Microstructures and wear properties of surface treated Ti–36Nb–2Ta–3Zr–0.35O alloy by electron beam melting (EBM)

Chen, Zijin; Liu, Yong; Wu, Hong; Zhang, Weidong; Guo, Wei; Tang, Huiping; Liu, Nan

doi:10.1016/j.apsusc.2015.09.240

Cited by 20 publications

(6 citation statements)

References 39 publications

(38 reference statements)

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“…The gradient surface structure treated by impulse electron beam irradiation was revealed by other authors [36]. The first top layer showed re-melted nanostructured grains [37]. The second layer becomes a heat-effected zone and may have a different structure as reported by Chen et al [37].…”

Section: Morphology Microstructure and Phase Composition Of Tnzt Alloymentioning

confidence: 74%

“…The first top layer showed re-melted nanostructured grains [37]. The second layer becomes a heat-effected zone and may have a different structure as reported by Chen et al [37].…”

Section: Morphology Microstructure and Phase Composition Of Tnzt Alloymentioning

confidence: 80%

“…%) could be performed by the increasing processing time of the mechanical alloying. The effect of the processing parameters on the phase compositions and microstructural features of EBM treated Ti-36Nb-2Ta-3Zr-0.35O alloys was discussed by Chen et al [37]. It was observed that the scanning speed had increased the microstructural changes from the highly dispersed acicular α phase to the formation of cellular grains and α phase.…”

Section: Mechanical Propertiesmentioning

confidence: 99%

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New Ti–35Nb–7Zr–5Ta Alloy Manufacturing by Electron Beam Melting for Medical Application Followed by High Current Pulsed Electron Beam Treatment

Surmeneva

Grubova

Glukhova

et al. 2021

Metals

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High-current pulsed electron-beam (PEB) treatment was applied as a surface finishing procedure for Ti–35Nb–7Zr–5Ta (TNZT) alloy produced by electron beam melting (EBM). According to the XRD results the TNZT alloy samples before and after the PEB treatment have shown mainly the single body-centered cubic (bcc) β-phase microstructures. The crystallite size, dislocation density, and microstrain remain unchanged after the PEB treatment. The investigation of the texture coefficient at the different grazing angle revealed the evolution of the crystallite orientations at the re-melted zone formed at the top of the bulk samples after the PEB treatment. The top-view SEM micrographs of the TNZT samples treated by PEB exhibited the bcc β-phase grains with an average size of ~85 μm. TEM analysis of as-manufactured TNZT alloy revealed the presence of the equiaxed β-grains with the fine dispersion of nanocrystalline α and NbTi4 phases together with β-Ti twins. Meanwhile, the β phase regions free of α phase precipitation are observed in the microstructure after the PEB irradiation. Nanoindentation tests revealed that the surface mechanical properties of the melted zone were slightly improved. However, the elastic modulus and microhardness in the heat-affected zone and the deeper regions of the sample were not changed after the treatment. Moreover, the TNZT alloy in the bulk region manufactured by EBM displayed no significant change in the corrosion resistance after the PEB treatment. Hence, it can be concluded that the PEB irradiation is a viable approach to improve the surface topography of EBM-manufactured TNZT alloy, while the most important mechanical parameters remain unchanged.

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Section: Morphology Microstructure and Phase Composition Of Tnzt Alloymentioning

confidence: 74%

“…The first top layer showed re-melted nanostructured grains [37]. The second layer becomes a heat-effected zone and may have a different structure as reported by Chen et al [37].…”

Section: Morphology Microstructure and Phase Composition Of Tnzt Alloymentioning

confidence: 80%

Section: Mechanical Propertiesmentioning

confidence: 99%

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New Ti–35Nb–7Zr–5Ta Alloy Manufacturing by Electron Beam Melting for Medical Application Followed by High Current Pulsed Electron Beam Treatment

Surmeneva

Grubova

Glukhova

et al. 2021

Metals

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“…Accordingly, gum metal is a proper choice for biomedical purposes. [ 151 ] In 2015, Chen et al [ 152 ] employed EBM to surface treatment Ti–36Nb–2Ta–3Zr–0.35O samples. The authors stated that the EBM technique was an efficient way to modify the surface, which remarkably modified the wear resistance and surface hardness of the TNTZO alloy.…”

Section: Titanium Alloys Processabilitymentioning

confidence: 99%

Additive Manufacturing of Titanium Alloys: Processability, Properties, and Applications

Mosallanejad,

Abdi,

Karpasand

et al. 2023

Adv Eng Mater

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The restricted number of materials available for additive manufacturing (AM) technologies is a determining impediment to AM growing into sectors and providing supply chain relief. AM, in particular, is regarded as a trustworthy manufacturing technology to replace the traditional ones for Ti alloy components. Furthermore, the AM processability of Ti alloys and their features, such as microstructure, texture, and mechanical properties, is strongly dependent on the chemical composition of the processed alloy. It is essential to consider the ultimate applications as well. β Ti alloys are gaining popularity in the biomedical industry, while α + β Ti alloys are increasingly utilized for producing components in the automotive and aerospace sectors. Consequently, the topic has garnered considerable interest, and the current text reviews the advances during the last 10 years in this area to facilitate the pathway from the demanded Ti alloy to the best‐fit AM procedure. While systematically reviewing the works published in the literature, the current text attempts to establish a link between the production method, feedstock type, chemical composition, and the ultimate application. This review also features practical applications of Ti components produced by metal AM methods and offers prospective possibilities and industrial applications.

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“…have good antimicrobial and bone tissue growth-inducing properties. [3][4][5][6][7] However, the rate of osseointegration after implantation in the human body is relatively slow because of the inadequate bioactivity of Ti and Ti x O y . 8 Moreover, the mechanical properties of titanium alloy are much higher than those of human cortical bone (the compressive strength of cortical bone reaches 100-200 MPa, and cancellous bone reaches 2-20 MPa 9,10 ), which leads to bone atrophy and stress shielding.…”

Section: Introductionmentioning

confidence: 99%

Digital light processing of Ti_xO_y@Ti/HA biomaterials by oxidation of TiH₂ and dehydrogenation of TiO₂@TiH₂/HA precursors

Li,

Tang,

Huang

et al. 2024

J Am Ceram Soc.

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The complex structure of Ti/HA (HA: hydroxyapatite) implants prepared by additive manufacturing technology plays an essential role in its application in bone repair. Digital light processing (DLP) is widely used to prepare bioceramics with complex structures. However, it is a challenge to prepare Ti/HA biomaterials by DLP due to the high ultraviolet (UV) absorption of Ti powder. In the present work, TiH2 powder coated with a TiO2 layer is selected to reduce the UV absorption and improve the curing depth for DLP printed green bodies of TiO2@TiH2/HA, because the TiO2@TiH2 powder can be reduced by 12.7% compared to the TiH2 powder without any oxidation. Then, the shell layer of TiO2 undergoes dehydrogenation and reduction reaction with the core phase of TiH2 during the sintering process to transfer TiO2@TiH2/HA into TixOy@Ti/HA. In addition, the effects of HA content on compressive strength and biocompatibility are investigated in the TixOy@Ti/HA biomaterials. The results show that when adding 60 vol%HA, the maximum monolayer curing depth of the slurry reaches 90.1 ± 3.5 µm. 40%TixOy@Ti/60%HA shows the maximum effect in promoting the pre‐osteoblast differentiation and a relatively high compressive strength of 48.7 ± 3.5 MPa. This work provides an experimental basis for the preparation of ceramic–metal composites with high UV absorptivity using DLP.

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Microstructures and wear properties of surface treated Ti–36Nb–2Ta–3Zr–0.35O alloy by electron beam melting (EBM)

Cited by 20 publications

References 39 publications

New Ti–35Nb–7Zr–5Ta Alloy Manufacturing by Electron Beam Melting for Medical Application Followed by High Current Pulsed Electron Beam Treatment

New Ti–35Nb–7Zr–5Ta Alloy Manufacturing by Electron Beam Melting for Medical Application Followed by High Current Pulsed Electron Beam Treatment

Additive Manufacturing of Titanium Alloys: Processability, Properties, and Applications

Digital light processing of Ti_xO_y@Ti/HA biomaterials by oxidation of TiH₂ and dehydrogenation of TiO₂@TiH₂/HA precursors

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Microstructures and wear properties of surface treated Ti–36Nb–2Ta–3Zr–0.35O alloy by electron beam melting (EBM)

Cited by 20 publications

References 39 publications

New Ti–35Nb–7Zr–5Ta Alloy Manufacturing by Electron Beam Melting for Medical Application Followed by High Current Pulsed Electron Beam Treatment

New Ti–35Nb–7Zr–5Ta Alloy Manufacturing by Electron Beam Melting for Medical Application Followed by High Current Pulsed Electron Beam Treatment

Additive Manufacturing of Titanium Alloys: Processability, Properties, and Applications

Digital light processing of TixOy@Ti/HA biomaterials by oxidation of TiH2 and dehydrogenation of TiO2@TiH2/HA precursors

Contact Info

Product

Resources

About

Digital light processing of Ti_xO_y@Ti/HA biomaterials by oxidation of TiH₂ and dehydrogenation of TiO₂@TiH₂/HA precursors