Experimental and numerical investigation of influence of air-voids on the compressive behaviour of foamed concrete

A combined experimental and numerical approach is proposed in this study for the characterisation of the mechanical behaviour of foamed geopolymer concretes. Advanced experimental techniques employing X-Ray CT give both microstructures and mechanical responses of a range of geopolymer concretes with...

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Bibliographic Details
Published in:Materials & design 2017-09, Vol.130, p.103-119
Main Authors: Nguyen, Thang T., Bui, Ha H., Ngo, Tuan D., Nguyen, Giang D.
Format: Article
Language:English
Subjects:
Air-void
Discrete element method (DEM)
Foamed concrete
Strength prediction
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Summary:A combined experimental and numerical approach is proposed in this study for the characterisation of the mechanical behaviour of foamed geopolymer concretes. Advanced experimental techniques employing X-Ray CT give both microstructures and mechanical responses of a range of geopolymer concretes with varying densities. In parallel with this, a numerical modelling technique based on the discrete element method (DEM) is developed for explicit descriptions of air-void distribution, while the mortar binder is described at the micro/meso scale with cohesive behaviour. The calibrated and validated DEM model is then used to systematically study the effects of air-void content, air-void distribution and microstructural parameters, including particle size and porosity on the compressive strength of foamed concretes. A non-linear relationship between the compressive strength and porosity of foamed concretes is found from DEM simulations, which are consistent with our experimental findings and existing strength-porosity models. Furthermore, it is found that the air-void distribution has a significant influence on the compressive strength of foamed concretes, while the micro-void structure has less effect on the loading bearing capacity of the material. The proposed combined approach demonstrates the tight correlations between experimental and numerical techniques in characterising the mechanical behaviour of foamed concretes for practical design purposes. [Display omitted] •A combined experimental-numerical approach can further the characterisation of foamed concretes with varying densities.•Porosity and types of air voids in a foamed concrete can have a profound effect on its mechanical properties.•DEM analyses indicate that local pore collapse and macro shear failure compete to govern the response of foamed concrete.•DEM simulations could provide consistent numerical data for the development of a better strength-porosity model.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2017.05.054