280 Steels: Metallurgy and Applications
of about 850~ prior to oil quenching. Tempering at 550-650~ then produces
tensile strengths in the range 800-1100 N/mm 2. However, in the mid-1970s,
German manufacturers demonstrated that these strength levels could be produced
in a micro-alloy, medium-carbon steel (49 MnVS3) after air cooling from the
forging operation, thus eliminating the need for heat treatment. Since that time,
major effort has been devoted to the development of micro-alloy forging steels in
Europe and Japan and these steels have gradually been introduced as substitutes
for quenched and tempered steels in some automotive components.
Metallurgical considerations
As indicated in earlier chapters, niobium, titanium and vanadium are used as
micro-alloying elements in low-carbon steels, although high soaking tempera-
tures must be employed in order to achieve substantial solution of Nb(CN), TiC
and TiN. However, vanadium has a high solubility in austenite, regardless of
the carbon content, and is therefore the most suitable micro-alloying element
for medium-carbon steels. On cooling from the solution treatment temperature,
vanadium carbonitride precipitates in both the proeutectoid ferrite and the ferrite
lamellae of the pearlite. The physical metallurgy of these steels has been reviewed
by Gladman. 46
As illustrated in Figure 3.43, the tensile properties of these grades increase
progressively with vanadium content and, depending upon the levels of strength
required, vanadium contents in the range 0.05-0.2% are employed. The level
of precipitation strengthening is also influenced by the nitrogen content and
Figure 3.43
Mn steel
1000
800
E 600
v
" 400
if)
200
0
0
25
A
El ,--
2o "~ N
e-
_15 W
, I I. 10
0.05 0.10 0.15
Vanadium (%)
Effect of vanadium on the tensile properties of air-cooled 0.45% C 0.9%