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Optimization of End Mill Geometry for Machining 1.2379 Cold-Work Tool Steel Through Hybrid RSM-ANN-GA Coupled FEA Approach

Tolga Berkay Şirin, Oğuzhan Der, H Kuś, Çağla Gökbulut, Ş. Yüksel, Ayhan Etyemez, Mustafa Ay

2025Machines9 citationsDOIOpen Access PDF

Abstract

Optimizing end mill geometry is critical for improving performance and reducing costs in the high-volume manufacturing of tools, dies and molds. This study demonstrates a successful optimization framework for solid end mills machining 1.2379 cold-work tool steel, integrating Finite Element Analysis (FEA), Artificial Neural Networks (ANN), and Genetic Algorithms (GA). The optimized tool geometry, derived from four key design parameters, delivered substantial performance gains over an industrial reference (parent) tool. Our ANN-GA model achieved a remarkable predictive accuracy (R = 0.75–0.98) over the RSM model (R = 0.17–0.63) and identified an optimal design that reduced the resultant cutting force by approximately 11% (to 142.8 N) and improved surface roughness by 21% (to 0.1637 µm) compared to experimental baselines. Crucially, the new geometry halved the tool breakage rate from 50% to ~25%. Parameter analysis revealed the width of the land as the most influential geometric factor. This work provides a validated, high-performance tool design and a powerful modeling framework for advancing machining efficiency in tool, mold and die manufacturing.

Topics & Concepts

End millMachiningMechanical engineeringFinite element methodSurface roughnessCutting toolMachine toolTool wearGenetic algorithmEngineeringResponse surface methodologySurface finishStructural engineeringEnd millingArtificial neural networkMillEngineering drawingWork (physics)BreakageMoldMulti-objective optimizationDie (integrated circuit)Geometric modelingNumerical controlBearing (navigation)Design toolSolid modelingAdvanced machining processes and optimizationAdvanced Machining and Optimization TechniquesAdvanced Surface Polishing Techniques