Abstract
This work aims to study the influence of using construction and demolition waste in the replacement of coarse and fine aggregate to produce recycled aggregate concrete (RAC). A moderate compressive strength concrete made with usual fine and coarse aggregate was used as a benchmark material. Compressive and split tensile tests were performed using 120 cylindrical concrete specimens with 150 mm diameter and 300 mm length. Four-point flexural tests in reinforced beams made with conventional concrete and RAC were performed. The results obtained showed that the use of recycled fine aggregates, in both percentages of substitution investigated—50% and 100%—did not generate any deleterious influence on the values of compressive strength and split tensile strength of the RACs produced. Tin fact, the mechanical strengths of RACs produced with recycled fine aggregate were equal or higher than those from the reference concrete. The same behavior was not observed, however, when the recycled coarse aggregate was used. For this case, decreases in concrete mechanical strengths were observed, especially in compressive strength, with values around 35% lower when compared to the reference concrete. Tensile mechanical tests results confirmed the excellent behavior of all RACs made with replacement of usual fine aggregates by recycled. Bending tests performed in reinforced RAC beams had as objective to evaluate the deformation profile of the beams. The obtained results showed that RAC beams with full replacement of usual fine aggregate by the recycled aggregates have presented little changes in the global behavior, an aspect that encourages its use.
Highlights
Urban development around the world, combined with inefficient management of public and private spaces plays an important role in the generation of construction and demolition waste (CDW)
The following conclusions can be drawn from the results of tests performed: Compressive strength ratios between recycled aggregate concrete (RAC) and natural aggregate concrete (NAC) indicated the following values: (a) 0.89 for RAC-F50; (b) 1.04 for RAC-F100; (c) 0.80 for RAC-G50; and (d) 0.64 for RAC-G100; Compressive mechanical tests results indicate that, unless those related with RAC made with full coarse usual aggregate substitution, all RACs investigated exhibited a good performance in terms of compressive strength compared to conventional concrete
This observation highlights the potential for recycled aggregates is substitution of usual aggregates without significant loss of performance; When one observes tensile strength ratios of RAC and NAC the following results were obtained: (a) 1.14 for RAC-F50; (b) 1.21 for RAC-F100; (c) 1.01 for RAC-G50 and (d) 0.79 for RAC-G100; Tensile mechanical tests results confirm the excellent behavior of all RACs investigated, even for those related with RAC made with full coarse usual aggregate substitution
Summary
Urban development around the world, combined with inefficient management of public and private spaces plays an important role in the generation of construction and demolition waste (CDW). Global demand for construction aggregates is forecast to rise by about 2.5% per year to approximately 48 billion metric tons in 2023 [4] This demand can be explained by several facts, among which stand out the continued strong growth in global construction activity, the rebound in global cement demand to build necessary infrastructure in several underdeveloped countries around the world [5]. This scenario points to the need to develop research to find technically and financially sustainable alternatives for the use of CDW. When one observes that the use of CDW is very incipient in most continents on the planet, representing less than 5% of worldwide aggregate demand [6,7], it becomes clear the great potential of this emerging market
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