Selection of stainless steels for cryogenic applications_toughness

Selection of stainless steels

Affect of steel structure on toughness

The toughness of the austenitics relies on their fcc atomic structure. The presence of either ferrite or martensite can limit the cryogenic usefulness of the austenitic stainless steels.
The small levels of ferrite usually present in wrought austenitics is not usually detrimental.

Cold working of austenitic stainless steels can also affect their cryogenic toughness.
This is due to the progressive formation of martensite from the ‘meta-stable‘ austenite. In effect this is similar to the presence of ferrite and can be controlled in the same way through compositional changes that stabilise the austenite.
In addition the effects of cold work can be removed by heat treatment. Solution annealing (softening) by heating to around 1050 / 1100 °C and cooling in air, depending on section size, will completely stress relieve the structure and transform the structure back the naturally tough austenitic one.

Welded areas may be at risk of brittle failure at very low temperatures, as ferrite levels in welds are higher than the surrounding wrought steel (to avoid hot cracking on solidification).
Special low ferrite level welding consumables are available for cryogenic applications and should be considered for very low, safety critical, temperature applications.

Castings compositions for austenitic stainless steel also have ferrite levels higher than the corresponding wrought grades BS3100 – Steel Castings for General Engineering Purposes, requires special impact tests at -196°C for the cryogenic application grades such as 304C12LT196. Although there are no major restrictions on composition, this grade is required to meet an additional Charpy impact test requirement of 41 Joules minimum at -196°C

Impact toughness of austenitic stainless steels

When austenitic stainless steels are Charpy tested at -196°C the test piece is usually ductile enough not to fracture (which actually invalidates the test).

Data available however quotes impact energies of over 130J for the 304 (1.4301) type. This is well within the 60-Joule minimum required in BS EN 10028-7 pressure vessel standard for 304 (1.4301) at -196°C.
Any of the austenitic stainless steels should be suitable for applications at these temperatures. The best choices of grades for very low temperatures are those with austenite stabilising additions such as nitrogen e.g. asi n grade 304LN (1.4311). (Higher alloy grades such as 310 (1.4845) or 904L (1.4539) which derive their austenite stability from higher nickel levels could also be considered)

Wrought grades with ferrite stabilising additions such as 321 (1.4541) or 347 (1.4550) may not be suitable at very low temperatures e.g. at the liquid helium boiling point of -269°C.

Impact toughness of other stainless steels

The ferritic, martensitic and duplex stainless steels cannot be considered as cryogenic steels.
Their impact characteristics change at sub-zero temperatures in a similar way to low alloy steels. The transition temperatures will depend on composition and heat treatment.

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