How Titanium Alloy Is Used In These 4 Industries Today?

Titanlegierung is a titanium alloy that incorporates additional elements. It is used in modern industry because it provides high strength, corrosion resistance and heat tolerance. Titanium exhibits biocompatibility, superconductivity, hydrogen storage and shape memory. These properties justify its use in medical devices, chemical production, aerospace, naval engineering and other applications.

The use of titanium alloys currently focuses on the following sectors.

Titanium Alloy for Aerospace

Titanium is a critical component in aircraft fuselages, engines and rocket modules. The United States employed titanium alloys in aircraft projects such as the X-31 and X-30. This usage improved the M coefficient by approximately 3 times and reduced total mass to 80% of the original value. Russia manufactures titanium alloy plates and forgings for aircraft production using titanium‐based materials. Titanium alloys were also applied in the development of the Chinese spacecraft Shenzhou.

Further reading: Titanium Usage in the Aerospace Industry

Titanium Alloy for Shipbuilding

Materials used in ships must perform reliably when exposed to water continuously. They require corrosion resistance, safety, reliability and a long service life. Titanium alloys are applied in shipbuilding because they offer established strength, mechanical stability, corrosion resistance and impact toughness. In Russian ships, these alloys are used in pumps, filters, supply pipes, fire suppression systems and pressure vessels. The US Navy and the company Timet developed a titanium alloy known as Timetal 5111. This alloy provides fracture toughness, corrosion resistance, stable temperature and creep performance and is amenable to welding. It is used in ship systems, cooling systems, sewage treatment equipment and electrical components.

Further reading: Titanium in the Shipbuilding Industry

Titanium Alloy in Biomedical Applications

Titanium alloys are widely used in surgical implants. The alloy Ti-12Mo-6Zr-2Fe is a metastable composition. It meets requirements for high strength, fracture toughness, wear resistance, corrosion resistance and has an elastic modulus suitable for orthopaedic devices.

The mechanical performance, corrosion resistance and biocompatibility of titanium alloys may be improved by incorporating additional elements such as Zirconium, Palladium, Niobium, Tin and Tantalum. This approach is the primary method for producing biocompatible titanium alloys.

Further reading: Titanium in the Medical Industry

Titanium Alloy in the Automotive Industry

Lightweight design is an important objective in the automotive sector. Titanium alloys are mainly employed in engine components such as connecting rods, springs, crankshafts and fasteners.

Further reading: Titanium in the Automotive Industry

Conclusion

We appreciate your reading of this article. The information provided is intended to improve understanding of titanium applications in aerospace, shipbuilding, biomedical and automotive sectors. For additional details on titanium products, please visit Stanford Advanced Materials (SAM).

Stanford Advanced Materials (SAM) is a global supplier of titanium products. It has more than 20 years of experience in manufacturing and distributing medical‐grade titanium materials. The products meet the research, development and production requirements of customers. We trust that SAM will be your chosen supplier and business partner.