Compressive strength development and durability of an environmental load-reduction material manufactured using circulating fluidized bed ash and blast-furnace slag

Abstract

The aim of this study is to investigate the compressive strength and durability of zero-cement mortar fabricated using 100% by-products by incorporating circulating fluidized bed ash (CFB), blast-furnace slag (BFS), and recycled aggregates. CFB can potentially react as an alkali activator with BFS. The compressive strength of zero-cement mortar with an optimal mix proportion of CFB:BFS=75:25 can reach approximately 28MPa after 91days of curing, which is mainly dependent on the curing temperature, water-to-binder ratio, and aggregate type, but not the curing environment. Moreover, for the sake of application to building construction, the strength can be enhanced to 40MPa after 28days and 50MPa after 91days by maintaining a 40% water-to-binder ratio and incorporating BFS with a fineness of 600m2/kg, 2.5% calcium sulfate (CS), and 6% Ca(OH)2. CFB-based zero-cement mortar shows a tendency to improve the chloride diffusion suppression, frost resistance, and carbonation resistance when the water-to-binder ratio is reduced. Furthermore, the investigated zero-cement mortar presents excellent sulfuric acid resistance compared with the cement-based mortar. Although the use of zero-cement mortar is currently limited, the manufactured product is considered to have a potential application as an environmental load-reduction material.