A multiphysics model to predict the surface integrity of EDM machined parts

Adnene Tlili; Farhat Ghanem

doi:10.1051/mattech/2023046

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Volume 112 / No 3 (2024)

Matériaux & Techniques, 112 3 (2024) 305

Abstract

Special Issue on ‘Non-Conventional Machining Processes’, edited by Sami Chatti, Naoufel Ben Moussa, Yessine Ayed, Farhat Ghanem, Guénaël Germain and Wacef Ben Salem

Issue		Matériaux & Techniques Volume 112, Number 3, 2024 Special Issue on ‘Non-Conventional Machining Processes’, edited by Sami Chatti, Naoufel Ben Moussa, Yessine Ayed, Farhat Ghanem, Guénaël Germain and Wacef Ben Salem


Article Number		305
Number of page(s)		13
Section		Modelling and simulation: materials processing, numerical twins, numerical materials
DOI		https://doi.org/10.1051/mattech/2023046
Published online		14 May 2024

Matériaux & Techniques 112, 305 (2024)

Original Article

A multiphysics model to predict the surface integrity of EDM machined parts

Adnene Tlili¹^,2^a^,* and Farhat Ghanem²^a

¹ Higher Institute of Technological Studies of Nabeul, Department of Mechanical Engineering, University Campus, Mrezgua, 8000, Nabeul, Tunisia
² Laboratoire de Mécanique, Matériaux et Procédés, ENSIT, 5 Avenue Taha Hussein Montfleury, 1008, Tunis, Tunisia

^* e-mail: adnen.tlili@nabeul.r-iset.tn
^a These authors contributed equally to this work.

Received: 31 August 2023
Accepted: 11 December 2023

Abstract

This study presented a numerical methodology to elucidate the local mechanical response of the surface layer during and after an EDM electrical discharge, aiming to refine the numerical prediction of the residual stress and strain hardening induced by this process. Advances in models, loads, and boundary conditions were proposed and simulated using the ABAQUS/Explicit computational software. A coherent thermomechanical model was formulated, incorporating Grüneisen’s hydrodynamic behavior coupled with the Johnson-Cook plasticity model. Numerical findings highlighted the efficiency of the uniform heat flux distribution model in predicting residual stresses accurately.

Key words: EDM / numerical model / residual stress / numerical simulation / AISI 316L

© SCF, 2024

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