Optimization of the Ultimate Bearing Capacity of Reinforced Soft Soils through the Concept of the Critical Length of Stone Columns

Boumekik, Nour El Islam; Labed, Mohamed; Mellas, Mekki; Mabrouki, Abdelhak

doi:10.28991/cej-2021-03091737

Cited by 5 publications

(5 citation statements)

References 28 publications

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“…The values of soil materials and geometric parameters used for the analysis are displayed in Table 2. They are selected according to the typical range adopted in the latest studies (Basu, 2009;Boumekik et al, 2021). The results are presented as the load-displacement curves and the parameters analyzed are the friction angle, Young's modulus, the column length and the encasement stiffness of the geotextile.…”

Section: Parametric Studymentioning

confidence: 99%

“…Currently, the reinforcement by a stone column is one of the techniques used to reduce the settlement and increase the bearing capacity of soft soil. The technique concept is to change 10-40% of the weak soil with a cylinder containing compacted granular material (Boumekik et al, 2021). Ordinary Stone Columns (OSCs) are constructed in soft soil to reduce settlement, as well as to improve and increase the bearing capacity (Han and Ye, 2001).…”

Section: Introductionmentioning

confidence: 99%

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Numerical Analysis of a 3D Unit Cell Model for Soft Soil Reinforced with Different Granular Columns

Amin

2023

JJCE

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Recycled aggregates have been increasingly considered in recent years, owing to the limited supply of natural aggregates coupled with the corresponding carbon footprint. Recycled aggregates are aggregates prepared from construction and demolition waste. Their use aims to reduce energy consumption and contributes to reducing waste harmful to the environment. This study is based on a number of numerical tests using the finite element method of PLAXIS 3D software with the elastic-perfectly plastic behavior model and the Mohr flow criterion for all materials. A unit cell model of soft soil treated with three types of granular columns was loaded to failure: ordinary stone columns (OSCs), sand-fiber mix (SFM) and recycled aggregate porous concrete pile (RAPP). An extensive parametric study was conducted to investigate the effect of column type, friction angle, elasticity modulus, column length and geotextile effective stiffness on the behavior of soft soils. The results of numerical tests indicated that the bearing capacity of the recycled aggregate columns is three times greater than that of columns of natural aggregates. The findings of this research are given in the form of load-settlement graphs, which made it possible to release recommendations to carry out works using this technique. KEYWORDS: Soft soil, Granular column, Numerical analysis, Unit cell, Bearing capacity, PLAXIS 3D software

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Section: Parametric Studymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical Analysis of a 3D Unit Cell Model for Soft Soil Reinforced with Different Granular Columns

Amin

2023

JJCE

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“…In the present study, each experiment was repeated twice to ensure the accuracy of the experiments performed. It is important to note that, before making the samples, the inner walls of the test box (device) were well impregnated with oil to minimize the friction of sandy soil with the surfaces of the device under test [23].…”

Section: Laboratory Studymentioning

confidence: 99%

Numerical and Larg‐Scale Laboratory Study of Rock Column Groups in Sandy Soil Behavior Improvement

Samangani

Naderi

2022

Advances in Civil Engineering

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The use of stone columns as one of the effective methods in improving soil behavior can increase soil bearing capacity. One of the common methods in improving poor soil is the use of stone columns. Stone columns are considered one of the suitable options to improve the bearing capacity of loose cohesive and granular soils, which, in addition to reducing soil subsidence, is also considered an effective, economical, and environmentally friendly method in structures built on soil. Considering the financial and human losses caused by the construction of various buildings on poor soils, the importance of developing improvement methods in weak and unsuitable soils is essential. On the other hand, sandy soils are always considered an unsuitable soil sample in design. Therefore, in the present study, we use group stone columns to improve the behavior of a sandy soil sample. When a sample of soft sandy soil is exposed to loading due to its sandiness, we see an increase in soil subsidence and thus a decrease in its load-bearing capacity. In order to obtain practical and useable results in practice, in addition to numerical studies, we conduct a laboratory study to investigate the effect of rock columns on improving sandy soil performance. In sandy soil armed with 4 rock columns, the comparison of the results obtained from the numerical and laboratory model to the displacement of 2 mm is completely consistent with each other, and with increasing displacement, we see a difference between the numerical and laboratory results, so that for a 6 mm displacement, we see an 8% difference in numerical and laboratory results. The final sample capacity in the numerical and laboratory study in this case is 6730 N and 6192 N, respectively.

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“…Another study conducted by Bunawan et al [10] states that limited efforts have been made to investigate and identify the failure behavior of a concrete column group [11]. A proper design of roads and airfield pavements requires an in-depth soil properties evaluation to determine suitability of soil [12]. e main aim of this research is to recommend the optimum specification of the reinforced soil-footing system.…”

Section: Introductionmentioning

confidence: 99%

Stabilizers Effects Comprehensive Assessment on the Physical and Chemical Properties of Soft Clays

Pourebrahim

Zolfegharifar

2022

Shock and Vibration

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Deep soil mixing (DSM) is one of the practical methods of soil improvement in the world, which produces cement columns and modification by injecting stabilizing materials such as cement or lime using a mechanically hollow shaft drill in the soil. In this method, the soil characteristics are improved by mixing the soil with cementitious materials by deep mixers and creating cement soil columns. In addition, by overlapping the columns before full setting, continuous walls can be constructed below the ground. The aim of this study was to investigate the effect of the additive type on the strength of the samples. For soil samples stabilized with lime, the maximum value of uniaxial resistance was 247 kPa and for the mixture of 10% lime and 4% sodium silicate was obtained.

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Optimization of the Ultimate Bearing Capacity of Reinforced Soft Soils through the Concept of the Critical Length of Stone Columns

Cited by 5 publications

References 28 publications

Numerical Analysis of a 3D Unit Cell Model for Soft Soil Reinforced with Different Granular Columns

Numerical Analysis of a 3D Unit Cell Model for Soft Soil Reinforced with Different Granular Columns

Numerical and Larg‐Scale Laboratory Study of Rock Column Groups in Sandy Soil Behavior Improvement

Stabilizers Effects Comprehensive Assessment on the Physical and Chemical Properties of Soft Clays

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