Custom Molybdenum Strip

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Molybdenum Strip Suppliers

Welcome to the category of Molybdenum Strips, a versatile material with a myriad of applications. These strips play an integral role in the production of electric light sources, enabling the creation of efficient and long-lasting lighting solutions. Additionally, molybdenum strips are utilized in the production of molybdenum wires for wire cutting applications, delivering precision and reliability. Their use as steel additives enhances the mechanical properties of steel, making it more robust and durable. Whether in the lighting industry, manufacturing, or steel production, Molybdenum Strips offer essential characteristics that drive innovation and efficiency in various sectors.
Taizhou Huacheng Tungsten And Molybdenum Manufacture Co., Ltd.
Taizhou Huacheng Tungsten And Molybdenum Manufacture Co., Ltd.
Taizhou Huacheng Tungsten and Molybdenum Products Co., Ltd. is a professional company that produces tungsten and molybdenum series products. The company specializes in the production of tungsten and molybdenum special-shaped parts, high-density tungsten alloys, tungsten-copper alloys, and the research and development of new tungsten-molybdenum materials. Molybdenum Strip Suppliers and Custom Molybdenum Strip Factory. The main products are:
● Tungsten
● Molybdenum strip
● Plate
● Electrode rod
● Tungsten and molybdenum crucible
● Molybdenum Piercing Mandrel
● TZM rare earth molybdenum
● Sodium tungstate
● Sodium molybdate
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Industry knowledge
What are the key mechanical, thermal, and electrical properties of Molybdenum Strip?
Molybdenum Strip possesses several key properties that make it valuable for various industrial applications. Here are the key mechanical, thermal, and electrical properties of Molybdenum Strip:
Mechanical Properties:
Tensile Strength:
Molybdenum Strip exhibits high tensile strength, making it suitable for applications requiring robust and durable materials.
Tensile strength values can be well above 100,000 psi.
Elongation at Break:
While Molybdenum is generally brittle, certain manufacturing processes and alloying elements can influence the elongation at break, allowing for some flexibility.
Molybdenum is known for its high hardness at room temperature, contributing to its wear resistance.
Alloying with other elements may influence the hardness of Molybdenum Strip.
Young's Modulus:
Molybdenum exhibits a high Young's Modulus, indicating its ability to withstand deformation under stress.
Thermal Properties:
Melting Point:
Molybdenum has a very high melting point of approximately 2,623 degrees Celsius (4,753 degrees Fahrenheit).
This property makes it suitable for high-temperature applications, such as in the aerospace and electronics industries.
Thermal Conductivity:
Molybdenum is characterized by good thermal conductivity, allowing it to efficiently transfer heat.
This property is valuable in applications where heat dissipation is crucial.
Coefficient of Thermal Expansion (CTE):
The CTE of Molybdenum is relatively low, contributing to its stability under thermal cycling conditions.
Low CTE is advantageous in applications where dimensional stability is critical.
Electrical Properties:
Electrical Conductivity:
Molybdenum is a good electrical conductor, although it is not as conductive as materials like copper.
The electrical conductivity of Molybdenum Strip can be influenced by factors such as purity and alloying elements.
At low temperatures, Molybdenum can exhibit superconducting properties, making it useful in certain specialized applications.
Other Properties:
Corrosion Resistance:
Molybdenum has good corrosion resistance in many environments, particularly at elevated temperatures.
It forms a protective oxide layer on its surface that enhances resistance to corrosion.
Molybdenum can be machined using conventional methods, but its hardness may pose challenges in some machining processes.
Molybdenum is weldable using methods like Tungsten Inert Gas (TIG) welding. However, special considerations may be required, and the choice of welding technique can impact the properties of the final product.
Molybdenum can be formed into various shapes, but its brittleness may limit the extent of formability.
Understanding these properties is crucial for selecting Molybdenum Strip for specific applications, particularly those involving high temperatures, mechanical stress, or electrical conductivity requirements. 

Can Molybdenum Strip be welded, and what methods are commonly used?
Molybdenum Strip can be welded, and various methods are commonly used for this purpose. Welding molybdenum requires specific considerations due to its high melting point, low thermal conductivity, and susceptibility to embrittlement. Here are some common welding methods used for Molybdenum Strip:
Tungsten Inert Gas (TIG) Welding:
TIG welding, also known as GTAW (Gas Tungsten Arc Welding), is a widely used method for welding Molybdenum Strip.
In TIG welding, a non-consumable tungsten electrode is used to create an arc that melts the molybdenum strip and any filler material if used.
TIG welding is suitable for both thin and thick sections of molybdenum, providing good control over the welding process.
Laser Welding:
Laser welding is another effective method for joining Molybdenum Strip.
It utilizes a focused laser beam to melt and fuse the edges of the molybdenum strip.
Laser welding can provide precise control and is suitable for applications where minimal heat-affected zones are desired.
Electron Beam Welding (EBW):
Electron beam welding is a high-energy welding process that uses a focused beam of electrons to join metals, including Molybdenum Strip.
EBW can produce deep, narrow welds with minimal heat input, making it suitable for high-purity and precision applications.
Resistance Welding:
Resistance welding methods, such as spot welding or seam welding, can be used for joining Molybdenum Strip.
These methods involve passing an electric current through the material, generating heat at the contact points to create a weld.
Plasma Arc Welding (PAW):
Plasma arc welding is similar to TIG welding but uses a constricted plasma arc for higher energy concentration.
PAW can be used for welding Molybdenum Strip, offering advantages in terms of penetration and welding speed.
Hydrogen Arc Welding:
Hydrogen arc welding is a process where hydrogen gas is used as a shielding gas.
This method can be used for welding refractory metals like molybdenum, providing good control over the welding environment.
Inert Gas Atmosphere Furnace Welding:
In certain applications, especially those involving larger components, molybdenum strips can be joined using inert gas atmosphere furnace welding.
This method is suitable for achieving uniform heating and controlled cooling.
The choice of welding method depends on factors such as the specific application, the thickness of the molybdenum strip, and the desired characteristics of the weld. Proper handling and welding practices are essential to minimize the risk of embrittlement and achieve strong, durable welds. Additionally, the use of appropriate shielding gases and filler materials may be necessary to prevent oxidation and improve the quality of the weld.
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