Abstract
Geogrid is as one of the component materials classified under the geosynthetics used for soil stabilizing and reinforcement. Due to its higher strength-to-weight ratio, ease of handling, and comparatively low costs, geogrid has been gradually explored for possible use in concrete reinforcement. This research aims to assess the feasibility of using geogrids as a possible reinforcement for high-strength self-compacted concrete slabs to provide additional tensile strength and ductility. To enhance the bond between geogrid layers and the cement matrix, two types of geogrid surface modification methods are introduced. Gluing sand to the geogrid surface as a physical surface modification method and immersion in polycarboxylate as a chemical surface modification method are investigated. The effect of geogrid type (uniaxial, biaxial and triaxial) and the number of layers is also introduced. The test results show that the chemical treatment increased the ultimate flexural loading capacity of the tested slab by about 8.5% for one geogrid layer and 13% for two geogrid layers compared to untreated specimens. This work was extended to add two geogrid layers in addition to the slab’s steel reinforcement. The results show that adding geogrid decreased the ultimate flexural loading capacity but significantly increased the slab ductility.
Highlights
Geogrid is a type of component material, classified under geosynthetics, and derived from polymers, such as polypropylene, polyethylene and polyester [1,2]
The current study introduces two types of geogrid’s surface modification techniques to enhance the bond between geogrid layers and the cement matrix
Load-deflection curves for high strength self-compacted concrete (HSSCC) 5-cm slabs containing 1 and 2 layers of uniaxial, biaxial and triaxial geogrids are shown in Figures 9 and 10
Summary
Geogrid is a type of component material, classified under geosynthetics, and derived from polymers, such as polypropylene, polyethylene and polyester [1,2]. Using geogrids as a reinforcing material is increasing towards pavement network, reinforcing portion in particular asphalt layers and stabilizing medium in unbound layers. Due to their significantly higher strength to weight ratio, ease of handling, and comparatively low cost, geogrids were gradually explored for possible use as a replacement for rigid pavements [3]. Uniaxial geogrids can mainly be used for grade separating purposes, including retaining walls and steep slopes, while biaxial and triaxial geogrids can be used mainly for roadway uses This will be defined either through a series of performance characteristics, such as tensile strength and junction efficiency [4]
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