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Showing 2 results for Nonwoven Geotextile

Ali Pak, Zahra Zahmatkesh,
Volume 9, Issue 2 (6-2011)

Geotextiles are one of the most widely used synthetic materials in filtration and drainage applications. Since in real

applications, geotextiles are subjected to various hydraulic gradients and confining stresses, hydraulic behavior of geotextiles

under different circumstances is of great practical importance. In this study filtration and drainage properties of several

nonwoven needle-punched geotextiles with different properties and unit mass per area of 200g/m2, 400g/m2, 500g/m2 and

800g/m2, under various confining stresses and hydraulic gradients, were studied using standard permittivity

and transmissivity equipments. Prepared samples were subjected to hydraulic heads in the range of 10cm to 60cm and

confining stresses up to 1000kPa and their hydraulic behavior was investigated accordingly. In this study the flow regime

through the geotextile fibers and also the anisotropic behavior of geotextile permeability were investigated. The results show

that transmissivity will decrease exponentially with increasing the normal stress until a residual value is reached, and

permittivity and transmissivity coefficients were seen to decrease with increasing the hydraulic gradient. The flow regime has

found to be non-turbulent in all cases.The Geotextile hydraulic behavior is of great usage in the design of landfill covers,

design of embankments and irrigation structures drainage systems, and in the design of protection systems in river


Omar Al Hattamleh,
Volume 14, Issue 2 (3-2016)

ABSTRACT The influence of the sand placement method above geotextile layer on interface shear strength behavior was investigated. Seven different types of woven and non woven geotextile were used with only poorly graded sand. The investigation involved placement of sand layer through inclined horizontal plane with different angles. This step constitutes a fundamental step for assessing soil to be deposited in different plane and therefore with different internal soil fabric. The interface shear strength was evaluated by using direct shear test. Although the investigated soil is uniform poorly graded sand, the influence of the deposit plane was significant especially for nonwoven geotextile. Differences in soil interface shear strength associated with the tested geotextiles samples shows that samples with higher mass per unit area and same opening sizes had the higher interface friction angle regardless the bedding plane. Influence of bedding plane on interface modulus of elasticity which used in most of interface modeling was investigated using Janbu’s formula. It is noted that the use of secant interface modulus of elasticity at 1% strain and at 50% of peak stresses gave a consistent prediction of n and Ku constant appear in Janbu’s formula for all types of geotextile. The above results were reflected in the prediction for interface molded such as Chen and Juran as shown. Therefore, the existing interface modeled is needed to be modified to account for the method that the sand is being placed above the geotextile layer.

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