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Multiobjective optimization of end milling parameters for enhanced machining performance on 42CrMo4 using machine learning and NSGA-III

Van-Hai Nguyen, Tien-Thinh Le, Anh-Tu Nguyen, Hoang Xuan Thinh, Nhu-Tung Nguyen

2024Machining Science and Technology14 citationsDOI

Abstract

The present study analyzes and optimizes machining characteristics, including feed rate (fz), depth of cut (ap), cutting speed (Vc), cutter-coated material (Mtc) and cutting-edge radius (rt), impacting on surface roughness (Ra), material removal rate (MRR) and tool wear (VB) of 42CrMo4 steel during dry end-milling. A total of 108 experimental runs were conducted, focusing on Ra, VB and MRR as response parameters. The nano TiAlN PVD-coated tool yielded better results for Ra and VB than did the TiCN/Al2O3 MT-CVD-coated tool. Then, Ra, VB and MRR optimization was carried out simultaneously using a Non-Dominated Sorting Genetic Algorithm III (NSGA-III) and Machine Learning (ML) models. Pareto solutions were found to offer a range of values for the three performance objectives: Ra (0.315–0.556 µm), VB (12.33–32.48 µm) and MRR (0.44–3.58 cm3/min). A quantitative performance score (Ps) ranking index was calculated to rank Pareto solutions for practical case studies. Validation experiments were subsequently performed to affirm that the optimal solution fell within a reasonable error range, with MAPE of 9.58% for Ra, 9.25% for VB and 13.39% for MRR. The validation results underscore the versatility of this approach, suggesting its applicability to a wide array of machining optimization challenges.

Topics & Concepts

End millingMachiningSortingMulti-objective optimizationEnhanced Data Rates for GSM EvolutionSurface roughnessTool wearMechanical engineeringMachine toolEnd millMaterials scienceEngineering drawingComputer scienceEngineeringAlgorithmComposite materialMachine learningArtificial intelligenceAdvanced machining processes and optimizationAdvanced Machining and Optimization TechniquesInjection Molding Process and Properties
Multiobjective optimization of end milling parameters for enhanced machining performance on 42CrMo4 using machine learning and NSGA-III | Litcius