About 314 Redraw Wire

314 redraw wire, a variant of stainless steel, offers exceptional corrosion resistance and heat resistance. Commonly utilized in high-temperature applications like furnace components, it provides durability and reliability in demanding environments, making it suitable for various industrial applications requiring resistance to oxidation and thermal cycling.

314 Redraw Wire chemical composition

The chemical composition of 314 redraw wire, a high-temperature stainless steel variant, typically includes:

• Chromium (Cr): Approximately 23-26%
• Nickel (Ni): Around 19-22%
• Molybdenum (Mo): Typically 1.5-2.5%
• Silicon (Si): Usually around 1.5-2.5%
• Manganese (Mn): Typically less than 2%
• Carbon (C): Generally less than 0.25%
• Phosphorus (P): Usually less than 0.045%
• Sulfur (S): Generally less than 0.03%
• Iron (Fe): The remainder

This composition provides excellent resistance to oxidation and high-temperature corrosion, making it suitable for applications in furnace components and other high-temperature environments.

314 Redraw Wire physical properties

314 redraw wire, a high-temperature stainless steel variant, exhibits the following physical properties:

1. Density: Approximately 7.9 g/cm³.
2. Melting Point: Typically around 1390-1440°C (2534-2624°F).
3. Electrical Conductivity: Moderate electrical conductivity.
4. Thermal Conductivity: Moderate to high thermal conductivity.
5. Magnetic Properties: Typically non-magnetic in annealed condition.
6. Tensile Strength: High tensile strength, usually ranging from 600 to 800 MPa (87,000 to 116,000 psi).
7. Elongation: Generally exhibits moderate elongation, typically around 25-35%.
8. Modulus of Elasticity: Approximately 200 GPa (29,000 ksi).
9. Hardness: Varies depending on the wire diameter and manufacturing process, typically in the range of 20-30 HRC (Rockwell hardness).
10. Corrosion Resistance: Excellent resistance to oxidation and high-temperature corrosion, making it suitable for use in demanding high-temperature environments.

These properties make 314 redraw wire ideal for applications in furnace components, heat exchangers, and other high-temperature industrial environments requiring resistance to oxidation and thermal cycling.

314 Redraw Wire mechanical properties

The mechanical properties of 314 redraw wire, a high-temperature stainless steel variant, typically include:

1. Tensile Strength: High tensile strength, usually ranging from 600 to 800 MPa (87,000 to 116,000 psi). This property indicates the maximum amount of tensile stress the wire can withstand before failure.
2. Yield Strength: Typically, the yield strength is around 300 to 450 MPa (43,500 to 65,000 psi). It represents the stress level at which the material begins to deform plastically.
3. Elongation: Moderate elongation, typically around 25-35%. This property indicates the amount of deformation the wire can undergo before fracturing.
4. Modulus of Elasticity: Approximately 200 GPa (29,000 ksi). It reflects the wire’s stiffness and its ability to return to its original shape after deformation.
5. Hardness: Varies depending on the wire diameter and manufacturing process, typically in the range of 20-30 HRC (Rockwell hardness). Higher hardness values indicate greater resistance to deformation and wear.
6. Corrosion Resistance: Excellent resistance to oxidation and high-temperature corrosion, making it suitable for use in demanding high-temperature environments.

These mechanical properties make 314 redraw wire ideal for applications in furnace components, heat exchangers, and other high-temperature industrial environments requiring resistance to oxidation and thermal cycling.

314 Redraw Wire Applications

314 redraw wire, prized for its high-temperature resilience, finds applications in:

1. Furnace Components: Used in heating elements, radiant tubes, and furnace grids due to its resistance to oxidation and high temperatures.
2. Heat Exchangers: Employed in the manufacturing of heat exchangers for various industries requiring thermal stability.
3. Chemical Processing: Utilized in equipment like reactors and distillation columns where resistance to high temperatures and corrosive environments is crucial.
4. Power Generation: Found in gas turbines, boilers, and exhaust systems where it withstands high temperatures and thermal cycling.
5. Aerospace: Applied in aircraft engine components and exhaust systems, enduring extreme temperatures and environmental conditions.
6. Metallurgy: Utilized in the production of metal alloys and casting molds requiring high-temperature stability.
7. Automotive: Found in exhaust systems, catalytic converters, and turbochargers due to its ability to withstand high exhaust temperatures.
8. Renewable Energy: Used in solar thermal power plants and concentrated solar power systems due to its ability to endure high temperatures.
9. Petrochemical Industry: Applied in refining processes, such as cracking units and reformers, due to its resistance to high temperatures and corrosive environments.
10. Research and Development: Utilized in laboratories for high-temperature experiments and testing equipment.

These applications highlight its resilience and reliability in environments with high temperatures and corrosive elements.