Steels_ Metallurgy and Applications, Third Edition

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Low.carbon structural steels 151

By introducing a delay between roughing and finishing, rolling can be made to
take place at a temperature below 950"C, where the strain-induced precipitation
of Nb(CN) or TiC is sufficiently rapid to prevent recrystaUization before the next
pass. According to Cohen and Hansen, 11 austenite recrystaUization and carboni-
tride precipitation are interlinked during this process, substructural features in
the deformed austenite providing nucleation sites for carbonitride precipitation
which in turn pins the substructure and inhibits recrystallization. This results in
an elongated pancake morphology in the austenite structure and the austenite is
said to be conditioned. The deformation substructure that is introduced within
the austenite grains has a particularly beneficial effect in developing a finer grain
size. This arises from the fact that the substructure provides intragranular sites
for ferrite nucleation in addition to those at the austenite grain boundaries.
The controlled-rolling operation can be intensified by depressing the defor-
mation process below Ar3 and into the two-phase y + c~ region. In addition to
further grain refinement, rolling in this region also produces a significant change
in the microstructure. Thus a mixed structure is produced, consisting of polyg-
onal ferrite grains which have transformed from deformed austenite and deformed
ferrite grains which were produced during the rolling operation.

Transformation to ferrite

Although the mean ferrite grain size is related to the thickness of the pancaked
austenite grains, other factors also play an important part in the control of the
finished microstructure and properties. As discussed previously, alloying elements
depress the austenite to ferrite transformation temperature and thereby decrease
the ferrite grain size. A further important effect is the rate of cooling from the
austenite (or y + or) range and a combination of controlled rolling and accelerated
cooling is now being used to produce further improvement in properties.
The benefits of accelerated cooling can be used in two ways:



  1. To increase the strength compared with air-cooled, controlled-rolled material.


5OO

~.~ 450
oa
E
~400 alized
~" I ~/" / ~ ~ Controlled
350~ ~rolled (CR)
t CR + Accelerated
300 cooled

i I ...... I ..... I
0.3 0.35 0.4 0.45 0.5
Carbon equivalent

Figure 2.9 Exploitation of controlled rolling and accelerated cooling for improved prop-
erties in plate steels

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