High performance composite slabs with profiled steel deck and Engineered Cementitious Composite – Strength and shear bond characteristics

•Development of composite slab using novel Engineered Cementitious Composite (ECC).•Conducted experimental and Code based theoretical investigations.•Variables include concrete/profiled steel deck type, shear span and shear connectors.•Performance evaluated based on strength, ductility and shear bond resistance. Composite slab/flooring system known as fast track construction with profiled steel deck and regular concrete topping is very popular. This paper presents the development and performance evaluation of a new high performance composite flooring system incorporating emerging green cost-effective Engineered Cementitious Composites (ECCs). The high strain capacity while maintaining low crack widths makes fiber reinforced an ideal durable material for the composite floor construction. The proposed ECC based composite floors can resolve the problems associated with regular concrete based composite floors. Experimental investigations as per current Standard Specifications accompanied by Code based theoretical investigations were conducted to evaluate the structural performance of such flooring system in the construction and service stages. Thirty full-scale composite slabs were fabricated and tested under simply supported four-point loading conditions. The variables in the tests included: two types of concrete (a green cost-effective ECC and a commercial self-consolidating concrete ‘SCC’), two types of profiled steel sheet/deck, five different shear span and presence/absence of stud shear connectors. The structural performance of ECC based composite slabs was compared with their SCC counterparts based on load-displacement response, shear load resistance, failure modes, strain development in concrete/steel, load-slip behaviour, ductility, energy absorbing capacity and steel-concrete shear bond resistance. ECC composite slabs have shown superior performance compared with their SCC counterparts in terms of strength, ductility, energy absorbing capacity and shear bond resistance.