40th International Conference on Production Engineering of Serbia
ICPES 2025
Nis, Serbia, 18-19th september 2025

MODELS FOR PREDICTING THE MAXIMUM HEIGHT OF THE SURFACE ROUGHNESS PROFILE BASED ON AXIAL DRILLING FORCE

Radoslav VUCUREVIC, Zdravko KRIVOKAPIC, Saša S. RANÐELOVIC, Mirjana MILJANOVIC, Brankica COMIC

DOI: 10.46793/ICPES25.043V


Abstract:

The functional performance and in-service quality of products are strongly influenced by surface roughness, which is a direct outcome of material removal processes. In general, surface roughness is function by the input parameters of the machining process and the extent of tool wear, the increase of which leads to an increase cutting forces, torque, acoustic emission level, vibrations, and temperature. Finding the dependence between machining parameters, tool wear indicators, and surface roughness parameters enables real-time prediction of surface quality and contributes to appropriate processing quality. In this study, based on data obtained through experiment conducted using the Taguchi design of experiment, predictive models were developed using multiple regression analysis and artificial neural networks (ANN). These models establish a relationship between input drilling parameters, axial drilling force, and the maximum height of the surface roughness profile.

Keywords:

Drilling, Surface roughness, Axial force, Multiple regression, ANN

References:


[1] A. Çiçek, T. Kivak, G. Samtas: Application of Taguchi Method for Surface Roughness and Roundness Error in Drilling of AISI 316 Stainless Steel, Strojniški vestnik-Journal of Mechanical Engineering, Vol. 58, No. 3, pp. 165-174, 2012.
[2] B.V. Raghunandan, S.L. Bhandarkar, K.S. Pankaj: An Experimental Mathematical Modelling of Surface Roughness in Turning Opertion of En19 with Carbide Tool, International Journal of Mechanical Engineering and Research, Vol. 3, No. 5, pp. 495-502, 2013.
[3] M.N. Konanki, R.R. Sadineni: ANN Based Surface Roughness Prediction in Turning of AA 6351, International Journal of Engineering Research and Applications, Vol. 3, No. 4, pp. 1455-1459, 2013.
[4] M. Hanief, M.F. Wani: Artificial neural network and regression-based models for prediction of surface roughness during turning of red brass (C23000), Journal of Mechanical Engineering and Sciences, Vol. 10, No. 1, pp. 1835-1845, 2016.
[5] I.A. Badi, A.G. Shetwan, A. Maitig: Using Multiple Linear Regression and Artificial Neural Network to Predict Surface Rou-ghness in Turning Operations, International Journal of Computational & Neural Engineering, Vol. 4, No. 4, pp. 91-97, 2017.
[6] Y. Xu, K. Hiroyuki, Z. Wei: Back Propagation Wavelet Neural Network based Prediction of Drill Wear from Thrust Force and Cutting Torque Signals, Computer and Information Science, Vol. 2, No. 3, pp. 75-86, 2009.
[7] P. Karali: Acoustic Emission based Tool Condition Monitoring System in Drilling, in: Proceedings of the World Congress on Engineering 2011, 06-08.07.2011, London, UK, pp. 2126-2130.
[8] O. Spaic, B. Marinovic: Influence of Wearing Drills on Drilling Axial Force, in: Proceedings of 1st International Scientific Conference Cometa 2012, 28-30.11.2012, East Sarajevo-Jahorina, B&H, RS, pp. 83-90.
[9] R. Vucurevic, Z. Krivokapic, R. Brdanin: Comparative Analysis of Surface Quality Prediction Models, International Journal of Engineering and Tehnology, Vol. 10, No. 2, pp. 441-449, 2018.
[10] Z. Krivokapic, R. Vucurevic, D. Kramar, J. Šakovic Jovanovic: Modelling Surface Roughness in the Function of Torque When Drilling, Metals, Vol. 10, No. 3, 337, 2020.
[11] Y.C. Lin, K.D. Wu, W.C. Shih, P.K. Hsu, J.P. Hung: Prediction of Surface Roughness Based on Cutting Parameters and Machining Vibration in End Milling Using Regression Method and Artificial Neural Network, Applied Sciences, Vol. 10, No. 11, 3941, 2020.
[12] M. Tomov, V. Gecevska, E. Vasileska: Modelling of multiple surface roughness parameters during hard turning: A comparative study between the kinematical-geometrical copying approach and the design of experiments method (DOE), Advances in Production Engineering & Management, Vol. 17, No. 1, pp. 75-88, 2022.
[13] R. Vucurevic, Z. Krivokapic, B. Comic: Prediction the maximum height of rou-ghness profile as a function of tool wear using artificial neural networks, in: Book of abstracts of 15. International Quality Conference, 21-23.05.2025, Kragujevac, Serbia, pp. 251-252.
[14] Per. of Student’s t distribution, available at: http://ptrckprry.com/course/langone/handout/t-percentile.pdf, accessed: 12.06.2025.