Impact of the initial microstructure and the loading conditions on the deformation behavior of the Ti17 titanium alloy

Boubaker, Houssem Ben; Mareau, Charles; Ayed, Yessine; Germain, Guénaël; Tidu, Albert

doi:10.1007/s10853-019-04014-5

Cited by 10 publications

(7 citation statements)

References 50 publications

(56 reference statements)

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“…At the strain rate of 1000 s −1 , multiple deformation mechanisms were comprehensively investigated in Ti-25Nb-3Zr-3Mo-2Sn, presenting the dynamic deformation sequences as {332}<113> and {112}<111> mechanical twining + stress-induced α” and ω phase transformations + dislocation slip at 293K → {332}<113> and {112}<111> mechanical twining + dislocation slip at 573K → dislocation slip only at 873 K [ 29 ]. The softening behavior of dual-phase Ti17 alloy (Ti-5Al-4Cr-4Mo-2Sn-2Zr) at a high temperature is attributed to the combinations of dynamic recrystallization, dynamic transformation, adiabatic heating, and morphological texture evolution [ 30 ]. Instead of thermal softening mechanisms, the microstructure evolutions or transformations play an important role in the initiation of ASB [ 21 , 24 , 31 , 32 , 33 ].…”

Section: Introductionmentioning

confidence: 99%

Effect of High Strain Rate on Adiabatic Shearing of α+β Dual-Phase Ti Alloy

Fang

et al. 2021

Materials

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In the present work, the localized features of adiabatic shear bands (ASBs) of our recently designed damage tolerance α+β dual-phase Ti alloy are investigated by the integration of electron backscattering diffraction and experimental and theoretical Schmid factor analysis. At the strain rate of 1.8 × 104 s−1 induced by a split Hopkinson pressure bar, the shear stress reaches a maximum of 1951 MPa with the shear strain of 1.27. It is found that the α+β dual-phase colony structures mediate the extensive plastic deformations along α/β phase boundaries, contributing to the formations of ASBs, microvoids, and cracks, and resulting in stable and unstable softening behaviors. Moreover, the dynamic recrystallization yields the dispersion of a great amount of fine α grains along the shearing paths and in the ASBs, promoting the softening and shear localization. On the contrary, low-angle grain boundaries present good resistance to the formation of cracks and the thermal softening, while the non-basal slipping dramatically contributes to the strain hardening, supporting the promising approaches to fabricate the advanced damage tolerance dual-phase Ti alloy.

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Section: Introductionmentioning

confidence: 99%

Effect of High Strain Rate on Adiabatic Shearing of α+β Dual-Phase Ti Alloy

Fang

et al. 2021

Materials

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“…The experimental procedure used for such tests is briefly described here. A detailed description of the experimental setup can be found in Ben-Boubaker et al (2020).…”

Section: Summary Of Experimental Resultsmentioning

confidence: 99%

“…For low temperatures (𝑇 ≤ 450 • C), the maximum error between the experimental and numerical curves does not exceed 6%. For temperatures above 700 • C, a yield drop phenomenon, which is attributed to either dynamic recrystallization Ben-Boubaker et al (2020) or the multiplication of mobile dislocations Teixeira et al (2007), is observed. This phenomenon is partly captured by the proposed model.…”

Section: Viscoplastic and Hardening Parameters Of The 𝛽 Phasementioning

confidence: 99%

A crystal plasticity-based constitutive model for near-β titanium alloys under extreme loading conditions: Application to the Ti17 alloy

Boubaker

Mareau

Ayed

et al. 2022

Mechanics of Materials

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“…In order to develop the advanced Ti alloys integrated the damage tolerance and high strength properties, a great amount of efforts have been completed investigating the high-strain rate shear behaviours of α Ti (Shahan and Taheri, 1993;Meyers et al, 1994;Chichili et al, 1998;Yang and Wang, 2006;Wang et al, 2007;Yang et al, 2010;Jiang et al, 2015;Kuang et al, 2017), Ti-6Al-4V alloy (Me-Bar andShechtman, 1983;Grebe et al, 1985;Da Silva and Ramesh, 1997;Lee and Lin, 1998;Timothy and Hutchings, 2013;Sun et al, 2014a;b;Mendoza et al, 2015;Zhou et al, 2017), TC16 (Wang, 2008), near-β Ti5551 (Ran and Chen, 2018) and Ti5553 (Yan and Jin, 2020), β ones (Zhan et al, 2016), α + β dual-phase ones (Yang et al, 2011b;Mantri et al, 2018;Ben Boubaker et al, 2019;Danard et al, 2019;Kloenne et al, 2020;Lee et al, 2020), and so on. It is worth mentioning that the dual-phase materials (Wu et al, 2017;Hao et al, 2021;Zou et al, 2021) always present ultra-strong and ductile behaviors combining the solid solution strengthening, grain refinement effect, and precipitation hardening, which could excellently deal with the planar-defects-dominated plastic deformation behaviors (Hao et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…The traditional wellaccepted thermal-softening mechanism of ASB should be double checked, calling for more research efforts to reveal the microstructure evolutions resulting in the local softening (Guo et al, 2019). Therefore, it is necessary to reveal their corresponding softening mechanisms, including the dynamic recrystallization, dynamic transformation, adiabatic heating, and morphologies texture evolution (Yang and Wang, 2006;Rittel et al, 2008;Osovski et al, 2012;Li et al, 2017;Lieou and Bronkhorst, 2018;Ben Boubaker et al, 2019;Hao et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Effect of High Strain Rates on Adiabatic Shear Bands Evolution and Mechanical Performance of Dual-Phase Ti Alloy

Fang

Wang

et al. 2022

Front. Mater.

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In the present work, the adiabatic shear characteristics of our recently designed α + β dual-phase Ti alloy at different strain rates have been investigated by hat shaped specimen. The deformation process is divided into three stages: work hardening stage, steady stage, and unstable thermal softening stage. Along or near the shear deformation paths, the microvoids and the cracks can be captured at the strain rate of 1.8 × 104 s−1, 2.0 × 104 s−1, and 2.3 × 104 s−1, both of which contribute to the stable and unstable softening. It is found that dynamic stored energy of cold work will be significantly improved by the enhanced high strain rate. In the view of coupling analysis of inverse pole figure and grain boundary map, it seems that low angle grain boundaries present a good resistance to the formation of cracks and thermal softening. On the contrary, high angles grain boundaries are typically located in ASBs and their affecting regions, which is in line with the reported results. While the geometrical necessary dislocation (GND) density of adiabatic shear band (ASB) and its surroundings increased significantly, the width of the ASB becomes wider as the strain rate increases, which is consistent with the theory of sub-grain rotation dynamic recrystallization model. The formation of multiple ASBs in the corner position is schematically illustrated and the average elastic modulus and hardness of the ASB region are lower than the α and β phases, combined with the GND analysis, which proves that the ASB is a thermal softening zone in this experiment.

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Impact of the initial microstructure and the loading conditions on the deformation behavior of the Ti17 titanium alloy

Cited by 10 publications

References 50 publications

Effect of High Strain Rate on Adiabatic Shearing of α+β Dual-Phase Ti Alloy

Effect of High Strain Rate on Adiabatic Shearing of α+β Dual-Phase Ti Alloy

A crystal plasticity-based constitutive model for near-β titanium alloys under extreme loading conditions: Application to the Ti17 alloy

Effect of High Strain Rates on Adiabatic Shear Bands Evolution and Mechanical Performance of Dual-Phase Ti Alloy

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