INFLUENCE OF GALVANISED IRON AND POLYPROPYLENE FIBERS ON THE PROPERTIES OF RECYCLED AGGREGATE CONCRETE

Abstract

Significant amount of concrete waste generates every day from construction and demolition (C&D) works and has become a global concern from environmental perspective. Recycled aggregate produced from these C&D waste can be used as an alternative material for natural aggregate (NA) which has finite resources. Recycled aggregate (RA) has lower density, higher water absorption, lower mechanical properties compared to normal aggregate (NA). Inclusion of fiber along with RA in concrete mixes improves the mechanical properties of concrete. This study investigates the fresh and hardened properties of normal aggregate concrete (NAC) and recycled aggregate concrete (RAC) made with locally available low-cost galvanized iron (GI) fiber, as an alternative to steel fibers, and polypropylene (PP) fibers. The objective of this study is to explore the effect of GI fiber and PP fiber in terms of compressive strength, stress-strain behavior, splitting tensile strength, and flexural strength. The study has been completed in two phases. In the first phase, GI fiber and PP fiber with 0.5%, 1% and combination of GI and PP fiber are used to prepare NAC to find out the optimum fiber type and percentage. From test results it has been observed that concrete with 0.5% GI fiber produced best results in terms of strength and ductility than the concrete with PP fiber, other GI fiber content and combination of GI and PP fibers. In the second part of the study, diameter and length of the GI fiber has been varied while keeping the fiber percentage of 0.5% constant. From local market three different diameters of GI fibers, such as 0.51 mm, 0.70 mm and 1.21 mm, have been used in NAC to evaluate the effect of GI fiber diameter on the properties of NAC. In terms of the performance against workability, compressive and splitting tensile strength, 0.51mm diameter GI fiber has chosen for the next part of the study. Finally, GI fiber of 0.51 mm diameter considering three different aspect ratios, such as 30, 50 and 70, for which the fiber lengths were 15, 26, and 36 mm respectively, have been incorporated in both NAC and RAC. For NAC, GI fiber of length 26 mm and for RAC, GI fiber of length 36 mm showed the highest compressive strength. In general, the test results have showed that RAC has lower strength than NAC at 28 days. However, at 56 days RAC have showed better strength compare to NAC. Inclusion of GI fiber has improved the mechanical properties of both NAC and RAC. On the other hand, incorporation of PP fiber has very little effect on the compressive, tensile and flexural strength of NAC and RAC.PP fiber showed reduced compressive and split tensile strength. But PP fiber performed better at lower fiber content. At 0.5 % PP fiber content, vii concrete had low air content. However, against flexural loading concrete with PP fiber showed better ductility. PP fiber performed better with RAC than the NAC.