Abstract
One of the most important topics in solid mechanics is the study of the so-called size effects, whose importance has been widely recognised during the last decades. Size effects are particularly strong in quasi-brittle (i.e., concrete-like) materials. In this paper we focus our attention on the tensile strength decrease associated with the size of concrete structures. An original explanation of this well-known size effect was proposed by the first Author based on the assumption of a fractal-like damage localisation at the mesostructural level. This hypothesis leads to a multifractal scaling law (MFSL) for concrete tensile strength. The present contribution provides a scaling law for concrete tensile strength based on its aggregate size distribution. Since the weakest link in normal strength concrete is represented by the interface between the cementitious matrix and the aggregates, it seems reasonable to look for a relationship between the aggregate grading and the material strength. Based on the hypothesis that the strength depends on the largest flaw, we compute the strength of a concrete specimen as a function of its size. Differently from other statistical approaches, we use a truncated distribution (namely the Füller distribution) in order to describe realistically the flaw population inside the specimen. Calculating the distribution of the largest flaw size by means of statistics of extremes, and relating it to the specimen size, we obtain a scaling law for concrete tensile strength whose trend strictly agrees with the MFSL. Finally, we pay particular attention to the computation of the power law exponent characterising the strength scaling at the smallest sizes and present a comparison with available experimental data.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Carpinteri, A. and Ferro, G. (1994). Size effects on tensile fracture properties: a unified explanation based on disorder and fractality of concrete microstructure. Materials and Structures 28, 563-571.
Carpinteri, A. (1994a). Fractal nature of material microstructure and size effects on apparent mechanical properties. Mechanics of Materials 18, 89-101.
Carpinteri, A. (1994b). Scaling laws and renormalization groups for strength and toughness of disordered materials. International Journal of Solids and Structures 31, 291-302.
Carpinteri, A., Chiaia, B. and Nemati, K.M. (1997a). Complex fracture energy dissipation in concrete under different loading conditions. Mechanics of Materials 26, 93-108.
Carpinteri, A. and Chiaia, B. (1997b). Multifractal scaling laws in the breaking behaviour of disordered materials. Chaos, Solitons and Fractals 8, 135-150.
Carpinteri, A., Ferro, G. and Invernizzi, S. (1997c). The nominal tensile strength of disordered materials: a statistical fracture mechanics approach. Engineering Fracture Mechanics 58, 421-435.
Carpinteri, A., Chiaia, B. and Invernizzi, S. (1999). Three-dimensional fractal analysis of concrete fracture at the meso-level. Theoretical and Applied Fracture Mechanics 31, 163-172.
Carpinteri, A. and Invernizzi, S. (2001). Influence of damage on the fractal properties of concrete subjected to pure tension. Materials and Structures (R.I.LE.M.) 34, 605-611.
Carpinteri, A., Chiaia, B. and Cornetti, P. (2002a). A scale-invariant cohesive crack model for quasi-brittle materials. Engineering Fracture Mechanics 69, 207-217.
Carpinteri, A. and Cornetti, P. (2002b). A fractional calculus approach to the description of stress and strain localization in fractal media. Chaos, Solitons and Fractals 13, 85-94.
Carpinteri, A. and Cornetti, P. (2002c). Size effects on concrete tensile fracture properties: an interpretation of the fractal approach based on the aggregate grading. Journal of the Mechanical Behaviour of Materials 13, 233-246.
Carpinteri, A., Chiaia, B. and Cornetti, P. (2003). On the mechanics of quasi-brittle materials with a fractal microstructure. Engineering Fracture Mechanics, in press.
Gumbel, E.J. (1958). Statistics of extremes. Columbia University Press, New York.
Hillerborg, A., Modéer, M. and Petersson, P.E. (1976). Analysis of crack formation and crack growth in concrete by means of fracture mechanics and finite elements. Cement and Concrete Research 6, 773-782.
van Mier, J.G.M. and van Vliet, M.R.A. (1999). Effect of strain gradients on the size effect of concrete in uniaxial tension. International Journal of Fracture 94, 195-219.
Stroeven, P. (2000). A stereological approach to roughness of fracture surfaces and tortuosity of transport paths in concrete. Cement and Concrete Composites 22, 331-341.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Carpinteri, A., Cornetti, P. & Puzzi, S. A stereological analysis of aggregate grading and size effect on concrete tensile strength. International Journal of Fracture 128, 233–242 (2004). https://doi.org/10.1023/B:FRAC.0000040986.00333.86
Issue Date:
DOI: https://doi.org/10.1023/B:FRAC.0000040986.00333.86