About 316Ti Redraw Wire

316Ti redraw wire, a stainless steel variant, contains titanium for enhanced resistance to corrosion in aggressive environments. Ideal for marine, chemical, and medical applications, it offers superior durability, strength, and corrosion resistance. Widely utilized in critical industries, it ensures reliability in demanding conditions.

 

316Ti Redraw Wire chemical composition

316Ti redraw wire, a stainless steel variant, typically contains the following chemical composition:

  • Chromium (Cr): Approximately 16-18%
  • Nickel (Ni): Around 10-14%
  • Molybdenum (Mo): Typically 2-3%
  • Titanium (Ti): Generally 0.5-1.5%
  • Carbon (C): Usually less than 0.08%
  • Silicon (Si): Typically less than 1%
  • Manganese (Mn): Usually less than 2%
  • Phosphorus (P): Typically less than 0.045%
  • Sulfur (S): Typically less than 0.03%
  • Iron (Fe): The remainder

This composition provides excellent corrosion resistance, especially in aggressive environments, making it suitable for various industrial applications.

 

316Ti Redraw Wire physical properties

316Ti redraw wire, a stainless steel variant, exhibits the following physical properties:

  1. Density: Approximately 8.0 g/cm³.
  2. Melting Point: Typically around 1370-1400°C (2498-2552°F).
  3. Electrical Conductivity: Moderate electrical conductivity.
  4. Thermal Conductivity: Moderate thermal conductivity.
  5. Magnetic Properties: Typically non-magnetic in annealed condition; may become slightly magnetic after cold working.
  6. Tensile Strength: High tensile strength, usually ranging from 500 to 700 MPa (72,500 to 101,500 psi).
  7. Elongation: Generally exhibits good elongation, typically around 40-50%.
  8. Modulus of Elasticity: Approximately 193 GPa (28,000 ksi).
  9. Hardness: Varies depending on the wire diameter and manufacturing process, typically in the range of 25-35 HRC (Rockwell hardness).
  10. Corrosion Resistance: Excellent corrosion resistance, particularly in aggressive environments, due to its alloy composition, including titanium.

These properties make 316Ti redraw wire suitable for various applications where corrosion resistance, durability, and mechanical strength are crucial, such as in marine, chemical, and medical industries.

 

316Ti Redraw Wire mechanical properties

316Ti redraw wire, a stainless steel variant, typically exhibits the following mechanical properties:

  1. Tensile Strength: High tensile strength ranging from approximately 500 to 700 MPa (72,500 to 101,500 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 200 to 300 MPa (29,000 to 43,500 psi). It represents the stress level at which the material begins to deform plastically.
  3. Elongation: 316Ti redraw wire generally shows good elongation, typically around 40-50%. This property indicates the amount of deformation the wire can undergo before fracturing.
  4. Modulus of Elasticity: Approximately 193 GPa (28,000 ksi). It reflects the wire’s stiffness and its ability to return to its original shape after deformation.
  5. Hardness: Depending on the wire diameter and manufacturing process, the hardness of 316Ti redraw wire typically ranges from 25 to 35 HRC (Rockwell hardness). Higher hardness values indicate greater resistance to deformation and wear.
  6. Corrosion Resistance: Excellent corrosion resistance, particularly in aggressive environments, due to its alloy composition, including titanium.

These mechanical properties make 316Ti redraw wire suitable for various applications where high strength, corrosion resistance, and durability are required, such as in marine, chemical, and medical industries.

 

316Ti Redraw Wire Applications

316Ti redraw wire, renowned for its corrosion resistance and mechanical strength, is utilized across diverse industries:

  1. Chemical Processing: Tanks, pipelines, valves, and fittings resist corrosion from acids and chemicals.
  2. Medical Devices: Surgical instruments, implants, and medical equipment benefit from its biocompatibility and sterilizability.
  3. Marine Industry: Fittings, rigging, and hardware endure harsh marine environments.
  4. Automotive: Exhaust systems, fasteners, and springs withstand corrosive conditions.
  5. Aerospace: Aircraft components like fasteners and wire rope ensure durability in challenging environments.
  6. Food Processing: Hygienic conveyors, handling equipment, and storage tanks ensure product purity.
  7. Oil and Gas: Equipment like pipelines and tubing resist corrosion in harsh environments.
  8. Textile Industry: Wire cloth, screens, and filters offer strength and durability.
  9. Electronics: Components benefit from corrosion resistance and electrical conductivity.
  10. Telecommunications: Antenna wires and cables rely on its durability and conductivity.

These applications underscore its versatility and reliability in demanding environments.