The effects of a Mo addition on both the precipitation kinetics and high-temperature strength of a Nb carbide have been investigated in the hot-rolled high-strength, low-alloy (HSLA) steels containing both Nb and Mo. These steels were fabricated by four-pass hot rolling and coiling at 650°C, 600°C, and 550°C. Microstructural analysis of the carbides has been performed using field-emission gun transmission electron microscopy (TEM) employing energy-dispersive X-ray spectroscopy (EDS). The steels containing both Nb and Mo exhibited a higher strength at high temperatures (∼600 °C) in comparison to the steel containing only Nb. The addition of Mo increased the hardenability and led to the refinement of the bainitic microstructure. The proportion of the bainitic phase increased with the increase of Mo content. The TEM observations revealed that the steels containing both Nb and Mo exhibited fine (<10 nm) and uniformly distributed metal carbide (MC)-type carbides, while the carbides were coarse and sparsely distributed in the steels containing Nb only. The EDS analysis also indicated that the fine MC carbides contain both Nb and Mo, and the ratio of Mo/Nb was higher in the finer carbides. In addition, electron diffraction analysis revealed that most of the MC carbides had one variant of the B-N relationship ((100)MC//(100)ferrite, [011]MC//[010]ferrite) with the matrix, suggesting that they were formed in the ferrite region. That is, the addition of Mo increased the nucleation sites of MC carbides in addition to the bainitic transformation, which resulted in finer and denser MC carbides. It is, thus, believed that the enhanced high-temperature strength of the steels containing both Nb and Mo was attributed to both bainitic transformation hardening and the precipitation hardening caused by uniform distribution of fine MC particles.
[1]
Masatomo Yoshida,et al.
Fire Resistance of Fire‐Resistant Steel Columns
,
1994
.
[2]
R. Chijiiwa,et al.
AP-FIM study on the effect of Mo addition on microstructure in Ti-Nb steel
,
1994
.
[3]
J. Jonas,et al.
Effect of vanadium and molybdenum addition on high temperature recovery, recrystallization and precipitation behavior of niobium-based microalloyed steels
,
1983
.
[4]
A. Brownrigg,et al.
Fire resistant high strength low alloy steels
,
1990
.
[5]
S. Keown,et al.
The orientation relationship and growth direction of Mo2C in ferrite
,
1966
.
[6]
R. D. Pehlke,et al.
Nitrogen solubility and nitride formation in austenitic Fe-Ti alloys
,
1985
.
[7]
Y. Sakumoto,et al.
High‐Temperature Properties of Fire‐Resistant Steel for Buildings
,
1992
.
[8]
Y. Cho,et al.
Effect of controlled cooling on the formability of TS 590 MPa grade hot-rolled high strength steels
,
1999
.
[9]
T. Gladman.
The Physical Metallurgy of Microalloyed Steels
,
1997
.
[10]
F. Froes,et al.
Conditions controlling matrix and stacking fault precipitation
,
1967
.