Abstract
A gradation pattern in the strength of concrete columns is unavoidable due to the presence of static and dynamic segregation. The effect of concrete uniformity on columns subjected to monotonic lateral load is investigated experimentally in this study. Reinforced concrete columns with cross-sectional dimensions of 150 x 150 mm and a height of 1000 mm are prepared as graded concrete column (GCC) specimens and controlling specimens. The columns are designed with a reinforcement ratio of 1%. Two concrete mixes with a strength of 20 MPa and 30 MPa are cast in moulds using the gradual compaction procedure to create a satisfactory strength transition throughout the specimens’ height. The resulting lateral deformation and resisting load are utilised for further analysis. The analyses show that the GCC exhibits a lower peak load and lateral deformation than the control specimen, and a distinct failure mode is observed. The GCC also shows more brittle behaviour in the post-peak region.
Highlights
Concrete is a composite material that is generally used for construction due to its ease of design and application of structural elements
Dynamic segregation arises from the effects of compaction procedures that cause the coarse aggregate to gravitationally sink to the bottom part
The column is subjected to a monotonic lateral load; and the load carrying capacity, translation, and the failure modes are compared to the controlling specimen
Summary
Concrete is a composite material that is generally used for construction due to its ease of design and application of structural elements. Previous studies show that the height-towidth ratio of concrete elements affects the material’s homogeneity because of the presence of segregation. There are two types of segregation, namely dynamic segregation and static segregation. Dynamic segregation arises from the effects of compaction procedures that cause the coarse aggregate to gravitationally sink to the bottom part. Static segregation happens immediately when concrete is cast. Static segregation is highly influenced by the dimension ratio of the elements and the characteristics of the concrete mix. The high use of a water-to-content ratio, for example, will result in a high fluidity of the concrete mix but a loss of viscosity
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