Abstract
Surface roughness, an indicator of surface quality, is one of the most specified customer requirements in machining of parts. In this study, the experimental results corresponding to the effects of different insert nose radii of cutting tools (0.4, 0.8, 1.2 mm), various depth of cuts (0.75, 1.25, 1.75, 2.25, 2.75 mm), and different feedrates (100, 130, 160, 190, 220 mm/min) on the surface quality of the AISI 1030 steel workpieces have been investigated using multiple regression analysis and artificial neural networks (ANN). Regression analysis and neural network-based models used for the prediction of surface roughness were compared for various cutting conditions in turning. The data set obtained from the measurements of surface roughness was employed to and tests the neural network model. The trained neural network models were used in predicting surface roughness for cutting conditions. A comparison of neural network models with regression model was carried out. Coefficient of determination was 0.98 in multiple regression model. The scaled conjugate gradient (SCG) model with 9 neurons in hidden layer has produced absolute fraction of variance(R2)values of 0.999 for the training data, and 0.998 for the test data. Predictive neural network model showed better predictions than various regression models for surface roughness. However, both methods can be used for the prediction of surface roughness in turning.
Highlights
Metal cutting is one of the most significant manufacturing processes in material removal
The 33 full factorial design was used to study the effect of the three process parameters: depth of cut, feed rate, and insert nose radius on surface roughness
After 75 specimens were cut for experimental purpose, they were measured with a profilometer to obtain the surface roughness average value Ra and were recorded
Summary
Metal cutting is one of the most significant manufacturing processes in material removal. Metal cutting can be defined as the removal of metal from a workpiece in the form of chips in order to obtain a finished product with desired size, shape, and surface roughness. Turning is the process of machining external cylindrical and conical surfaces. It is usually performed on a lathe [1]. The quality of machined components is evaluated by how closely they adhere to set product specifications for length, width, diameter, surface finish, and reflective properties. Dimensional accuracy, tool wear, and quality of surface finish are three factors that manufacturers must be able to control at the machining operations [2]
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