Hybrid approaches for sheet metal formability prediction: A synergy of experimental, numerical and machine learning tools

Authors

  • Mounir Trabelsi Higher Institute of Technological Studies of Sfax, Route de Tunis km 10, B.P. 261, 3031 Sfax, Tunisia
  • Boutheina B. Fraj Nanomaterials and Systems for Renewable Energy Laboratory, Research and Technology Center of Energy, Technopole Borj Cedria, B.P. 95, 2050 Hammam Lif, Tunisia
  • Hamdi Hentati Higher School of Sciences and Technology of Hammam Sousse (ESSTHS), University of Sousse, Rue Lamine Abassi, 4011 Sousse, Tunisia
  • Taoufik Kamoun Higher Institute of Technological Studies of Sfax, Route de Tunis km 10, B.P. 261, 3031 Sfax, Tunisia
  • Mounir B. Amar Laboratory of Process and Materials Sciences (LSPM), CNRS, Sorbonne Paris Nord University, 99 Avenue Jean Baptiste Clément, 93430 Villetaneuse, France
  • Mohamed Haddar LA2MP Laboratory, National School of Engineers of Sfax, University of Sfax, B.P. 1173, 3038 Sfax, Tunisia

DOI:

https://doi.org/10.15282/jmes.19.4.2025.3.0851

Keywords:

Forming tests, Sheet metal, Microstructural analysis, Plasticity and damage models, Machine learning

Abstract

The optimization of sheet metal forming processes is a main goal in the mechanical industry, particularly in the widely used drawing technique. However, the lack of material databases concerning metal ductility presents significant challenges. To address this issue, this study develops machine learning (ML) methods to optimize the sheet metal forming process. The Erichsen cupping tests are employed to evaluate the formability and damage characteristics of A36 sheet parts, aiming for successful drawing outcomes. These tests consider three key parameters: punch diameter, friction between tools and sheet metal, and sheet thickness. Experimental findings show that punch diameter greatly affects the Erichsen index (IE). Microstructural analysis reveals a notable impact of sheet thickness on the maximum punch force (Fmax), which is further confirmed by X-ray diffraction analysis. A finite element (FE) model based on the Johnson–Cook material law is developed to simulate the deep drawing tests. Numerical predictions show good agreement with experiments, with an average error of less than 4% for IE and 5% for Fmax. By comparing numerical and experimental results, the isotropic model demonstrates satisfying and consistent performance. Using both experimental and numerical datasets, ML models are trained to predict IE and Fmax. Among the tested algorithms (LR, RF, DT, SVR, and XGB), XGBoost (XGB) provides the most accurate predictions, with R² values of 99.60% for IE and 97.46% for Fmax. The results indicate that XGB offers a robust and efficient approach for optimizing sheet metal forming processes through accurate prediction of formability and damage indicators.

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Published

2025-12-29

Issue

Volume 19 No. 4, (December 2025)

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Article

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How to Cite

[1]
M. Trabelsi, B. B. Fraj, H. Hentati, T. Kamoun, M. B. Amar, and Mohamed Haddar, “Hybrid approaches for sheet metal formability prediction: A synergy of experimental, numerical and machine learning tools”, J. Mech. Eng. Sci., vol. 19, no. 4, pp. 10863–10876, Dec. 2025, doi: 10.15282/jmes.19.4.2025.3.0851.

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