Sj. Seo et al., EVALUATION OF SUSCEPTIBILITY TO SURFACE HOT SHORTNESS IN CU-CONTAINING STEELS BY TENSILE TEST, ISIJ international, 37(3), 1997, pp. 232-239
The feasibility of a new method for evaluating the susceptibility of s
teels to surface hot shortness due to Cu and Sn was examined. Steels u
sed are IF steels containing 0.1-0.2%Cu and 0.1%C-0.5%Cu steels. Chemi
cal compositions of the IF steels were controlled with the purpose of
being as similar as possible to those of steels of which the susceptib
ility was previously examined by a visual method in a practical rollin
g process at Nippon Steel Corporation. Tensile tests were carried out
at 1100 degrees C after heating a specimen in air or Ar gas. The total
elongation and maximum load were measured from a load-elongation curv
e. By dividing the difference between the total elongations or maximum
loads obtained in air and Ar gas by the total elongation or maximum l
oad in Ar gas, the parameters Ee or Ep were calculated. By considering
the reduction in specimen diameter due to oxidation, the Ep corrected
, Ep', was calculated. The Ee, Ep and Ep' of the IF steels corresponde
d to the degree of surface cracks observed in the practical rolling pr
ocess. Penetration of Cu-enriched phase into grain boundaries tends to
occur under thermal and external stresses. Surface cracks stop growin
g along the depth direction at the earlier stage of deformation when t
he amount of Cu-enriched phase is the smaller at steel/scale interface
. Tensile tests using specimens having artificial round cracks clarifi
ed that the Ee and Ep' increased with an increase in the crack depth a
nd that, in contrast, the Ep' increased slightly and the Ee decreased
with an increase in the number of cracks. The parameter Ee and Ep' sho
wed a maximum value at a strain rate of around 3x10(-2)s(-1), and the
difference in their values among the steels is largest around this str
ain rate. Therefore it is possible to know sensitively the effects of
any factors like alloying or impurity elements on surface hot shortnes
s at around this strain rate although this strain rate is much slower
than those of hot workings.