Abstract
There are currently still some sustainability-related issues that need to be tackled within the construction sector. Namely, cement production is accountable for nearby 5% of the worldwide total CO2-eq release. Therefore, environmentally viable and economically sustainable solutions need to be pursued in order to mitigate the use of Portland cement. The incorporation of industrial waste in concrete compositions, such as fly ash (from coal combustion in power stations) is a feasible alternative. The properties of these residues may be enhanced through alkaline activation, which is able to yield aluminosilicate-based materials with excellent physico-chemical properties. Nonetheless, these materials exhibit a brittle behaviour. Therefore, the present work addresses the study of alkali-activated composites reinforced with sisal fibres. For that purpose, alkali-activated Class F fly ash was mixed with natural fibres and the composite mechanical behaviour was assessed through both indirect tensile and compressive tests. Four different fibre contents, in wt % of fly ash (0, 0.2, 0.6 and 1%), two fibre lengths (13 and 50 mm) and four curing periods (14, 28, 56 and 112 days) were considered. Results confirm that the post-cracking response of these composites was improved with the inclusion of sisal fibres. In general, higher residual tensile strengths and dissipated energy were observed for the lengthier fibres, i.e., 50 mm.
Highlights
It is widely acknowledged that, nowadays, a strong commitment should be embraced to develop more sustainable materials for the construction industry
The results show that, in general, the indirect tensile strength increased with the fibre content with the exception of the series regarding the 14 days, in which the increase of fibre content favoured a the exception of the series regarding the 14 days, in which the increase of fibre content favoured decrease of the indirect tensile strength
The compressive strength increased with the curing time
Summary
It is widely acknowledged that, nowadays, a strong commitment should be embraced to develop more sustainable materials for the construction industry. Portland cement is itself responsible for about 5% of the global production of CO2 [1]. One of the major challenges, if not the greatest considering its wide use, is to find binder materials that could compete with Portland cement. It is recognized that alkaline activation is a valid process to produce alternative binders using industrial by-products as raw material. This chemical process, which implies the existence of a precursor rich in aluminosilicates and Fibers 2018, 6, 30; doi:10.3390/fib6020030 www.mdpi.com/journal/fibers
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