High density: Molybdenum wire has a high viscosity, usually close to 10.2g/cm³. This high density gives the molybdenum wire good stability in the manufacturing process and can provide better weight distribution.
High melting point: the melting end of molybdenum wire is very high, reaching 2610℃. This means that molybdenum wire can maintain its structural stability at high temperatures and can, therefore, be used to manufacture components and structures in high-temperature environments.
Corrosion resistance: Molybdenum wire has good corrosion resistance in most chemical environments. Therefore, it can manufacture components and structures in the chemical industry, such as those in reactors and high-temperature furnaces.
Good mechanical properties: Molybdenum wire has good mechanical properties, including high strength, hardness, and toughness. These characteristics make molybdenum wires perform well in environments with high loads and shocks.
Good high-temperature oxidation resistance: At high temperatures, the surface of the molybdenum wire will form a dense oxide film, effectively preventing further oxidation. This characteristic gives the molybdenum wire an excellent protective effect in high-temperature environments.
Easy to process: Although the melting point of molybdenum wire is high, its processing performance is still excellent. Molybdenum wire can be processed by forging, rolling, extrusion, and injection molding.
Non-toxic: molybdenum wire itself is non-toxic and will not cause harm to human health. However, long-term exposure to molybdenum wire may cause skin irritation and respiratory disease, so corresponding protective measures must be taken.
High strength: Molybdenum wire has high power and can withstand sizeable tensile and bending stress. This strength makes the molybdenum wire have good durability and reliability in manufacturing.
Good plasticity: Molybdenum wire has good plasticity and can change its shape and size by plastic deformation. This property makes molybdenum wire have good processability and adaptability in the manufacturing process.
Good fatigue resistance: Molybdenum wire has good fatigue resistance and can withstand periodic and impact loads. This property makes molybdenum wire have good durability and reliability in manufacturing.
Good thermal stability: molybdenum wire has good thermal stability at high temperatures, which can maintain the strength of its structure and performance. This means that molybdenum wire can manufacture components and systems in high-temperature environments without deformation or performance degradation.
Applications of Molybdenum wire:
Aerospace field: Molybdenum wire has a wide range of applications in the aerospace field. Due to its high density, high melting point, and good electrical conductivity, molybdenum wire is used to manufacture various components and structures in aerospace spacecraft, such as fuel ejectors, guide blades, turbine blades, and rocket nozzles. In addition, molybdenum wire can be used to manufacture high-temperature furnaces in aerospace spacecraft and components in reactors.
Electronic field: Molybdenum wire is also widely used in electronics. Due to its high conductivity and melting point, molybdenum wire is used to manufacture various components in electronic devices, such as resistors, capacitors, and tubes. In addition, molybdenum wire can manufacture multiple electronic devices, such as transistors and integrated circuits.
Chemical industry: Molybdenum wire also has a wide range of applications in the chemical industry. Molybdenum wire is used to manufacture various components and structures in chemical equipment, such as reactors, heat exchangers, and distillation towers. In addition, molybdenum wire can manufacture multiple chemical products, such as acids, bases, and salts.
Nuclear industry: Molybdenum wire also has a wide range of applications in the nuclear industry. Due to its high melting point, good corrosion resistance, and high-temperature oxidation resistance, molybdenum wire manufactures components and structures in atomic reactors, such as fuel rods, control rods, and reactor vessels. In addition, molybdenum wire can be used to manufacture other components and structures in the nuclear industry, such as components in the nuclear fuel cycle system.
Automotive field: Molybdenum wire is also widely used in the automotive field. Due to its high strength, hardness, and toughness, molybdenum wire is used to manufacture various components and structures in automotive parts, such as valves, pistons, and crankshafts. In addition, molybdenum wire can be used to manufacture components such as car bodies and interiors.
Medical field: Molybdenum wire also has a wide range of applications in the medical field. Due to its high density, good biocompatibility, and corrosion resistance, molybdenum wire is used to manufacture various components and structures in medical devices, such as orthopedic implants, dental implants, and cardiovascular implants.
Production Method of Molybdenum wire:
Powder metallurgy: Powder metallurgy is a traditional method for preparing molybdenum wire. The technique is putting molybdenum powder into the mold, sintering, and extruding at high temperatures to make molybdenum billet. Then, the molybdenum billet is processed and heat-treated to obtain the required molybdenum wire. The advantages of powder metallurgy are that the prepared molybdenum wire has high purity and density. Still, the disadvantages are that the production process is complex, and the production cost could be higher.
Melting method: The melting method prepares molybdenum wire by melting molybdenum material at high temperatures. The technique is to melt molybdenum into a high-temperature furnace and then spin through the spinning mechanism to obtain molybdenum wire. The advantage of the smelting method is that the production process is simple and can be large-scale, but the disadvantage is that the purity of the prepared molybdenum wire is low.
Electrolysis: Electrolysis is a method of preparing molybdenum wire by electrolysis of molybdate solution. The technique is to put the molybdate solution into the electrolytic tank and reduce the molybdate into molybdenum powder by electrolysis. Then, the obtained molybdenum powder is processed and heat-treated to receive the required molybdenum wire. The advantage of the electrolysis method is that the production process is simple and can be large-scale. Still, the disadvantage is that the purity of the prepared molybdenum wire is low.
Laser cutting method: Laser cutting method is a method to prepare molybdenum wire by laser cutting molybdenum material. The method is to put the molybdenum material into the laser cutting machine and cut the molybdenum material through the high-energy laser beam to get the required molybdenum wire. The laser cutting method has high production efficiency and the preparation of high-precision molybdenum wire; the disadvantage is the higher equipment cost.
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Alloy Metal 99.95% Purity Mollybdenum Wires Properties
Other Titles
Molybdenum Wire
N/A
Compound Formula
Mo
Molecular Weight
N/A
Appearance
wire
Melting Point
N/A
Solubility In Water
N/A
Density
>=10.2g/cm3
Purity
>=99.95%
Size
Individualized
Boling Point
N/A
Specific Heat
N/A
Thermo Conductivity
N/A
Thermal Expansion
N/A
Young's Module
N/A
Exact
N/A
Monoisotopic
N/A
Metal alloy 99.95% purity Molybdenum wires Safety & health information