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Improvement of thermomechanical full-field analysis of metallic polycrystals using crystallographic data

Mechanics & Industry 2012 5 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 20 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Rian Seghir, Éric Charkaluk Éric Charkaluk Jean‐François Witz, Éric Charkaluk Rian Seghir, Rian Seghir, Éric Charkaluk Éric Charkaluk Jean‐François Witz, Jean‐François Witz, Jean‐François Witz, Philippe Dufrénoy, Philippe Dufrénoy, Philippe Dufrénoy, Éric Charkaluk

Summary

This paper improved intragranular thermomechanical analysis of metallic polycrystals by applying a crystallography-based projection technique to map thermal and displacement fields onto a polynomial basis consistent with grain orientations. The method enabled coupled analysis of strain and temperature at the grain scale in an AISI 316L steel specimen.

This paper is based on additional treatments of the experimental results obtained by L. Bodelot, L. Sabatier, E. Charkaluk, P. Dufrénoy [Experimental setup for fully coupled kinematic and thermal measurements at the microstructure scale of an AISI 316l steel, Mater. Sci. Eng. A 501 (2009) 52–60]. In order to perform inter- and intragranular thermomechanical analyses in a metallic polycrystal at the grain scale, a crystallography-based projection technique of the thermal and displacement fields on a polynomial basis is proposed. It enables intragranular coupled analysis of strain and temperature full-field data consistent with the plastic slip activation observed on specimen surface after the test.

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