| Summary: | In Canada, approximately 1 million tonnes of steel slag are produced annually, but, at
the present time, there is no economic outlet for the large scale recycling of this by-product.
The overall objective of this work was to determine whether steel slag might be processed
into a sufficiently cementitious material to allow it to be recycled as an additive to ordinary
Portland cement clinker. Blending steel slag with with clinker in a modest ratio of 1:10, it
would be possible to effectively recycle all of this steelmaking by-product. Although steel
slag has a composition which is similar to that of Portland cement, (consisting mainly of
lime, silica, and iron oxide), there are important compositional, mineralogical, and process
related differences. Steel slag has limited cementitious properties due to both a lack of
tricalcium silicate and the presence of wustite solid solutions as a predominant mineral
phase. Even though wustite (FeO) possesses no inherent cementitious properties, it has been
shown that hematite (Fe2C<3) will form hydraulic minerals when cooled from a slag melt.
Thus, the valence state of the iron oxide in slag and cement systems will directly influence
the cementitious properties of the material.
This work explores the effects of Fe oxidation state, overall composition, and cooling
rate on the mineral structure, crystalline formation, and glass forming ability of several
synthetic slags and one commercial BOF slag. XRD, SEM, and EDX analyses were
performed on both slow cooled and quenched slags, which had been oxidized. These
analyses, of both synthetic and commercial slag, suggest that the trivalent iron (Fe2C«3)
promoted both cementitious mineral formation in the slow cooled slags and glass formation
in the quenched slags. The rate of cooling directly influenced the crystalline formation and
mineral structure in the solidified product. The slow cooled slags tended to form highly
crystalline polycomponent mineral systems, whereas the rapidly cooled granulated slags
formed a predominantly amorphous material containing the primary Portland cement
minerals.This granulated slag product was blended with Portland cement in varying ratios and
hydrated to form cylindrical compression specimens. The preliminary compression results
indicate that, for a hydration period of 1 to 35 days, blends with a 10% slag addition had
increased strength relative to that of Portland cement. Blends with 20% slag maintained the
same strength as Portland cement, while those with a 45% slag addition exhibited a
significant loss in strength, for the hydration period tested. Therefore, the optimization of
certain slag processing conditions enhanced the cementitious nature of the material allowing
it to be blended with Portland cement, (at additions of up to 20% by weight), without
affecting the strength performance of the material. === Applied Science, Faculty of === Materials Engineering, Department of === Graduate
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