Open Access Open Access  Restricted Access Subscription Access

Machine Learning Approach to the Prediction of Surface Roughness of Turned Glass/Basalt Epoxy Composites


Affiliations
1 KLE Technological University's Dr.MSSCET, Depatment of Mechanical Engineering, Belagavi, 590008, India

In this work, the Machine Learning techniques namely Support Vector Regression, Random forest methodand Extreme Gradient Boosting (XGBOOST) are utilized for the prediction of Surface Roughness in the turning process of Glass/Basalt epoxy hybrid composites. The experiments were conducted in accordance with the Taguchi's L27 orthogonal array. The experimental results indicates that, the surface roughness of the turned Glass/Basalt epoxy composites decreases with the increase in Spindle speed, decrease in Feed rate and Depth of cut. It was also observed that feed rate has a greatest impact and Depth of cut has a least effect over the surface roughness while the spindle speed moderately influenced the surface roughness. From the results of Machine Learning models, it is evident that the Random forest model appears to be superior with a Mean Absolute error and Maximum error of 4.96% and 7.73% respectively for testing data set.

Keywords

Composites, Production, Turning, Surface Roughness, Machine Learning
User
Notifications
Font Size

Abstract Views: 68




  • Machine Learning Approach to the Prediction of Surface Roughness of Turned Glass/Basalt Epoxy Composites

Abstract Views: 68  | 

Authors

Amith Gadagi
KLE Technological University's Dr.MSSCET, Depatment of Mechanical Engineering, Belagavi, 590008, India
Chandrashekar Adake
KLE Technological University's Dr.MSSCET, Depatment of Mechanical Engineering, Belagavi, 590008, India

Abstract


In this work, the Machine Learning techniques namely Support Vector Regression, Random forest methodand Extreme Gradient Boosting (XGBOOST) are utilized for the prediction of Surface Roughness in the turning process of Glass/Basalt epoxy hybrid composites. The experiments were conducted in accordance with the Taguchi's L27 orthogonal array. The experimental results indicates that, the surface roughness of the turned Glass/Basalt epoxy composites decreases with the increase in Spindle speed, decrease in Feed rate and Depth of cut. It was also observed that feed rate has a greatest impact and Depth of cut has a least effect over the surface roughness while the spindle speed moderately influenced the surface roughness. From the results of Machine Learning models, it is evident that the Random forest model appears to be superior with a Mean Absolute error and Maximum error of 4.96% and 7.73% respectively for testing data set.

Keywords


Composites, Production, Turning, Surface Roughness, Machine Learning