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Stainless Steel
   
303 Stainless Steel
304 Stainless Steel
309 Stainless Steel
310 Stainless Steel
316 Stainless Steel
347 Stainless Steel
410 Stainless Steel
2205 Duplex Stainless Steel Bar
416 Stainless Steel
420 Stainless Steel
440 Stainless Steel
13-8Mo Stainless Steel
15-5PH Stainless Steel
17-4PH Stainless Steel

 

310 Stainless Steel
 

Specifications

The following specifications cover Stainless Steel 310

  • AISI 310
  • AMS 5577 (Round Tube- Welded)
  • AMS 5651
  • ASTM A167
  • ASTM A182 (Forging - Open Die)
  • ASTM A213
  • ASTM A249
  • ASTM A276
  • ASTM A314
  • ASTM A358 (Pipe- Welded)
  • ASTM A403
  • ASTM A409 (Pipe- Welded)
  • ASTM A473 (Forging - Open Die)
  • ASTM A479
  • ASTM A580
  • ASTM A632
  • DIN 1.4841
  • QQ S763
  • QQ S766
  • UNS S31000

Related Metals: 2RE10 (tm)

Chemistry Data :

Carbon 0.25 max
Chromium 24 - 26
Iron Balance
Manganese 2 max
Nickel 19 - 22
Phosphorus 0.045 max
Silicon 1.5 max
Sulphur 0.03 max
Principal Design Features The strength of this alloy is a combination of good strength and corrosion resistance in temperatures up to 2100 F (1149 C). Due to its relatively high chromium and nickel content it is superior in most environments to 304 or 309 stainless.
Applications Oven linings, boiler baffles, kilns, lead pots, radiant tubes, annealing covers, saggers, burners, combustion tubes, refractory anchor bolts, fire box sheets, furnace components and other high temperature containers.
Machinability This alloy machines similarly to type 304 stainless. Its chips are stringy and it will work harden rapidly. It is necessary to keep the tool cutting at all times and use chip breakers.
Welding Most of the austenitic stainless steels can be readily welded using fusion or resistance methods. Oxyacetylene welding is not recommended. Filler metal should be AWS E/ER 310.
Hot Working Most common hot work methods can be successfully performed after uniform heating to 2150 F (1177 C). Do not forge below 1800 F (982 C). Rapid cooling is required to maximize corrosion resistance.
Cold Working Although this alloy has a high work hardening rate, it can be drawn, headed, upset, and stamped. Full annealing is required after cold work to remove internal stress.
Annealing 1900-2050 F (1038-1121 C) water quench.
Hardening This alloy does not respond to heat treatment. Cold work will cause an increase in both hardness and strength.


Physical Data :

Density (lb / cu. in.) 0.289
Specific Gravity 7.9
Specific Heat (Btu/lb/Deg F - [32-212 Deg F]) 0.12
Electrical Resistivity (microhm-cm (at 68 Deg F) 468
Melting Point (Deg F) 2650
Modulus of Elasticity Tension 30