Mélodie Mandy scite author profile

In advanced high strength automotive steels, small amounts of diffusible hydrogen can lead to a deterioration of mechanical performances, especially a loss of ductility, in the simultaneous presence of internal stresses and of a sensitive microstructure. In the hot-dip galvanizing process, hydrogen is mainly absorbed during high temperature operations in hydrogen-containing atmospheres before hot-dipping when the solubility of hydrogen in steel is the highest. After hot-dipping, the metallic zinc-based coating can impede hydrogen diffusion out of the metal. As a result, an excess of diffusible hydrogen remains in the steel substrate and can subsequently lead to a possible embrittlement. In this contribution, the effects of the coating nature on the hydrogen diffusion of a 980 MPa dual phase steel (DP980) are investigated. The attention is focused on three Znbased coating alloys: galvanized (Zn-0.23%Al), galvannealed (Fe-Zn based on Zn-0.12%Al) and Zn1.2Al1.2Mg. The hydrogen permeability of the coatings is first assessed through degassing experiments at room temperature and highlights the tightness of all coatings at room temperature. Secondly, cyclic SAE J2334 corrosion testing is performed and enables to highlight a stronger corrosion of GI and GA samples with respect to Zn1.2Al1.2Mg-coated samples, which is however the sole coating that seems to promote a hydrogen uptake during corrosion experiment.

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Statistical Evaluation of Surface Roughness in Abrasive Flow Machining Process

Kohail

Mandy

Ahmed

2011

International Conference on Aerospace Sciences and Aviation Tec

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Abrasive flow machining (AFM) process is used in a wide range of applications to deburr, polish, radius edges, remove recast layers, and produce compressive residual stresses on the surface.The aim of the present work is to study the effects of the different process parameters, such as machining time, concentration and mesh size of abrasive, as well as media flow speed ... etc. on the produced surface roughness. A mathematical model to evaluate surface roughness has been presented using experimental design. This model is can be used for the prediction of the surface roughness. Comparisons between experimental and theoretical results are also presented.

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A Better Understanding of Hydrogen Trapping and Diffusion in Aluminized Press-Hardenable Steels

Krid¹,

Mandy²,

Grigorieva³

et al. 2023

Preprint

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Mélodie Mandy

Investigation of PVD thin films as hydrogen barriers in aluminized press hardened steels (PHS)

On the analysis of the simultaneous uptake and desorption of different isotopes of gaseous hydrogen by advanced high strength steels

Influence of Zn-based Coating Alloys on Hydrogen Diffusion and Corrosion Resistance in a DP Steel

Statistical Evaluation of Surface Roughness in Abrasive Flow Machining Process

A Better Understanding of Hydrogen Trapping and Diffusion in Aluminized Press-Hardenable Steels

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