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Thesis
Home   /   Thesis   /   Study of the influence of the microstructure of a 316L steel produced by the L-PBF process on its mechanical properties: characterization and modeling of creep and fatigue behavior

Study of the influence of the microstructure of a 316L steel produced by the L-PBF process on its mechanical properties: characterization and modeling of creep and fatigue behavior

Condensed matter physics, chemistry & nanosciences Engineering sciences Mechanics, energetics, process engineering Ultra-divided matter, Physical sciences for materials

Abstract

Research into additive manufacturing for the nuclear industry shows that the production of 316L austenitic steel components using laser powder bed fusion (L-PBF) presents technical challenges, including process control, material properties, qualification and prediction of mechanical behaviour under service conditions. The final properties differ from traditional processes, often exhibiting anisotropy that challenges existing design standards.
These differences are linked to the unique microstructure resulting from the L-PBF process. Controlling the manufacturing chain, from consolidation to qualification, requires an understanding of the interactions between process parameters, microstructure and mechanical properties.
The aim of this thesis is to study the relationships between the microstructure, texture and mechanical properties of 316L steel manufactured by the L-PBF process, under static or cyclic loading. This includes the influence on creep and fatigue properties, and the development of a model to predict mechanical behaviour. Using samples of 316L steel with specific microstructures consolidated by L-PBF, the proposed study aims to establish links between microstructure and mechanical properties to better predict in-service behaviour.

Laboratory

Département de Recherche sur les Matériaux et la Physico-chimie pour les énergies bas carbone
Service de Recherche en Matériaux et procédés Avancés
Laboratoire de Technologie des Matériaux Extrêmes
Paris-Saclay
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