A multi-scale analysis of the residual stresses developed in a single-phase alloy cylinder after quenching

Residual stresses, RSs, both at the macroscopic and microscopic scales, are developed during component manufacture. Knowing the magnitude of these stresses is crucial in structural design optimization. While determining the macroscopic residual stress, M-RS, by diffraction methods is well known, the calculation of the microscopic residual stress, m-RS, which varies from grain to grain in single-phase alloys is still a pending task. In this work, a multi-scale analysis to calculate both types of stresses in a single-phase alloy has been conducted for the first time using synchrotron radiation diffraction data and a compositematerial approach. This analysis, together with the results derived froma finite elementmodel, FEM, demonstrates the strong influence of the severity of thermal-mechanical treatments on the generation of a grain orientation dependent m-RS and, contrary to other kinds of m-RS (such as inmetal matrix composites, MMCs), its irreversible nature. It is also seen that, while it is possible to generate an appropriate M-RS for a given application (e. g.,a compressive surface stress), a strong and detrimental m-RS field may arise simultaneously. This can be the origin of local inter-granular cracking during service of components. (C) 2017 Elsevier Ltd. All rights reserved.