm length and 50 mm 

in diameter. Utilizing the PSG-A141 traditional 
lathe machine with an uncoated carbide insert 
tool, dry turning is performed on all workpieces as 
shown in figure 1. For the experimental design, 
Taguchi's L27 orthogonal array is selected. The 
experiments are carried out by changing the 
process parameters and the mean surface 
roughness values (Ra) with a sampling length of 5 
mm were measured. Table 1 shows the considered 
cutting parameters and their levels. 

 
  

 

   
 
Fig. 1. Turning process in experimental work.  

 
Table 1, 
Control factors and levels 
Control Factors Units Level 1 Level 2 Level 3 
Cutting speed, V rev/ min 355 230 150 
Feed rate, f mm/min 0.3 0.13 0.07 
Cutting depth, d mm 0.6 0.4 0.2 

 
 

An experimental plan is needed to build a 
simulation model on the basis of the ANN that 
concerns to the average surface roughness and 
cutting parameters. Often, the classic experiment 
design is too complicated, considerable time, and 
difficult to use. Therefore, the Taguchi design of 
the experiment has been included in the current 
investigation. Three cutting parameters were 
considered, cutting speed (V), feed rate (f), and 
cutting depth (d). Based on the prior studies, the 
process parameter ranges were chosen. The 
process parameters were organized in the L27 
Orthogonal Array of standard Taguchi. The 
twenty-seven pieces are machined utilizing the 
above set of values and surface roughness (Ra) 
values are reported in Table 2 utilizing the micro-
roughness tester TR220 as shown in figure 2.  

 
 

 
 

Fig. 2. TR220 micro roughness device when 
measuring surface roughness.  
 

 
 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

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Table 2, 
Experimental values of surface roughness Ra. 
Exp. No. Cutting Speed (V) 

rev/min 
Feed Rate (f) 
mm/min

Cutting Depth (d) 
mm

Roughness   
(Experimental) µm 

1 355 0.3 0.6 2.577 
2 355 0.3 0.4 2.789 
3 355 0.3 0.2 2.89
4 355 0.13 0.6 2.376 
5 355 0.13 0.4 2.949 
6 355 0.13 0.2 2.819 
7 355 0.07 0.6 2.14
8 355 0.07 0.4 1.7545 
9 355 0.07 0.2 3.647 
10 230 0.3 0.6 2.464 
11 230 0.3 0.4 3.216 
12 230 0.3 0.2 3.53
13 230 0.13 0.6 2.714 
14 230 0.13 0.4 2.975 
15 230 0.13 0.2 3.096 
16 230 0.07 0.6 2.3
17 230 0.07 0.4 2.45
18 230 0.07 0.2 3.8
19 150 0.3 0.6 2.21
20 150 0.3 0.4 2.813 
21 150 0.3 0.2 3.8
22 150 0.13 0.6 2.161 
23 150 0.13 0.4 2.596 
24 150 0.13 0.2 3.711 
25 150 0.07 0.6 3
26 150 0.07 0.4 3.4
27 150 0.07 0.2 3.6

 
 

2.2 Artificial Neural Network (ANN)Model  
 
The input layer of ANN in this work has three 

neurons in terms of the three process parameters 
and one neuron in terms of surface roughness in 
the output layer. Different networks with different 
numbers of hidden layers and neurons in the 
hidden layer were constructed and verified to find 
the best network architecture; various training 
algorithms were utilized (Gradient descent, 
Newton method, Conjugate gradient, Quasi-
Newton, and Levenberg-Marquardt); log sigmoid 
transfer functions in the hidden layer and output 
layer were modified and the generalization 

potential of the various networks was observed 
and eventually, the optimum network was chosen 
with best performance (minimum MSE) to 
precede. 

The configuration of the ANN is indicated as 
3-40-1, consisting of three input neurons; the 
hidden layer is composed of forty neurons, and 
the output layer composed of one output neuron, 
as shown in figure 3. After designing and 
examining several networks that differ in their 
structure, transfer mechanism, training algorithm, 
etc. The number of neurons in the hidden layer is 
calculated by the trial-and-error process. 

 
 
 
 

A 
 
 

   
 

 
Fig. 3. Neural network schematic diagram for Ra.  

Cutting speed 

Feed rate 

Depth of cut 

 
Roughness 

Artificial 
network 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

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Training of an ANN represents an essential 
task in the design of an estimation model. The 
reliability of the forecast relies on how well it has 
been trained. In the work, the training of the 
neural network was done utilizing a “feed-forward 
back-propagation algorithm”. Two levels of data 
flow are carried out by the network. The input 
data is first spread from the input to the output 
layers and generates an output as a result. Then, 
the error signals arising from the disparity 
between the expected values of the networks and 
the real values are propagated back to the previous 
layers from the output layer to change their 
weights consequently. The weights upgrade 
continues till the objective of network error is 
achieved. 

The number of neurons in the hidden layer is 
deliberately selected to begin with five neurons, 
and the hidden neurons are progressively added to 
the hidden layer. Until there is no substantial 
advance in network output, the addition of hidden 
neurons continues. In terms of network training, 
the network performance was assessed by mean 
square error (MSE) between the predicted and the 
experimental values for each output node. The 
feedback from that processing is called the 
"average error" or "performance". Since the 
average error is reached or below the needed 
target, the neural network stops training and is 
thus, ready to be confirmed. MATLAB is utilized 
to train the network architecture that are produced 
for surface roughness estimation. 

The performance plot of the trained ANN 
model is shown in figure 4. The best confirmation 
performance (MSE) of the ANN is identified as 
0.00006497 which can be regarded as highly 
acceptable. The 27 patterns input-output dataset 
was split randomly into three categories: the 
training dataset consists of 50% of the data, the 
test dataset consists of 25% of the data, and the 
validation consists of 25% of the data. For ANN 
modeling of surface roughness, there are 13 
training patterns considered. After training, the 
weights are frozen and the model is examined for 
confirmation. The network is confirmed in this 
work concerning the agreement with experimental 
outcomes.  

 
 

 
 
Fig. 4. Performance graph of the neural network 
after training. 
 
 
3. Results and Discussions 
3.1 Experimental Analysis  
             

The experiment plan is designed to determine 
the impact of feed rate, cutting speed, and cutting 
depth on surface roughness Ra. This is observed 
in figure 5 where the surface roughness increases 
when the cutting speed increases from 150 rpm to 
350 rpm. The above pattern of rising the surface 
roughness with an increase in cutting speed is due 
to that the rate of heat transmitted to the 
surrounding from the machining area may be 
high. Therefore, the machining zone accumulates 
less heat. It is observed in figure 5 that as the feed 
rate increase from 0.07 mm/rev to 0. 3 mm/rev, 
the surface roughness steadily rising, due to the 
higher friction between cutting tool and work 
material as a result of greater cross-sectional area 
in the deformation region [19]. And it is also 
noted in the main impact plot in Fig. 5 that the 
surface roughness decreases as the cutting depth 
increases from 0.2 mm to 0.6 mm which is in 
agreement with Prasad et al. [19]. This can be 
assigned to the fact that a rise in cutting depth 
allows the temperature to increase due to an 
increase in frictional heat due to further contact 
between the working material and tool. Higher 
cutting temperatures, therefore, contribute to 
thermal softening of the working material, which 
leads less roughness of the metal [19]. 
Consequently, figure 5 and Table 2 show that 
machining with a cutting speed of 355 rpm with a 
feed rate of 0.07 mm/rev and a cutting depth of 
0.4 mm achieved lower surface roughness. 

 
 
 

 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

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Fig. 5. Main effect plots of Ra.  
 
 
3.2 Artificial Neural Network Analysis  
        

The estimated values are obtained and error is 
determined for each data set as shown in Table 3. 
The estimated average percentage error is 3.64 %, 
indicating that the accuracy of the forecast is 
around 96 %. Figure 6 shows the plot of estimated 
surface roughness for different test cutting 
conditions utilizing the neural network and actual 
surface roughness. From the graphs, it is clear that 

for each of the output parameters, the suggested 
model can estimate values that are almost quite 
similar to experimental observations. The results 
show that the ANN model can be easily used to 
predict surface roughness and thus, assists in the 
optimal choice of process parameters (V, f, d) for 
the planning of the cutting process and 
optimization of cutting parameters in turning DSS 
by uncoated carbide insert tool, which is agreed 
with Lavanya et al. [8]. 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

14 

 
Table 3, 
Experimental and estimated surface roughness comparison 

Exp. No. Cutting 
Speed (V) 
rev/min 

Feed Rate (f) 
mm/min 

Cutting 
Depth (d) 
mm 

Roughness   
(Experimental) 
µm 

Roughness 
(ANN) 
µm 

Error 
 
% 

1 355 0.3 0.6 2.577 2.66 3.22 
2 355 0.3 0.4 2.789 2.70 3.19 
3 355 0.3 0.2 2.89 2.97 2.76 
4 355 0.13 0.6 2.376 2.24 5.70 
5 355 0.13 0.4 2.949 2.93 0.64 
6 355 0.13 0.2 2.819 2.99 6.06 
7 355 0.07 0.6 2.14 1.97 7.94 
8 355 0.07 0.4 1.7545 1.83 4.3 
9 355 0.07 0.2 3.647 3.53 3.20 
10 230 0.3 0.6 2.464 2.49 1.05 
11 230 0.3 0.4 3.216 3.05 5.16 
12 230 0.3 0.2 3.53 3.73 5.66 
13 230 0.13 0.6 2.714 2.63 3.09 
14 230 0.13 0.4 2.975 3.08 3.52 
15 230 0.13 0.2 3.096 3.19 3.03 
16 230 0.07 0.6 2.3 2.40 4.34 
17 230 0.07 0.4 2.45 2.38 2.94 
18 230 0.07 0.2 3.8 3.64 4.21 
19 150 0.3 0.6 2.21 2.35 6.33 
20 150 0.3 0.4 2.813 2.76 1.88 
21 150 0.3 0.2 3.8 3.67 3.42 
22 150 0.13 0.6 2.161 2.21 2.26 
23 150 0.13 0.4 2.596 2.72 4.77 
24 150 0.13 0.2 3.711 3.71 0.02 
25 150 0.07 0.6 3 2.83 6.00 
26 150 0.07 0.4 3.4 3.28 3.52 
27 150 0.07 0.2 3.6 3.61 0.27 

 

 
 

Fig. 6. Experimental and estimated surface roughness comparison at different cutting conditions. 
  
 
 
 

 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

15 

4. Conclusions 
 
In the present study, the ANN model has been 

designed for surface roughness prediction in 
turning of DSS by utilizing the experimental 
results. The outcomes of the current work are 
outlined in the following: 
-  Machining at a cutting speed of 355 rpm with a 
feed rate of 0.07 mm/rev and a cutting depth of 
0.4 mm has been found to achieve lower surface 
roughness.  
-  An increase in the cutting speed and feed rate 
increases the surface roughness, while an increase 
in the depth of cut reduces the surface roughness. 
-  The expected values obtained from ANN are 
similar to those obtained from experimental 
values. The outcome of the prediction is 
advantageous with a 3.64% average error, which 
means the neural network is capable of predicting 
up to 96% accurate surface roughness. 
-  It is also noted that ANN is a better model 
considering its speed, ease, and ability to learn 
from examples. It does not need more 
experimental investigation. 
 
 
5. References 

 
[1] J. Z. Zhang, J. C. Chen, and E. D. Kirby, 

“Surface roughness optimization in an end-
milling operation using the Taguchi design 
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technology, vol. 184, no. 1-3, pp. 233-239, 
2007. 
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[2]  Kahraman, and A. Sagbas, “An investigation 
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[3] H. Gokkaya, and M. Nalbant,  “ The effects 
of cutting tool coating on the surface 
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Engineering and Environmental Sciences, 
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[4] M. Nalbant, H. Gokkaya, and I. Toktas, 
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[5] K. Palanikumar, and R. Karthikeyan, 
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[6] A. Javidi, U. Rieger, and W. Eichlseder, 
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[7] H. Dave,  L. Patel, and H. Raval, “Effect of 
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[8] K. Mani Lavanya, R. K .Suresh, A. Sushil 
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[9] G. Kant, and K. S. Sangwan,  “Predictive 
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[10] J. Vaibhav, and B. Sachin, “Process 
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[11] B. Das, R. N. Rai, , and S.C. Saha, “ Surface 
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[12] M. Gupta, and S.  Kumar, “ Investigation of 
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81, 2015. 
https://doi.org/10.1016/j.jestch.2014.09.006 



Osamah F. Abdulateef                        Al-Khwarizmi Engineering Journal, Vol. 17, No. 2, P.P. 8- 17 (2021) 
   

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[13] P. Sonali, and A. M. Mohanty, “ Performance 
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[14] S. Dahbi, L. Ezzine, and H.E.L. Moussami, 
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[15] K. Pawan and J. P. Misra, “A Surface 
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[16] Arjun Joshy, Royson Dsouza, Veerakumar 
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2019. https://doi.org/10.18280/jesa.520501 

[17] R. Suresh, L. Shivaramu, N.G. Siddesh 
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[18] Ahmed A. Elsadek, Ahmed M. Gaafer, and 
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[19] M. V. R. D. Prasad, Yelamanchili Sravya, 
and Karri Sai Tejaswi, “Study of the 
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 )2021(  8- 17 صفحة ،2العدد ،17المجلد الهندسية الخوارزمي جلةم                               اسامة فاضل عبد اللطيف                         

17 

 

 
 الخراطة   عملية  بعد)  DSS(  للصدأ  المقاوم  الفوالذ   سطح  بخشونة   التنبؤ

  
  أسامة فاضل عبداللطيف    

    بغدادقسم هندسة التصنيع المؤتمت/ كلية الهندسة الخوارزمي/ جامعة  
  drosamah@kecbu.uobaghdad.edu.iq : البريد اإللكتروني                                                                

                                                        
 

 
 الخالصة

 
الخلف  االصطناعية  العصبية  الشبكة  نموذج  تصميم  تم  الفوالذ  سطح  بخشونة  للتنبؤ  MATLAB Neural Network Toolbox  باستخدام  يلالنتشار 
 القطع  وسرعة)  f(   التغذية   معدل   هي  اإلدخال  تغيراتم  كانت.  مصقول  غير   كربيد   قطع نوع   أداة   باستخدام  ة المتعامد  بعد الخراطة  الوجهين  على  للصدأ   المقاوم

)V  (القطع  وعمق  )d  (العملية  من  لكل  تصميم   طريقة  باستخدام).  Ra(  السطح  خشونة   هو  اإلخراج  متغير  كان  بينما  ،   ANN)(  توقعال  ونموذج   التجارب 
Taguchi  بنية  على  الحصول   تم  ،  التجريبية  ANN  تدريب  خوارزمية  مع  مثالية  Levenberg-Marquardt  .بنية   باستخدام  حدودي  بحث  إجراء  تم  ANN  

 توسيعها   ويمكن  االستخدامات  متعددة  أداة  هي  ANN  أن  إلى  تحقيقها  تم  التي  نتائج ال  تشير.  السطح   خشونة  على   تحول  متغير  كل  تأثير  عن  لإلبالغ  المحّسنة 
   .المختلفة  المعادن  قطع لعمليات  أكبر ثقةو  بسهولة