Soil–Geosynthetic Interface Shear in Different Testing Scales

Characterization of soil-geosynthetic interaction is a key aspect in understanding mechanical performance of structures made using geosynthetics (e.g., geosynthetic-stabilized roadways, geosynthetic-reinforced soil walls). Pullout test has been one of the most widely used experimental techniques to characterize this interaction. This study implements t-z analysis approach, originally developed to evaluate load transfer mechanism in deep foundations, to predict pullout test results of geosynthetics. Formulations of the method and step-by-step solution algorithm are presented. Suitability of the method was evaluated by comparisons made between predictions of the t-z analysis approach and experimental pullout test results presented in literature. Specifically, geosynthetic and soil-geosynthetic characterization data presented in four studies with a wide range of soil and geosynthetic types, normal pressures, and test configurations were used in the t-z analysis framework presented in this study to simulate pullout test results. Results from the simulations were then compared to the experimental data presented in the four studies. This comparison underscored suitability of the t-z analysis approach in producing reasonably consistent results with the experimental data.

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HDPE geogrid-residual soil interaction under monotonic and cyclic pullout loading

Ferreira

Vieira

Lopes

et al. 2020

Geosynthetics International

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The understanding of soil-geosynthetic interaction under cyclic loading conditions is essential for the safe design of geosynthetic-reinforced soil structures subjected to repeated loads, such as those induced by road and railway traffic and earthquakes. This paper describes a series of large-scale monotonic and multistage pullout tests carried out to investigate the behaviour of a HDPE uniaxial geogrid embedded in a locally available granite residual soil under monotonic and cyclic pullout loading. The effects of the pullout load level at the start of the cyclic stage, cyclic load frequency and amplitude, number of cycles and soil density on the load-strain-displacement response of the reinforcement are evaluated and discussed. Test results have shown that the cumulative displacements measured along the length of the geogrid

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Soil–Geosynthetic Interface Shear in Different Testing Scales

Cited by 3 publications

References 18 publications

Soil-reinforcement interaction: Stress regime evolution in geosynthetic-reinforced soils

Soil-reinforcement interaction: Stress regime evolution in geosynthetic-reinforced soils

Implementation of T-Z Analysis Approach to Predict Pullout Test Results

HDPE geogrid-residual soil interaction under monotonic and cyclic pullout loading

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