Litcius/Paper detail

A novel grey-box approach to tool wear prediction using machine learning and finite element methods

Maximilian Berndt, Hagen Schmidt, Lars Müller, Eberhard Kerscher, J Seewig, Benjamin Kirsch

2025Wear7 citationsDOIOpen Access PDF

Abstract

This study presents an innovative approach combining numerical simulations with experimental data to improve the accuracy of tool wear prediction. A hybrid modeling strategy is employed, integrating physics-based finite element method with data-driven machine learning techniques. Tool life experiments in turning operations were conducted, and a tool wear state-dependent finite element model was developed alongside an acoustic emission-based extreme gradient boosting regression model. Cutting forces calculated through the finite element model were integrated into the machine learning model to enhance predictive performance. The results show that incorporating simulated process data significantly improves wear prediction capabilities and accuracy compared to purely data-driven models. This demonstrates the potential of hybrid modeling approaches, so called grey-box, to bridge the gap between physical process understanding and machine learning predictions, minimizing the need for extensive experimental data collection. Furthermore, this approach reduces the dependency on expensive measurement technologies by substituting real measurement data with simulated data. By leveraging these advancements, this research contributes to the development of a robust and reliable tool wear prediction system, which not only improves manufacturing efficiency but also reduces operational costs in the future. • Novel grey-box modeling approach combining finite element method and machine learning. • 3D finite element model accounts for multiple derived tool wear states. • Machine learning predicts flank wear width from acoustic emission alone or combined with simulated cutting forces. • Combining simulation and machine learning improves tool wear prediction accuracy.

Topics & Concepts

Finite element methodTool wearMachine learningMachine toolProcess (computing)Boosting (machine learning)Artificial intelligenceGradient boostingComputer scienceMachiningBridge (graph theory)Cutting toolExtreme learning machineMechanical engineeringExperimental dataSupport vector machinePredictive modellingFlankProcess modelingAcoustic emissionArtificial neural networkEngineeringComputational learning theoryEnsemble learningAlgorithmAdvanced machining processes and optimizationAdvanced Machining and Optimization TechniquesMetal Alloys Wear and Properties