Quantitative Anisotropic Damage Mechanism in a Forged Aluminum Alloy Studied by Synchrotron Tomography and Finite Element Simulations

• Published in: Advances in materials science and engineering Vol. 2019; no. 2019; pp. 1 - 12
• Main Authors: Helfen, Lukas, Allais, Lucien, Garnier, Jérôme, Morgeneyer, Thilo F., Shen, Yang, Crépin, Jérôme
• Format: Journal Article
• Language: English
• Published: Cairo, Egypt Hindawi Publishing Corporation 2019; Hindawi; Hindawi Limited; Wiley
• Subjects: Alloys; Aluminum alloys; Aluminum base alloys; Anisotropy; Computed tomography; Computer simulation; Configurations; Crack initiation; Crack propagation; Damage; Damage assessment; Engineering; Engineering Sciences; Finite element method; Forging; Fracture mechanics; Fracture toughness; Ligaments; Materials; Materials and structures in mechanics; Materials science; Mechanical engineering; Mechanical properties; Mechanics; Mechanics of materials; Microstructural analysis; Precipitates; Propagation; Stress state; Structural mechanics; Synchrotron radiation
• ISSN: 1687-8434; 1687-8442
• DOI: 10.1155/2019/8739419

A highly anisotropic toughness behavior has been revealed on a forged AA6061 aluminum alloy by toughness tests with CT specimens. The toughness values with specimens loaded on the longitudinal direction are larger than that loaded on the transverse direction due to the anisotropic shape and distribution of coarse precipitates induced by the morphological anisotropy of grains during forging process. Synchrotron radiation computed tomography analysis on as-received material and arrested cracks revealed different fracture modes for the two loading configurations. The damage mechanism has been validated by finite element simulations based on the Gurson–Tvergaard–Needleman micromechanical damage model with different sets of damage parameters for the two loading configurations obtained from quantitative void volume fraction analysis on SRCT data, in situ SEM experiments, and SRCT microstructural analysis.