Abstract
In the experiment, the aluminosilicate glasses with aluminum saturation index (ASI), defined as the Al2O3/(Na2O+K2O+2CaO), equal to 0.74, 1.72. 2.52, or 4.05 were synthesized. The spectroscopy tests (MIR and 27Al MAS-NMR) confirm that in glass with ASI < 1, the aluminum ions occur in the [AlO4]5- only. In glasses with ASI > 1, the aluminum ions create mainly [AlO4]5-, but part of them occurs in the form of [AlO6]9-. The content of [AlO6]9- octahedrons increases successively for ASI from 1.72 to 4.05. Glass with ASI equal to 4.05 demonstrates the highest content of pozzolanic active Al2O3. Model ashes were prepared by mixing 70 wt.% of glass, 20 wt.% of synthetic mullite and 10 wt.% of SiO2 as an equivalent of quartz. Then Portland cement CEM I 42.5R was milled together with 20 wt.% of each of model ashes to Blaine’s specific surface area of 4,200±50 cm2 g-1. It was found that the addition of ash with higher content of [AlO6]9- octahedrons in the structure of glass accelerates the hydration process of cement blend, which, in turn, positively affects its usable features (heat of hydration, initial setting time and compressive strength). According to the requirements of PN-EN 197-1:2012 standard, the introduction of ash with ASI coefficient equal to 4.05 gives cement blend of strength class of 52.5N. Cement blends with the ash of ASI value equal to 1.72 and 2.52 correspond to strength class of 32.5R, whereas the cement blend with the ash of ASI value equal to 0.74 does not achieve the minimum value of strength for any cement strength class. Results show that the change in chemical composition of fly ash glass and resulting from this diversified structure are essential from the point of view of hydration and properties of cement containing fly ashes in its composition.
Highlights
Fly ashes constitute basic by-products which are formed in process of coal dust combustion in furnaces of power and heat and power generating stations
Examinations carried out by the method described in PN-EN 196-2:2013 standard (Ref 27) demonstrate that the content of reactive SiO2, i.e., the silica reacting under normal conditions with Ca(OH)[2], decreases successively in glasses with a higher aluminum saturation index (ASI) coefficient (Table 3)
Results of microcalorimetric measurements of examined Portland-fly ash cement pastes confirm that the coordination of aluminum ions in glassy constituent in fly ash has a strong influence on the degree of cement hydration
Summary
Fly ashes constitute basic by-products which are formed in process of coal dust combustion in furnaces of power and heat and power generating stations For many years, they have been a valuable mineral additive used in the production of cement, multicomponent binding agents and concrete. Previous studies indicate that the properties of fly ashes depend on many factors such as fineness (especially the contribution of grain size below 10 lm), chemical composition (silica and alumina contents), and mineralogy and amorphousness of fly ashes (Ref 1-4). These parameters influence the pozzolanic reactivity of fly ashes and the hydration process of cement blend with fly ashes. This is because fine-grain fractions of fly ashes are characterized by a higher content of glassy constituent, while a portion of crystalline phases is lower
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