Abstract
The main objective of this article is to perform the turning operation on an EN36B steel work-billet with a tungsten carbide tool, to study the optimal cutting parameters and carry out an analysis of flank-wear. Experimental and simulation-based research methodology was opted in this study. Experimental results were obtained from the lab setup, and optimisation of parameters was performed using RSM (response surface methodology). Using RSM, cutting-tool flank-wear was optimised, and the cutting parameters which affect the flank wear were determined. In results main effect plot, contour plot, the surface plot for flank-wear and forces (Fx, Fy and Fz) were successfully obtained. It was concluded that tool flank-wear is affected by depth of cut, and that flank-wear generally increases linearly with increasing cutting-speed, depth of cut and feed-rate. To validate the obtained results, predicated and measured values were plotted and were in very close agreement, having an accuracy level of 96.33% to 98.92%.
Subject
General Materials Science
Reference53 articles.
1. In-process tool wear estimation in milling using cutting force model;Choudhury;J. Mater. Process. Technol.,2000
2. Optimisation of surface roughness on turning fibre-reinforced plastics (FRPs) with diamond cutting tools;Davim;Int. J. Adv. Manuf. Technol.,2005
3. Evaluation of expert system for condition monitoring of a single point cutting tool using principle component analysis and decision tree algorithm;Elangovan;Expert Syst. Appl.,2011
4. An experimental study of effect of process parameters in turning of LM6/SiCP metal matrix composite and its prediction using response surface methodology;Joardar;Int. J. Eng. Sci. Technol.,2011
5. John, R., Lin, R., Jayaraman, K., and Bhattacharyya, D. (2021). Modified Taylor’s equation including the effects of fiber characteristics on tool wear when machining natural fiber composites. Wear, 468–469.
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