TM10768 Titanium Alloy Sheet Ti-0.3Mo-0.8Ni Grade 12 UNS R53400

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

Titanium Alloy Sheet Ti-0.3Mo-0.8Ni Grade 12 UNS R53400 is produced from a carefully balanced mixture of titanium, molybdenum, and nickel. The 0.3Mo-0.8Ni composition enhances resistance to oxidation and improves ductility, making the sheet suitable for forming and precision fabrication. The alloy's characteristic microstructure and low defect density offer benefits in maintaining dimensional stability and consistent mechanical properties during industrial processing.

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

1.       Industrial Manufacturing
- Used as load-bearing panels in high-temperature processing equipment to achieve dimensional stability by leveraging the alloy's maintained strength and oxidation resistance.

2.       Aerospace Applications
- Applied as lightweight structural components in aircraft to reduce system weight while ensuring adequate strength, benefiting from the alloy's balanced mechanical profile.

3.       Chemical Processing
- Serves as corrosion-resistant liners in reactor systems to maintain chemical inertness and process integrity by utilising the alloy's stable microstructure.

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

The sheet is securely packaged in anti-scratch, inert protective wraps and placed in rigid, moisture-resistant containers. It is stored under controlled temperature conditions to prevent oxidation and mechanical damage during transit. Anti-contamination measures are implemented, and customisation of packaging—such as size-specific crating—is available on request to meet logistical and storage requirements.

Additional Information

Titanium alloys are extensively studied for their strength-to-weight ratio and corrosion resistance. The addition of alloying elements such as Mo and Ni alters phase stability and mechanical performance, making these materials vital in areas where thermal and chemical challenges are present. Understanding the interplay between composition and processing methods is crucial for optimising performance in industrial applications.

Advances in metallurgical techniques have enhanced quality control and microstructure analysis in titanium alloys. Improved testing, including metallography and mechanical testing, enables precise control over alloy properties. This ensures that materials perform consistently in high-stress applications, contributing to safer and more efficient operational environments.