Abstract
One of the critical design parameters used in evaluating soil structure is the friction angle, derived from Mohr's Circle failure criterion. The soil friction angle is an engineering parameter estimated in the laboratory to quantify the soil shear strength in geotechnical applications. This paper indicates an experimental study investigating the impact of particle size on different sandy soils shear strength behavior. The direct shear test equipment is useful for simulating various stress regimes to determine the soil strength by employing a slow moving lateral force to a consolidated sample along a shear plane. A series of direct shear tests were conducted to investigate the interface behavior of soil. Soil samples were selected from different locations in New Mexico, United States. The influence of soil particle size on the soil's shear strength behavior is discussed by performing a series of symmetric direct shear tests according to ASTM D3080 and analyzing the results. To minimize errors, electronic transducers were used to measure vertical and horizontal displacements. DS7 is geotechnical testing software controlling the test by utilizing a data logger. The investigation indicates that the maximum vertical deformation for all different kinds of sandy soils accrued simultaneously. It was concluded that a soil's friction angle is affected by coarse-grained material. Accordingly, sandy soils with bigger particle size record a higher friction angle than soils containing small particles. Furthermore, a non-linear regression analysis was performed to determine the direct relationship between soil's friction angle and soil particle characteristics.
Highlights
To predict the engineering behavior of the soil, it is a crucial early step to estimate the water content, the Atterberg limits and strength parameters (Rasti et al, 2020)
This study aims to determine the effect of particle size characteristics on the friction angle of sandy soil materials
The effects of particle sizes on the sandy soil's shear strength parameters were studied in this investigation
Summary
To predict the engineering behavior of the soil, it is a crucial early step to estimate the water content, the Atterberg limits and strength parameters (Rasti et al, 2020). The internal friction angle is an important parameter of soil, the estimated strength can be derived using Mohr's Circle failure criterion. The friction angle is a common parameter used to quantify the soil shear strength in geotechnical applications, including pavements, earth dams, retaining walls, slope stability, foundation design, pipelines and soil cement stabilization. Common apparatuses include the triaxial stress test, direct shear test and double-punch test (Hasan and Rashid, 2017). Both direct shear and triaxial methods have been widely used to measure the shear strength of soil and rock materials in geotechnical engineering practice. The direct shear test is a simple and common method for design and research to estimate the friction angle and cohesion of materials per ASTM D3080. Direct shear testing has several applications since less time is required to fail and complete the test than the triaxial test (Gan et al, 1988; Lee, 1970; ASTM International, 2011)
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