Gholam Moradi scite author profile

In embankment construction, earth pressure on buried culverts is reduced either by placing them in a trench in the ground or by inserting a soft zone in the fill over the culvert to create an ‘induced trench’. Although the performance of both methods has been studied in the literature, there are limited findings for applying the two methods in combination. A study was therefore carried out on the earth pressure exerted on box culverts buried in a trench with a soft zone included above. Laboratory tests and numerical analyses were conducted to study the performance of the proposed combined method. A surcharge load was applied to the backfill, and earth pressure around the buried box culvert was measured. After validation of the test results by a numerical method, parametric studies were performed to investigate the effect of the expanded polystyrene geofoam properties and the culvert dimensions. The results showed that culvert installation using the proposed method significantly decreased the earth pressure applied to the walls of the buried box culvert, especially when compared to the trench-only method. Using a width 1.5 times greater than the culvert width and a low-stiffness geofoam, earth pressure transferred to the buried culvert can be significantly decreased.

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The influence of overburden pressure on liquefaction potential

Moradi¹,

Sutubadi²,

Khatibi³

2014

Turkish J Eng Env Sci

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One of the important design considerations for structures situated on sand deposits is the potential for instability caused by the development of excess pore water pressure as a result of earthquake loading. A build-up of excess pore water pressure may lead to initial liquefaction. In this paper, to examine the influence of overburden pressure on liquefaction potential, equivalent loads of several buildings with various stories were loaded on a sandy soil deposit using the FLAC program. The pore water pressure ratio ru was defined for the program by a Fish function. Analyses showed that by increasing the applied loading due to building construction, the values of effective stress and shear stress in the soil mass increased, and this generally can be a factor to influence liquefaction potential. Furthermore, dynamic analyses showed that there was a shallow longitudinal area beneath tall buildings in which liquefaction potential increased due to stress concentration and high confining effective stress; generally, they can be named as the factors to increase liquefaction potential.

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Performance of the horizontal drains in upstream shell of earth dams on the upstream slope stability during rapid drawdown conditions

et al. 2013

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Gholam Moradi

Evaluation of compression index of marine fine-grained soils by the use of index tests

Performance of Cutoff Walls Under Hydraulic Structures Against Uplift Pressure and Piping Phenomenon

Experimental and numerical analyses of buried box culverts in trenches using geofoam

The influence of overburden pressure on liquefaction potential

Performance of the horizontal drains in upstream shell of earth dams on the upstream slope stability during rapid drawdown conditions

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