Alloy 361 Molybdenum is a high-performance, material frequently adopted in the aerospace and defense industries as its outstanding mechanical characteristics and corrosion resistance provide additional durability for these applications. To be specific, its chemical makeup largely consists of moiيّbdenum, titanium, zirconium, and carbon, and some other elements, that make it a super material for operation under really extreme conditions. In addition, alloy 361 possesses unusual thermal stability, allowing its application in thermal surrounding. Such characteristics are thoroughly considered in order to select options that have been specifically adjusted to the needs of the particular industry, among other features such as strength and ductility. Comprehensive, the table and chart enabled to see its chemical composition and mechanical properties, also the engineers and manufacturers can clearly know the grades and the kinds of the alloy, especially for the uses. The web-based PDF documents increase the convenience of seeking close-to-perfect information for both material selection and designing process.
Mostafa Alloy 361 of Molybdenum is widely acknowledged for the superiority of its elemental composition and grade characteristics, favoring its utilization in various industries. As for the development of the alloy, this one is mainly made from molybdenum but it also consists of specific amounts of other important elements like titanium, zirconium and silicon, which are there to increase the strength of the alloy and the way it works. The exceptional combination of strength, corrosion resistance, and impressive thermal stability makes this alloy the go-to choice of more and more manufacturing facilities both large and small and even in the most adverse conditions and environments. The engineers and manufacturers highly depend on the its exact chemical composition and grade table for the application in the critical operations to retain it reputation as a top-class alloy.
Elements | Mo | C | Si | Fe | O | Ni | N |
---|---|---|---|---|---|---|---|
Min (%) | 99.9 | - | - | - | - | - | - |
Max (%) | 100 | 0.010 | 0.010 | 0.010 | 0.0070 | 0.0050 | 0.0020 |
Advantages:
High Melting Point: Suitable for high-temperature conditions.
Good Thermal Conductivity: Facilitates efficient heat transfer.
Low Coefficient of Thermal Expansion: Reduces dimensional changes due to temperature.
Good Electrical Conductivity: Exhibits good electrical conductivity.
Disadvantages:
Susceptible to Oxidation: Prone to oxidation when exposed to oxygen.
Limited Ductility: Lower ductility compared to other materials.
Costly Processing: Requires extra processing, increasing costs.
Susceptible to Hydrogen Embrittlement: Vulnerable to embrittlement when exposed to hydrogen.
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