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Titanium Beta C refers to Ti Beta-C ,a trademark for a titanium alloy.Beta C is comparatively simple to melt and fabricate because of its propensity to gall, it is not advised for applications with significant wear.
Due to the characteristics of titanium and its capacity to spontaneously produce a well-adhered protective oxide layer when exposed to a high oxygen environment, beta C has good corrosion resistance to both salty conditions and acids. Because Beta C is one of the least dense beta alloys and can be heat treated to high strengths, it has a strong strength to weight ratio.
Moreover, it can consistently produce high strength even with rather thick section thicknesses. When a large amount of -stabiliser elements are added to titanium, the temperature of the allotropic transformation of titanium is reduced, resulting in beta titanium alloys.
The Global Titanium Beta C Market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.
Beta Titanium Alloys: Latest Advances in Biomedical Applications.Due to their low elastic moduli and excellent biocompatibility, -type titanium (Ti) alloys have received a lot of attention as innovative biomedical materials.
It offers a thorough and in-depth analysis of -type Ti alloys in terms of their design, techniques of preparation, mechanical characteristics, corrosion behaviour, and biocompatibility. This article discusses the design of -type Ti alloys from the perspectives of the molybdenum equivalency (Moeq) method and DV-X molecular orbital approach after providing a brief overview of the history of titanium and titanium alloys for biomedical applications.
A sizable number of -type Ti alloys are created using these techniques. Although having lower elastic moduli than other types of Ti alloys, -type Ti alloys nonetheless have higher elastic moduli than human bones.
As a result, porous -type Ti alloys with decreased elastic moduli have been created using a variety of fabrication techniques, including powder metallurgy and additive manufacturing.
When compared to other types of Ti alloys, -type Ti alloys offer similar or even superior mechanical qualities, corrosion behaviour, and biocompatibility. As a result, -type Ti alloys are the better options for usage as implant materials. Biological inertness is one issue that still exists with -type Ti alloys.
