Abstract
Compressive strength is an important property in construction material, particularly for thermal insulation purposes. Although the insulation materials possess high fire-retardant characteristics, their mechanical properties are relatively poor. Moreover, research on the correlation between fire-retardant and compressive strength of rice husk ash (RHA)-based geopolymer binder (GB) is rather limited. In addition, previous studies on RHA-based GB used the less efficient one-factor-at-a-time (OFAT) approach. In understanding the optimum value and significant effect of factors on the compressive strength, it was deemed necessary to employ statistical analysis and a regression coefficient model (mathematical model). The objective of the study is to determine the effect of different material behavior, namely brittle and ductile, on the compressive strength properties and the optimum material formulation that can satisfy both compressive strength and fire-retardant properties. The factors chosen for this study were the rice husk ash/activated alkaline solution (RHA/AA) ratio and the sodium hydroxide (NaOH) concentration. Compressive strength and fire-retardant tests were conducted as part of the experiments, which were designed and analyzed using the response surface methodology (RSM). The microstructure of geopolymer samples was investigated using a scanning electron microscope (SEM). Results showed that RHA/AA ratio was highly significant (p < 0.000) followed by NaOH concentration (p < 0.024). When the RHA/AA ratio was at 0.7 to 0.8 and the NaOH concentration was between 12 and 14 M, high compressive strength above 28 MPa was recorded. Optimum compressive strength of approximately 47 MPa was achieved when the RHA/AA ratio and NaOH concentration were 0.85 and 14 M, respectively. Brittle samples with low Si/Al ratio of 88.95 were high in compressive strength, which is 33.55 MPa, and showed a high degree of geopolymerization. Inversely, ductile samples showed low compressive strength and degree of geopolymerization. Water content within the geopolymer binder had a major effect on its fire-retardant properties. Semi-ductile GB showed the best fire-retardant properties, followed by semi-brittle and brittle GB. Using RHA as an aluminosilicate source has proven to be a promising alternative.
Highlights
Geopolymer is known for good mechanical properties and high early-aged strength.One of the properties is compressive strength
The potential advantages of rice husk ash (RHA)-based geopolymer material in enhancing its mechanical and thermal properties are mainly associated with rice husk (RH) with high silica content
The results show that higher porosity of the binders will result in lower compressive strength and vice versa
Summary
Geopolymer is known for good mechanical properties and high early-aged strength. One of the properties is compressive strength. The potential advantages of rice husk ash (RHA)-based geopolymer material in enhancing its mechanical and thermal properties are mainly associated with rice husk (RH) with high silica content. Compared to fly ash (FA) or other aluminosilicate sources, RHA contained the highest silica between 85.0% and. Higher loading of RHA will result in higher silica content. Higher silica and lower alumina content mean higher silica to alumina (Si/Al) ratio. Higher mechanical strength can be achieved, as proved by Komnitsas and Zaharaki [1] and De Silva, et al [2]. Higher Si/Al ratio proved to provide higher compressive strength, a further increase in Si/Al ratio leads to a decrease in compressive strength, as studied by Songpiriyakij, et al [3]. Geopolymer with a Si/Al ratio exceeding 24 may become more elastic and deform than brittle, failing under certain forces [4]
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