Analysing the Interaction between Microscopic Deformation, Microstructure and Void Evolution of Near-α Titanium Alloys during Non-Superplastic Hot Deformation by an Integrated Crystal Plasticity Finite Element Model

Zhao, Jie; Wang, Kehuan; Lv, Liangxing; Wang, Liliang; Politis, Denis J.; Liu, Gang

doi:10.3390/ma15010294

Materials

2021

DOI: 10.3390/ma15010294

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Analysing the Interaction between Microscopic Deformation, Microstructure and Void Evolution of Near-α Titanium Alloys during Non-Superplastic Hot Deformation by an Integrated Crystal Plasticity Finite Element Model

Jie Zhao

Kehuan Wang

Liangxing Lv

et al.

Abstract: High-efficiency and low-cost hot forming technologies for titanium alloys have been developed for producing complex-shaped, thin-walled tubular components under non-superplastic forming conditions. Under these forming conditions, there exist complex and highly integrated material evolution processes including microscopic heterogeneous deformation, microstructure evolution and damage behaviour. This paper presents an integrated crystal plasticity finite element model of near-α titanium alloys during non-superpl… Show more

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2024

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Advances in Understanding the Evolution Mechanism of Micropore Defects in Metal Materials under External Loads

Liang,

Zhang,

Peng

et al. 2024

Metals

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Micropores are one of the critical factors affecting materials’ performance and service life. As the need for a deeper understanding of micropore evolution and damage mechanisms grows, assessing the mechanical properties of materials containing micropores and predicting the lifespan of related metal structural components becomes increasingly complex. This paper focuses on the evolution process, regularities, and research methods of micropores in metal materials. Based on recent research and practical applications, the key stages of micropore evolution are discussed, encompassing nucleation, growth, coalescence, collapse, interaction, and the influence of other microstructures. Firstly, the advantages and limitations of commonly used characterization methods such as scanning electron microscopy, transmission electron microscopy, and X-ray computed tomography are introduced in the study of micropore evolution. Subsequently, critical theoretical models for micropore evolution, such as the Gurson model and its extensions, are summarized. By using a multiscale approach combining the crystal plasticity finite element method, dislocation dynamics, and molecular dynamics, the factors influencing the micropore evolution, such as external stress conditions, internal microstructures, and micropore characteristics, are specifically elaborated, and the basic physical mechanisms of micropore evolution are analyzed. Finally, a comprehensive review and summary of current research trends and key findings are provided, and a forward-looking perspective on future research directions is presented.

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Advances in Understanding the Evolution Mechanism of Micropore Defects in Metal Materials under External Loads

Liang,

Zhang,

Peng

et al. 2024

Metals

View full text Add to dashboard Cite

show abstract

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Analysing the Interaction between Microscopic Deformation, Microstructure and Void Evolution of Near-α Titanium Alloys during Non-Superplastic Hot Deformation by an Integrated Crystal Plasticity Finite Element Model

Cited by 1 publication

References 48 publications

Advances in Understanding the Evolution Mechanism of Micropore Defects in Metal Materials under External Loads

Advances in Understanding the Evolution Mechanism of Micropore Defects in Metal Materials under External Loads

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