Effect of process parameters on surface oxides on chromium-alloyed steel powder during sintering
Journal article, 2013
The use of chromium in the PM steel industry today puts high demands on the choice and control of the
atmosphere during the sintering process due to its high affinity to oxygen. Particular attention is required
in order to control the surface chemistry of the powder which in turn is the key factor for the successful
sintering and production of PM parts. Different atmosphere compositions, heating rates and green
densities were employed while performing sintering trials on water atomized steel powder pre-alloyed
with 3 wt.% Cr in order to evaluate the effect on surface chemical reactions. Fracture surfaces of sintered
samples were examined using high resolution scanning electron microscopy combined with X-ray
microanalysis. The investigation was complemented with thermogravimetric (TG) studies. Reaction
products in particulate form containing strong-oxide forming elements such as Cr, Si and Mn were
formed during sintering for all conditions. Processing in vacuum results in intensive inter-particle neck
development during the heating stage and consequently in the excessive enclosure of surface oxide
which is reflected in less good final mechanical properties. Enhanced oxide reduction was observed in
samples processed in hydrogen-containing atmospheres independent of the actual content in the range
of 3e10 vol.%. An optimum heating rate was required for balancing reduction/oxidation processes. A
simple model for the enclosure and growth of oxide inclusions during the sinter-neck development is
proposed. The obtained results show that significant reduction of the oxygen content can be achieved by
adjusting the atmosphere purity/composition.
oxidation
powder metallurgy
oxide
sintering