Formation of submicrocrystalline structure in titanium and titanium alloys and their mechanical properties

Салищев, Г. А.; Galeev, R. M.; Malysheva, S. P.; Zherebtsov, Sergey; Mironov, S.; Valiakhmetov, O. R.; Ivanisenko, É. I.

doi:10.1007/s11041-006-0045-7

Cited by 36 publications

(28 citation statements)

References 6 publications

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“…Figure 4 shows SEM images and elemental concentration maps of a polished cross section of the f-TiZr alloy, which was cut from a forged cylinder that was 20 mm in diameter. The very fine metallographic textures shown in these images should be effective to increase the hardness and strength of the metal [14], which has been repeatedly confirmed by previous studies, including those of Ti-based alloy systems [15][16][17][18]. This is also shown in our measurements of micro-Vickers hardness of the f-TiZr alloy at Hv = 339, which is significantly higher than that of non-forged Ti60Zr40 or Ti70Zr30 alloy with Hv = 230~280 [19].…”

Section: Figuresupporting

confidence: 89%

Forge-Hardened TiZr Null-Matrix Alloy for Neutron Scattering under Extreme Conditions

Okuchi

Hoshikawa²,

Ishigaki³

2015

Metals

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For neutron scattering research that is performed under extreme conditions, such as high static pressures, high-strength metals that are transparent to the neutron beam are required. The diffraction of the neutron beam by the metal, which follows Bragg's law, can be completely removed by alloying two metallic elements that have coherent scattering lengths with opposite signs. An alloy of Ti and Zr, which is known as a TiZr null-matrix alloy, is an ideal combination for such purposes. In this study, we increased the hardness of a TiZr null-matrix alloy via extensive mechanical deformation at high temperatures. We successfully used the resulting product in a high-pressure cell designed for high-static-pressure neutron scattering. This hardened TiZr null-matrix alloy may play a complementary role to normal TiZr alloy in future neutron scattering research under extreme conditions.

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Section: Figuresupporting

confidence: 89%

Forge-Hardened TiZr Null-Matrix Alloy for Neutron Scattering under Extreme Conditions

Okuchi

Hoshikawa²,

Ishigaki³

2015

Metals

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“…All most widely spread methods of the ultrafine-grained structure formation in metallic materials are based on Severe Plastic Deformation (SPD). The use of the SPD methods enables the sizes of the structural elements in the material to be decreased down to the nanolevel and, as a consequence, the strength characteristics to be increased by a factor of 1.5-2 [4][5][6][7]. At the same time, the rate of hydrogen absorption by metallic materials is known to be increased with decreasing grain sizes.…”

Section: Introductionmentioning

confidence: 99%

“…At the same time, the rate of hydrogen absorption by metallic materials is known to be increased with decreasing grain sizes. Therefore, the prospects for the application of the UFG polycrystals as structural materials will largely be determined by the effect of hydrogen on the structural and phase state [5][6][7][8]. While penetrating into material, hydrogen produces a wide range of defects, such as vacancy clusters, and reacts with the existing ones, forming the so-called "defect-hydrogen" systems.…”

Section: Introductionmentioning

confidence: 99%

Effect of hydrogen on the structural and phase state and defect structure of titanium alloy

Stepanova¹,

Bordulev²,

Kudiiarov³

et al. 2016

AIP Conference Proceedings

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“…Severe plastic deformation methods [5][6][7] promote the production of ultra-fine grained semi-finished billets (blocks) and products with significantly high mechanical properties in comparison to their coarse-grained analogues. Usually, the nanostructured phase , ultra-fine grain in metals and alloys is attained by combining two or more different intensive plastic deformation methods [5,[8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Microstructure and Grain Characteristics of Ti Nb40 Biological Implant Alloy

Zhu¹,

Sun²,

Zhang³

et al. 2015

Proceedings of the 5th International Conference on Civil Engineering and Transportation 2015

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Abstract. This paper focuses on the development of microstructure of TiNb 40 alloy after severe plastic deformation. Primary billets (blocks) are Ti alloy cast with 40% Nb mass which are exposed to a combined two-stages severe plastic deformation method, including abc-pressing and multi-pass rolling in grooved rolls . An area of less than 0.3 micron grains is about 6% of the total area. It plays a strong role for improving the strength of the material. Microhardness of the alloy increased to 2300MPa. The small-angle grain boundaries (less than 15 °) of the alloy account for 61.1% after the combined processing . It is shown that a relatively large amount of micron grains and subgrains were produced in the processing of the alloy.

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Formation of submicrocrystalline structure in titanium and titanium alloys and their mechanical properties

Cited by 36 publications

References 6 publications

Forge-Hardened TiZr Null-Matrix Alloy for Neutron Scattering under Extreme Conditions

Forge-Hardened TiZr Null-Matrix Alloy for Neutron Scattering under Extreme Conditions

Effect of hydrogen on the structural and phase state and defect structure of titanium alloy

Microstructure and Grain Characteristics of Ti Nb40 Biological Implant Alloy

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