Fabrication of an Ultra-Fine Grained Pure Titanium with High Strength and Good Ductility via ECAP plus Cold Rolling

Wu, Haoran; Jiang, Jinghua; Liu, Huan; Sun, Jiapeng; Gu, Yuanzheng; Ren, Tongjun; Zhao, Xincan; Ma, Aibin

doi:10.3390/met7120563

Cited by 20 publications

(20 citation statements)

References 44 publications

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“…However, the addition of lithium to the magnesium alloy forming Mg-Li alloy results in the formation of a β-rich Li phase which greatly increases the dislocation slip system and improves the plastic deformation ability of the Mg-Li alloys [26]. The results obtained from the reported research [27,28] show that, the use of rolling technique leads to an improvement in the strength properties of the Mg-Li alloy, activate more slip systems, enhance the ability of intergranular co-opening and improve the ability of plastic deformation at room temperature (RT). In the rolling process, strong basal texture will be formed [29].…”

Section: Introductionmentioning

confidence: 77%

Development of a High Strength Mg-9Li Alloy via Multi-Pass ECAP and Post-Rolling

Klu

Song

et al. 2019

Metals

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In this study, a high-strength Mg-9Li alloy was developed via multi-pass equal-channel-angular-pressing (ECAP) and post rolling, of which the yield tensile stress (YTS) and ultimate tensile stress (UTS) were 166 MPa and 174 MPa representing about 219% and 70% increase in YTS and UTS respectively, compared to the cast alloy. The cast alloy was ECAP processed at 200 °C for 4, 8, and 16 passes, followed by room-temperature rolling to a total thickness reduction of 50%. The 8-passes ECAPed (E8) alloy presented the best strength of all the ECAPed alloys, and the post rolling endowed the alloy (E8R) further strengthening and the best strength of all the alloys. Grain-boundary strengthening and dislocation strengthening were the two major factors for the high strength of the processed alloys. The α-Mg phase grains were greatly refined to about 2 μm after 8-passes ECAP, and was further refined to about 800 nm ~1.5 μm after rolling. Significant grain refinement endowed the alloy with sufficient grain-boundary strengthening. Profuse intragranular dislocation accumulated in the deformed matrix, leading to the significant dislocation hardening of the alloy. Rolling-induced strong basal texture of the α-Mg phase also enhanced the further strengthening of the E8R alloy.

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Section: Introductionmentioning

confidence: 77%

Development of a High Strength Mg-9Li Alloy via Multi-Pass ECAP and Post-Rolling

Klu

Song

et al. 2019

Metals

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“…The PM samples were pressed for 0, 4 and 8 ECAP passes (marked as PM-0p-ECAP, PM-4p-ECAP and PM-8p-ECAP) with a velocity of 0.5 mm/s at 703 K. Prior to ECAP, cubic PM samples (20 mm × 20 mm × 40 mm) were put into the ECAP die, and they were held at 703 K for 15 min before pressing. This RD-ECAP procedure was proven to be very effective to obtain ultrafine-grained microstructure in several materials [33,34,[37][38][39]. Graphite was used as a lubricant to reduce the friction between the billet and the inner wall of the die.…”

Section: Composite Fabrication and Processingmentioning

confidence: 99%

“…The compaction pressure, which has a significant influence on the compactness and properties of the final composite [31], was chosen to be 305 MP, which gives rise to a large apparent density of 2.56-2.58 g cm −3 . Then, the cold pressed specimens buried by graphite were sintered in a furnace at 873 K for 4 h. Finally, the PM samples were processed using a home-made rotary die for ECAP (RD-ECAP) with 90 • channel intersection, the operation principle of which can be found in our earlier work [32][33][34][35][36]. The PM samples were pressed for 0, 4 and 8 ECAP passes (marked as PM-0p-ECAP, PM-4p-ECAP and PM-8p-ECAP) with a velocity of 0.5 mm/s at 703 K. Prior to ECAP, cubic PM samples (20 mm × 20 mm × 40 mm) were put into the ECAP die, and they were held at 703 K for 15 min before pressing.…”

Section: Composite Fabrication and Processingmentioning

confidence: 99%

Development of High-Performance SiCp/Al-Si Composites by Equal Channel Angular Pressing

Wang

et al. 2018

Metals

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Relatively low compactness and unsatisfactory uniformity of reinforced particles severely restrict the performance and widespread industry applications of the powder metallurgy (PM) metal matrix composites (MMCs). Here, we developed a combined processing route of PM and equal channel angular pressing (ECAP) to enhance the mechanical properties and wear resistance of the SiC p /Al-Si composite. The results indicate that ECAP significantly refined the matrix grains, eliminated pores and promoted the uniformity of the reinforcement particles. After 8p-ECAP, the SiC p /Al-Si composite consisted of ultrafine Al matrix grains (600 nm) modified by uniformly-dispersed Si and SiC p particles, and the composite relative density approached 100%. The hardness and wear resistance of the 8p-ECAP SiC p /Al-Si composite were markedly improved compared to the PM composite. More ECAP passes continued a trend of improvement for the wear resistance and hardness. Moreover, while abrasion and delamination dominated the wear of PM composites, less severe adhesive wear and fatigue mechanisms played more important roles in the wear of PM-ECAP composites. This study demonstrates a new approach to designing wear-resistant Al-MMCs and is readily applicable to other Al-MMCs.nanostructured Al/SiC-graphite composite by accumulative roll bonding (ARB) and showed that a homogeneous ultra-fine grain structure and uniform distribution of particles could be obtained by eight ARB cycles. Haghighi et al. [18] revealed that the Al-5 vol.% nano-Al 2 O 3 composite consolidated by equal channel angular pressing (ECAP) possessed higher mechanical properties and hardness. In addition, twist extrusion (TE), as a potent tool for obtaining advanced engineering materials, can be used to improve the mechanical and tribological properties of MMCs [22,23].The tribological property is crucial to components sustaining wear. As important wear-resistant materials, Al-MMSs have been employed for vehicle discs. The optimized microstructure, especially the refined matrix grains, and improved mechanical properties of Al-MMCs by SPD lead to enhanced wear resistance. It was suggested that through the grain refinement, the wear-resistance of MMCs and some alloys can be improved to follow a linear relation with the d −0.5 (d is the average grain size), resembling the Hall-Petch effect [24][25][26][27]. However, there have been very limited reports in the literature dealing with the wear behavior of SPD-MMCs up to date, and among a few publications, there were conflicting results reported. Haghighi et al. [18,28] compared the Al-MMCs processed by ECAP or conventional extrusion and concluded that the ECAP samples possessed better wear resistance than the extruded counterparts. The improved wear resistance was attributed to pore elimination, homogeneity of the particle distribution and grain refinement by the ECAP. Similarly, enhanced wear resistance of Al-MMCs by ARB was reported by Darmiani [29]. However, decreased wear resistance was also reported by Jamaati et al. [26], who...

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Section: Introductionmentioning

confidence: 99%

“…Another method is to combine the SPD process with cold working. It has already been proven that the combination of processes can lead to even higher mechanical properties than in the case of purely SPD processing [20][21][22][23]. This paper deals with the development of continuous technology for commercially pure titanium (titanium Grade 4) processing combining Conform SPD and rotary swaging leading to highstrength wire production.…”

Section: Introductionmentioning

confidence: 99%

Continuous Production of Pure Titanium with Ultrafine to Nanocrystalline Microstructure

et al. 2020

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This work deals with the application of the Conform SPD (Severe Plastic Deformation) continuous extrusion process for ultrafine to nanostructured pure titanium production. The process has been derived from the Equal Channel Angular Pressing (ECAP) technique but, unlike ECAP, it offers continuous production of high-strength wire. This study describes the Conform SPD process combined with subsequent cold working (rotary swaging technique), its potential for commercial application, and the properties of high-strength wires of pure titanium. High-strength wire of titanium Grade 4 is the product. Titanium Grade 4 reaches ultimate strengths up to 1320 MPa. This value is more than twice the ultimate strength of the unprocessed material. The typical grain size upon processing ranges from 200 to 500 nm. Process development supported by FEM analysis together with detailed microstructure characterization accompanied by mechanical properties investigation is presented.

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Fabrication of an Ultra-Fine Grained Pure Titanium with High Strength and Good Ductility via ECAP plus Cold Rolling

Cited by 20 publications

References 44 publications

Development of a High Strength Mg-9Li Alloy via Multi-Pass ECAP and Post-Rolling

Development of a High Strength Mg-9Li Alloy via Multi-Pass ECAP and Post-Rolling

Development of High-Performance SiCp/Al-Si Composites by Equal Channel Angular Pressing

Continuous Production of Pure Titanium with Ultrafine to Nanocrystalline Microstructure

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