Factory Supplier for AISI304| SUS304| EN1.4948 Factory from Lyon

Factory Supplier for
 AISI304| SUS304| EN1.4948 Factory from Lyon

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Chemical Composition of Stainless Steel 304 Table 1. Chemical composition for 304 stainless steel alloys % 304 304L 304H C 0.0 – 0.07 0.0 – 0.03 0.04 – 0.08 Mn 0.0 – 2.0 0.0 – 2.00 0.0 – 2.0 Si 0.0 – 1.00 0.0 – 1.00 0.0 – 1.0 P 0.0 – 0.05 0.0 – 0.05 0.0 – 0.04 S 0.0 – 0.03 0.0 – 0.02 0.0 – 0.02 Cr 17.50 – 19.50 17.50 – 19.50 ...


  • Length: 3-5.8mm or Customization
  • Surface: black, peeled, or rough turned
  • Heat treatment: air-cooling, normalized, annealed, Q&T
  • Smelting process: EAF+LF+VD
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    Chemical Composition of Stainless Steel 304

    Table 1. Chemical composition for 304 stainless steel alloys

    %

    304

    304L

    304H

    C

    0.0 – 0.07

    0.0 – 0.03

    0.04 – 0.08

    Mn

    0.0 – 2.0

    0.0 – 2.00

    0.0 – 2.0

    Si

    0.0 – 1.00

    0.0 – 1.00

    0.0 – 1.0

    P

    0.0 – 0.05

    0.0 – 0.05

    0.0 – 0.04

    S

    0.0 – 0.03

    0.0 – 0.02

    0.0 – 0.02

    Cr

    17.50 – 19.50

    17.50 – 19.50

    17.00 – 19.00

    Ni

    8.00 – 10.50

    8.00 – 10.50

    8.00 – 11.00

    Fe

    Balance

    Balance

    Balance

    N

    0.0-0.11

    0.0-0.11

    0.0 – 0.10

    Properties of Stainless Steel 304

    Mechanical Properties of Stainless Steel 304

    Table 2a. Mechanical properties for 304 stainless steel alloys – sheet up to 8 mm thick

    Grade

    304

    304L

    304H

    Tensile Strength (MPa)

    540 – 750

    520 – 700

    -

    Proof Stress (MPa)

    230 Min

    220 Min

    -

    Elongation A50 mm

    45 Min %

    45 Min %

    -


    Table 2b. Mechanical properties for 304 stainless steel alloys – plate from 8 – 75 mm thick

    Grade

    304

    304L

    304H

    Tensile Strength (MPa)

    520 – 720

    500 – 700

    -

    Proof Stress (MPa)

    210 Min

    200 Min

    -

    Elongation A5

    45 Min %

    45 Min %

    -


    Table 2c. Mechanical properties for 304 stainless steel alloys – bar and section up to 160 mm diameter / thickness

    Grade

    304

    304L

    304H

    Tensile Strength (MPa)

    500 – 700

    500 – 700

    500 – 700

    Proof Stress (MPa)

    190

    175 Min

    185 Min

    Elongation A50 mm

    45 Min %

    45 Min %

    40 Min %

    Hardness Brinell

    215 Max HB

    215 Max HB

    -

    Physical Properties of Stainless Steel 304

    Table 3. Physical properties for 304 stainless steel alloys

    Property

    Value

    Density

    8.00 g/cm3

    Melting Point

    1450 °C

    Modulus of Elasticity

    193 GPa

    Electrical Resistivity

    0.072 x 10-6 Ω.m

    Thermal Conductivity

    16.2 W/m.K

    Thermal Expansion

    17.2 x 10-6 /K

    Alloy Designations

    Stainless steel 304 also corresponds to the following standard designations and specifications:

    Euronorm

    UNS

    BS

    En

    Grade

    1.4301

    S30400

    304S15

    304S16

    304S31

    58E

    304

    1.4306

    S30403

    304S11

    -

    304L

    1.4307

    -

    304S11

    -

    304L

    1.4311

    -

    304S11

    -

    304L

    1.4948

    S30409

    304S51

    -

    304H

    Corrosion Resistance of Stainless Steel 304

    Stainless steel 304
    has excellent corrosion resistance in a wide variety of environments
    and when in contact with different corrosive media. Pitting and crevice
    corrosion can occur in environments containing chlorides. Stress
    corrosion cracking can occur at temperatures over 60°C.

    Heat Resistance of Stainless Steel 304

    Stainless steel 304 has
    good resistance to oxidation in intermittent service up to 870°C and in
    continuous service to 925°C. However, continuous use at 425-860°C is
    not recommended if corrosion resistance in water is required. In this
    instance 304L is recommended due to its resistance to carbide
    precipitation.

    Where high strength is required at temperatures above 500°C and up to
    800°C, grade 304H is recommended. This material will retain aqueous
    corrosion resistance.

    Fabrication of Stainless Steel 304

    Fabrication of all stainless steels should
    be done only with tools dedicated to stainless steel materials. Tooling
    and work surfaces must be thoroughly cleaned before use. These
    precautions are necessary to avoid cross contamination of stainless steel by easily corroded metals that may discolour the surface of the fabricated product.

    Cold Working of Stainless Steel 304

    Stainless steel 304 readily
    work hardens. Fabrication methods involving cold working may require an
    intermediate annealing stage to alleviate work hardening and avoid
    tearing or cracking. At the completion of fabrication a full annealing
    operation should be employed to reduce internal stresses and optimise
    corrosion resistance.

    Hot Working of Stainless Steel 304

    Fabrication methods, like forging, that involve hot working should
    occur after uniform heating to 1149-1260°C. The fabricated components
    should then be rapidly cooled to ensure maximum corrosion resistance.

    Heat Treatment of Stainless Steel 304

    Stainless steel 304 cannot be hardened by heat treatment.

    Solution treatment or annealing can be done by rapid cooling after heating to 1010-1120°C.

    Machinability

    Stainless steel 304 has good machinability. Machining can be enhanced by using the following rules:

    • Cutting edges must be kept sharp. Dull edges cause excess work hardening.

    • Cuts should be light but deep enough to prevent work hardening by riding on the surface of the material.

    • Chip breakers should be employed to assist in ensuring swarf remains clear of the work

    • Low thermal conductivity of austenitic alloys results in heat
      concentrating at the cutting edges. This means coolants and lubricants
      are necessary and must be used in large quantities.

    Welding of Stainless Steel 304

    Fusion welding performance for Stainless steel 304 is excellent both with and without fillers. Recommended filler rods and electrodes for stainless steel 304 is grade 308 stainless steel.
    For 304L the recommended filler is 308L. Heavy welded sections may
    require post-weld annealing. This step is not required for 304L. Grade
    321 may be used if post-weld heat treatment is not possible.

    Applications of Stainless Steel 304

    Stainless steel 304 is typically used in:

    • Sinks and splashbacks

    • Saucepans

    • Cutlery and flatware

    • Architectural panelling

    • Sanitaryware and troughs

    • Tubing

    • Brewery, dairy, food and pharmaceutical production equipment

    • Springs, nuts, bolts and screws

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  • Tensile Tests of Steel Bar, tensile test, tensile energy, energy, reinforcement, rebar tests.

    In a tensile test of mild steel specimen, normally a round or flat bar is slowly pulled in a tests equipment until finally it breaks. Two points, known as gauge points, are marked on the central portion. The distance in between these points, ahead of the application of the load, is known as gauge size of the specimen. The extensions of the gauge size and the values of the corresponding loads are essential at frequent intervals. The extensions are calculated by an instrument known as an extensometer.

    The strains corresponding to the recorded extensions are calculated by dividing the latter by the gauge size, when the stresses are calculated by dividing the loads by the authentic area of cross-section of the specimen. Stresses so arrived at is known as nominal pressure to distinguish it from genuine pressure which is acquired by dividing the load at a individual quick by the area of the cross-section at that quick. Genuine pressure is higher than nominal pressure in a tensile test for the reason that the load raises, and correspondingly the area of the specimen decreases.

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    TRAFITAL spa http://trafital.paginegialle.it/produzione-acciai-trafilati-rettificati.html 301, v. Colombo Tel 0331 368900 Fax 0331 368940 Since 1953 we have been manufacturing drawn bars in carbon and alloy steel in the following sections: flats up to 500x40mm, squares up to 150x150mm, hexagons up to 100mm, angles up to 100x100x10mm, T-sections, splined shafts, cold-drawn special section bars to customer’s design. Peeled-reeled and ground bars: rounds up to 160mm. TRAFITAL spa – certified to ISO 9000 by IGQ since 1994 – was the first Italian firm to specialize in a wide range of large- and special-size bars off the shelf ; radial-edged flat and square drawn bars to customer’s design; drawn steel sections for racks; narrow tolerances on ground bars up to h6 and tolerances on cold-drawn bars, including h9 tolerances for feather keys; fixed or precision length up to ± 1mm. – http://www.paginegialle.it/trafital

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