8 research outputs found
Influence of aggregate size and fraction on shrinkage induced micro-cracking of mortar and concrete
In this paper, the influence of aggregate size and volume fraction on
shrinkage induced micro-cracking and permeability of concrete and mortar was
investigated. Nonlinear finite element analyses of model concrete and mortar
specimens were performed. The aggregate diameter was varied between 2 and 16
mm. Furthermore, a range of volume fractions between 0.1 and 0.5 was studied.
The nonlinear analyses were based on a 2D lattice approach in which aggregates
were simplified as monosized cylindrical inclusions. The analysis results were
interpreted by means of crack width and change of permeability. The results
show that increasing aggregate diameter (at equal volume fraction) and
decreasing volume fraction (at equal aggregate diameter) greatly increases
permeability.Comment: 12th International Conference on Fracture (ICF 12
The steel–concrete interface
Although the steel–concrete interface (SCI) is widely recognized to influence the durability of reinforced concrete, a systematic overview and detailed documentation of the various aspects of the SCI are lacking. In this paper, we compiled a comprehensive list of possible local characteristics at the SCI and reviewed available information regarding their properties as well as their occurrence in engineering structures and in the laboratory. Given the complexity of the SCI, we suggested a systematic approach to describe it in terms of local characteristics and their physical and chemical properties. It was found that the SCI exhibits significant spatial inhomogeneity along and around as well as perpendicular to the reinforcing steel. The SCI can differ strongly between different engineering structures and also between different members within a structure; particular differences are expected between structures built before and after the 1970/1980s. A single SCI representing all on-site conditions does not exist. Additionally, SCIs in common laboratory-made specimens exhibit significant differences compared to engineering structures. Thus, results from laboratory studies and from practical experience should be applied to engineering structures with caution. Finally, recommendations for further research are made
3D imaging techniques for characterising microcracks in cement-based materials
Concrete inherently contains pores and microcracks that can adversely impact its mechanical properties and long-term durability. However, characterising microcracks is difficult due to their complex, multiscale and three-dimensional (3D) nature. This paper presents an evaluation of 3D imaging techniques for characterising microcracks induced by different mechanisms. Seven cement pastes, mortars and concretes subjected to drying shrinkage, autogenous shrinkage and freeze-thaw cycles were investigated using focused ion beam nanotomography (FIB-nt), broad ion beam serial section tomography (BIB-SST), laser scanning confocal microscopy (LSCM) combined with serial sectioning and X-ray microtomography (µCT). The study shows that the characteristics of microcracks vary significantly depending on exposure conditions. Yet there is no single technique that can capture the entire size range of microcracks from sub to tens of µm within a sufficiently representative sampling volume. The achievable image volume and resolution, and the advantages and disadvantages of each technique are compared and discussed.M.J. Mac acknowledges the funding from the European Union Seventh Framework Programme under grant agreement 264448. We thank Dr. Trifon Trifonov from Universitat Politècnica de Catalunya (UPC) and Dr. Lidija Korat from the Slovenian National Building and Civil Engineering Institute (ZAG) for their assistance with the Zeiss Neon 40 cross beam and the Xradia MicroXCT-400 respectively. We also thank the Natural History Museum, Zeiss (Cambridge, UK) and FEI (Houston, USA) for providing X-ray μCT scans with the Metris X-Tek HMX ST 225, Xradia 520 Versa and Helican microCT respectively.Peer ReviewedPostprint (author's final draft
Influence of aggregate size and volume fraction on shrinkage induced micro-cracking of concrete and mortar
In this paper, the influence of aggregate size and volume fraction on shrinkage induced micro-cracking and permeability of concrete and mortar was investigated. Nonlinear finite element analyses of model concrete and mortar specimens with regular and random aggregate arrangements were performed. The aggregate diameter was varied between 2 and 16 mm. Furthermore, a range of volume fractions between 0.1 and 0.5 was studied. The nonlinear analyses were based on a 2D lattice approach in which aggregates were simplified as monosized cylindrical inclusions. The analysis results were interpreted by means of crack length, crack width and change of permeability. The results show that increasing aggregate diameter (at equal volume fraction) and decreasing volume fraction (at equal aggregate diameter) increase crack width and consequently greatly increases permeability