TM10772 Titanium Alloy Wire Ti-0.3Mo-0.8Ni Grade 12 UNS R53400

Titanium Alloy Wire Ti-0.3Mo-0.8Ni Grade 12 UNS R53400 Description

Titanium Alloy Wire Ti-0.3Mo-0.8Ni Grade 12 UNS R53400 is manufactured with a defined composition of titanium alloyed with 0.3% Mo and 0.8% Ni. This composition, controlled under ASTM B265, results in a material with tailored mechanical properties and corrosion resistance suitable for technical applications. The uniform microstructure and consistent alloying support precise performance in areas such as electrical conductivity and structural reinforcement.

Titanium Alloy Wire Ti-0.3Mo-0.8Ni Grade 12 UNS R53400 Characteristics

*The above product information is based on theoretical data and is for reference only. Actual specifications may vary.

Titanium Alloy Wire Ti-0.3Mo-0.8Ni Grade 12 UNS R53400 Applications

Electronics and Instrumentation
- Used as wiring in sensor assemblies to achieve accurate signal transmission by leveraging its consistent electrical conductivity.

Aerospace and Structural Components
- Employed in non-critical structural supports to reduce weight and sustain performance under elevated temperatures through its optimised alloy composition.

Industrial Equipment
- Applied as reinforcement in heat exchangers to maintain structural integrity under thermal cycling by utilising its controlled microstructure.

Titanium Alloy Wire Ti-0.3Mo-0.8Ni Grade 12 UNS R53400 Packing

The wire is packaged in sealed, inert-gas filled containers to minimise oxidation and contamination. It is wound on suitable reels and enclosed within moisture-resistant materials. Storage under controlled temperature conditions is recommended to preserve its characteristics. Custom packaging options, including detailed labelling and anti-contamination measures, are available to suit specific handling requirements.

Additional Information

Titanium alloys are esteemed in various technical fields due to their low density and resistance to corrosion. The unique composition of titanium with minor alloying elements plays a critical role in achieving targeted mechanical and chemical properties. Their use spans from wiring in high-performance electronics to components in industrial systems that require a balance between strength and weight.

Further understanding of alloy behaviour under different thermal and mechanical stresses supports the advancement of engineering applications. Detailed material characterisation and controlled processing remain essential in optimising these alloys for specific industrial and research demands.