Alloy Geek Nimonic 105 Standard
Are you looking for a reliable reference material to support your research and quality control efforts in the field of superalloys? Nimonic 105 Reference Material is your answer. Crafted to meet the stringent requirements of researchers, engineers, and quality assurance professionals, this reference material provides comprehensive insights into the composition and properties of Nimonic 105, a distinguished member of the Nimonic alloy family.
Chemical Composition (Ranges, Min-Max):
- Nickel (Ni): 51-61%
- Chromium (Cr): 19-21%
- Iron (Fe): 10-13%
- Titanium (Ti): 1.5-2.5%
- Aluminum (Al): 0.4-1.0%
- Manganese (Mn): 0.3% max
- Silicon (Si): 0.2% max
- Carbon (C): 0.08% max
High Temperature Strength: Nimonic 105 is renowned for maintaining exceptional mechanical strength even at elevated temperatures, making it invaluable for applications in gas turbine engines and other high-temperature environments.
Oxidation Resistance: This alloy exhibits outstanding resistance to oxidation and corrosion, ensuring long-term durability and performance in aggressive atmospheres.
Creep Resistance: Nimonic 105's resistance to creep deformation under high-stress, high-temperature conditions is a hallmark feature, ensuring structural integrity over extended service periods.
Thermal Stability: Nimonic 105 is known for its remarkable stability across a wide range of temperatures, a vital attribute for components subjected to extreme thermal cycling.
Weldability: The alloy's weldability allows for ease of fabrication and repair in demanding engineering projects.
Other Names for Nimonic 105:
- UNS N140105
- Nimonic Alloy 105
- Ni-Cr-Fe-Ti-Al Alloy 105
Unique Features of Nimonic 105:
Nimonic 105 sets itself apart from other alloys within the Nimonic family by offering a harmonious blend of properties. While other Nimonic alloys may excel in specific aspects, such as corrosion resistance or high-temperature strength, Nimonic 105 presents a well-rounded package of both. This unique composition and balanced performance make it particularly well-suited for critical aerospace, gas turbine, and industrial applications where reliability and performance under extreme conditions are essential.
Its robust resistance to oxidation and corrosion ensures it can endure harsh environments, while its high-temperature strength and creep resistance guarantee longevity in demanding applications like gas turbine components and exhaust systems. Moreover, Nimonic 105's weldability and thermal stability simplify the manufacturing process, providing engineers with a versatile material for complex designs and facilitating ease of use in research and development endeavors.
In conclusion, Nimonic 105 Reference Material offers comprehensive insights into this exceptional alloy's composition and properties, making it an invaluable tool for researchers and engineers seeking to harness its unique attributes for cutting-edge applications or quality assurance purposes. Its exceptional balance of characteristics distinguishes it as a top choice for industries where reliability and performance in extreme environments are non-negotiable.
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