TM10757 Titanium Alloy Rod Ti-3Al-2.5V Grade 9 UNS R56320

Titanium Alloy Rod Ti-3Al-2.5V Grade 9 UNS R56320 Description

Titanium Alloy Rod Ti-3Al-2.5V Grade 9 UNS R56320 is manufactured from a titanium alloy containing 3% aluminium and 2.5% vanadium. Its composition is optimised to balance strength and ductility while maintaining a lightweight profile. The alloy's properties support precise machining and dimensional stability, making it suitable for engineering structures where resistance to corrosion and thermal stability are necessary. Its standardised production per ASTM B265 ensures consistent performance across applications.

Titanium Alloy Rod Ti-3Al-2.5V Grade 9 UNS R56320 Characteristics

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

Titanium Alloy Rod Ti-3Al-2.5V Grade 9 UNS R56320 Applications

1.       Aerospace Applications
   - Used as fasteners or structural supports in aircraft components to achieve weight reduction by leveraging high strength-to-weight properties.
   - Applied as connecting rods in propulsion systems to enhance fatigue resistance, utilising its balanced ductility and strength.

2.       Industrial Applications
   - Employed as components in chemical processing equipment to achieve corrosion resistance and structural integrity in harsh environments.
   - Used in heat exchangers where low thermal conductivity and stable performance under high temperatures provide consistent operation.

Titanium Alloy Rod Ti-3Al-2.5V Grade 9 UNS R56320 Packing

The rod is packaged using protective wrapping within anti-static, shock-absorbent materials to minimise surface damage and contamination. It is stored in sealed, moisture-resistant containers at controlled temperatures to prevent oxidation. Custom packaging options, including bulk handling and labelling customisation, are available to meet specific handling and storage requirements.

Additional Information

Titanium alloys have emerged as essential materials in high-performance engineering due to their low density and exceptional corrosion resistance. The specific alloy composition of Ti-3Al-2.5V balances mechanical strength with improved weldability, making it a frequent choice for precision parts in demanding environments. Researchers in materials science continue to optimise processing techniques to further enhance these properties.

In the broader context of non-ferrous metals, titanium alloys represent a critical intersection of metallurgy and engineering design. Their behaviour under variable thermal and mechanical loads is a subject of ongoing study, highlighting the importance of controlled alloying and processing methods.