Steels_ Metallurgy and Applications, Third Edition

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Stainless steels 301

..... , ,. .,,, .=, ,,,, , .,..

25 Austenite

.. 20
\ \ / ,u,,oo,to
15- ~. Austenite~ / .+.
+ ~ / 840rrite

Z --
5 -- Nartensite

0 I I ,I , , I ,,, I , ,,I ,,
0 5 10 15 20 25 30 35 40
Chromium equivalent (%)

Figure 4.7 Schaeffler diagram-modified (After Schneider 3)

In a similar manner, the austenite-forming elements are expressed in terms of a
nickel equivalent:


Ni equivalent = (Ni) + (Co) + (0.5Mn) + (0.3Cu) + (25N) + (30(2)

all concentrations being expressed as weight percentages.

Commercial grades of stainless steels


From the foregoing remarks, it can be appreciated that stainless steels embrace
a wide range of microstructures which are controlled by means of a complex
relationship with composition. Although chromium may be the principal alloying
element in a stainless steel, the level may give little indication of structure, and
steels containing 17% Cr can be martensitic, ferritic or austenitic, depending on
heat treatment and the presence of other elements. In discussing the characteristics
of stainless steels, it is therefore more convenient to categorize these materials
in terms of microstructure rather than composition.
Although most industrialized countries have developed their own national
standards for stainless steels, these steels are referred to almost universally
by means of the American Iron and Steel Institute (AISI) numbering system.
Thus the martensitic stainless steels are classified as the 400 series but, rather
confusingly, the 400 series also includes the fetritic grades of stainless steel. The
more important grades of austenitic stainless steel are classified in the 300 series.
The nominal compositions of the common stainless grades, according to the AISI
numbering system, are shown in Table 4.2. In the UK, the familiar specification
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