Grain refinement of pure Ti during plastic deformation

Wu, Shijing; Fan, Kaifa; Jiang, Ping; Chen, Shaohua

doi:10.1016/j.msea.2010.06.085

Cited by 24 publications

(11 citation statements)

References 34 publications

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“…The cell structure can be considered as a 'precursor' of the eventually developing grain structure, as have been experimentally observed in the UFG microstructures pro duced by the SPD processes [5,7,[31][32][33][34][35][37][38][39]50]. The cell structure can be considered as a 'precursor' of the eventually developing grain structure, as have been experimentally observed in the UFG microstructures pro duced by the SPD processes [5,7,[31][32][33][34][35][37][38][39]50].…”

Section: Determination Of Materials Parametersmentioning

confidence: 70%

“…Figure 1 shows the transmission electron micro scope (TEM) images of CP Ti workpieces produced by (a) and (b) orthogonal cutting [5], (c) and (d) multipass cold rolling [31], (e) ten-pass ECAP plus cold rolling with 77% thickness reduction [32], (/) two-pass ECAP [33], (g) multipass hydrostatic extrusion [34] and (h) surface mechanical attrition treatment (SMAT) proc esses [35], Figure 1(a) shows a TEM micrograph of a chip machined with the +20 deg rake angle tool, which microstructure consists of sub-lOOnm dislocation cells/grains interspersed with elongated, less developed subgrain structures. A dislocation cell structure with high dislocation den sity is often observed in CP Ti workpieces treated by a variety of SPD processes.…”

Section: Grain Refinement Of Cp Ti Through Spdmentioning

confidence: 99%

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Dislocation Density-Based Grain Refinement Modeling of Orthogonal Cutting of Titanium

Ding

Shin

2014

Journal of Manufacturing Science and Engineering

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D is lo c a tio n D e n s ity -B a s e d G rain R e fin e m e n t M o d e lin g of O rth o g o n al C utting of T ita n iu mRecently, orthogonal cutting has been exploited as a means for producing ultrafine grained (UFG) and nanocrystalline microstructures for various metal materials, such as aluminum alloys, copper, stainless steel, titanium and nickel-based super alloys, etc. However, no predictive, analytical or numerical work has ever been presented to quanti tatively predict the change of grain sizes during plane-strain orthogonal cutting. In this paper, a dislocation density-based material plasticity model is adapted for modeling the grain size refinement mechanism during orthogonal cutting by means of a finite element based numerical framework. A coupled Eulerian-Lagrangian (CEL) finite element model embedded with the dislocation density subroutine is developed to model the severe plastic deformation and grain refinement during a steady-state cutting process. The orthogonal cutting tests o f a commercially pure titanium (CP Ti) material are simulated in order to assess the validity of the numerical solution through comparison with experiments. The dislocation density-based material plasticity model is calibrated to reproduce the observed material constitutive mechanical behavior of CP Ti under various strains, strain rates, and temperatures in the cutting process. It is shown that the developed model cap tures the essential features of the material mechanical behavior and predicts a grain size o f100-160 nm in the chips of CP Ti at a cutting speed oflOmmls.

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Section: Determination Of Materials Parametersmentioning

confidence: 70%

Section: Grain Refinement Of Cp Ti Through Spdmentioning

confidence: 99%

Dislocation Density-Based Grain Refinement Modeling of Orthogonal Cutting of Titanium

Ding

Shin

2014

Journal of Manufacturing Science and Engineering

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“…The mechanism of DRX may be classified into migrational and rotational types [39] where it was reported that primarily migrational DRX operates in metals subjected to static deformation or low strain rate dynamic deformation [27,40,41]. Nevertheless, in deformation at very high strain rates, there is insufficient time for long-range migration of the boundaries so that the DRX operates via the rotation of subgrain boundaries [40,42].…”

Section: The Recrystallization Mechanismmentioning

confidence: 99%

Temperature and strain rate dependence of microstructural evolution and dynamic mechanical behavior in nanocrystalline Ti

Zhang

Wang

Zhilyaev

et al. 2015

Materials Science and Engineering: A

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The mechanical behavior of commercial purity titanium with a nanocrystalline (NC) grain size was investigated using split Hopkinson pressure bar tests at high strain rates and over a range of temperatures. The study was accompanied by detailed microstructural investigations before and after compression testing. The results show that rotary dynamic recrystallization operates during compressive deformation at strain rates of ~3000 and ~4500 s -1 at temperatures from 298 to 573 K but cells form at 673 K. The dynamic mechanical behavior of NC Ti shows a strong dependence on temperature and strain rate such that the flow stress and the strain hardening rate both increase with increasing strain and decreasing temperature. A constitutive equation is derived to relate the flow stress to the temperature, strain rate and true strain and to predict the yield strength and the peak stress of NC Ti subjected to dynamic deformation at elevated temperatures.

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“…It has been demonstrated that dislocation motion and the value of the activation volume both vary with grain size during plastic deformation [46] and for CP Ti the magnitudes of V* were estimated as ~276b 3 , ~57b 3 and ~5b 3 for CG, UFG and NC Ti, respectively [47]. Although a reduction in grain size gives rise to an enhancement in stress, nevertheless this rise becomes less important when considering the drastic increase in the dislocation density in the coarser grains so that an increase in m with decrease in grain size is observed in the CP Ti.…”

Section: Strain Rate Sensitivitymentioning

confidence: 99%

Effect of grain size on compressive behaviour of titanium at different strain rates

Zhang¹,

Wang²,

Zhilyaev³

et al. 2015

Materials Science and Engineering: A

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Abstract:An investigation was conducted to evaluate the dependence on grain size of the compressive deformation of commercial purity (CP) Ti. Tests were performed at room temperature using grain sizes from coarse-grained CG (20 m) to ultrafine-grained UFG (500 nm) and nanocrystalline NC (90 nm) with testing strain rates in the range from 0.01 to 10 s -1 .The results show the flow stress and the strain rate sensitivity of CP Ti increase with decreasing grain size. Work hardening dominates at all strain rates in CG Ti but it balances with flow softening at 0.01 and 0.1 s -1 in UFG and NC Ti and there is obvious flow softening in these two materials at 10 s -1 .

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Grain refinement of pure Ti during plastic deformation

Cited by 24 publications

References 34 publications

Dislocation Density-Based Grain Refinement Modeling of Orthogonal Cutting of Titanium

Dislocation Density-Based Grain Refinement Modeling of Orthogonal Cutting of Titanium

Temperature and strain rate dependence of microstructural evolution and dynamic mechanical behavior in nanocrystalline Ti

Effect of grain size on compressive behaviour of titanium at different strain rates

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