Investigation on the size and distribution effects of O phase on fracture properties of Ti2AlNb superalloy by using image-based crystal plasticity modeling

Ti2AlNb superalloy consisting of O-phase and B-phase often exhibits deformation heterogeneity and incompatibility due to the mechanical characteristics of phases. To study the size and distribution effects of the O-phase on the fracture properties of Ti2AlNb superalloy, three types of material with...

Full description

Saved in:
Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2021-02, Vol.805, p.140787, Article 140787
Main Authors: Fu, Yanqi, Lv, Manqian, Zhao, Qing, Zhang, Haiming, Cui, Zhenshan
Format: Article
Language:English
Subjects:
Backscattering
Crack propagation
Crystal plasticity modeling
Dual-phase superalloy
Electron imaging
Fracture characteristics
Heat treatment
Heterogeneity
Incompatibility
Intermetallic compounds
Mechanical properties
Microcracks
Partitioning
Phase distribution
Plastic deformation
Plastic properties
Shear stress
Strain hardening
Strain partitioning
Stress concentration
Stress propagation
Superalloys
Tensile properties
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Ti2AlNb superalloy consisting of O-phase and B-phase often exhibits deformation heterogeneity and incompatibility due to the mechanical characteristics of phases. To study the size and distribution effects of the O-phase on the fracture properties of Ti2AlNb superalloy, three types of material with different O-phase sizes and distributions were prepared through heat treatments, and the tensile properties of the heat-treatment samples were investigated. An image-based crystal plasticity model was built based on the backscattered electron images of the superalloy to probe the effects of O-phase size and distribution on stress, strain partitioning, and fracture. The strain hardening and fracture behaviors were discussed in terms of the strain partitioning between O-phase and B-phase, and the formation and propagation of micro-cracks, respectively, by combining the simulation and experimental results. Simulation results show the stress and strain partitioning between O/B phase interfaces increases with the increase of O-phase size, and micro-cracks are formed when the local stress concentration exceeds the critical value. The presence of micro-cracks imposes high shear stress on the neighboring B-phase matrix and promotes fast crack propagation through the B-phase matrix, resulting in cleavage fracture. Inversely, micro-cracks tips can be alleviated when the stress concentration at O/B phase interfaces can be relaxed by the plastic deformation of the B-phase matrix. The variation of stress and strain partitioning with deformation during plastic deformation shows that strain partitioning isn't related to O-phase size, but stress partitioning depends on it. Thus, the effects of O-phase size on fracture mainly depend on stress partitioning. This paper presents a meaningful method to model the phase distribution, and the effects of O-phase size and distribution on stress, strain partitioning, and fracture behavior are studied.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2021.140787