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Improving the Bearing Capacity of Footing on Soft Soils Using Stone Columns

Ali Falsafi1 * and M. R. Motahari1

Corresponding author Email: Ali_Falsafi@yahoo.com

DOI: http://dx.doi.org/10.12944/CWE.10.Special-Issue1.123

In the present paper, the numerical analysis of stone columns in improving the bearing capacity of footing with the length of 10m, and thickness of 0.5 m in fine-grained soil is studied. The case study, stone columns group, has 3 columns which are symmetric. Two-dimensional finite element method is used for investigating the behavior of stone columns. In addition, behavior of stone column's materials and its surrounding soil has been modeled using the Mohr-Coulomb elasto-plastic constitutive model. In this analysis, the various parameters such as number of columns, influence of deformation in single column and stone column group, young modulus of the materials of stone column and soil, Poisson’s ratio of column's material and soil have been studied. Results indicate that efficiency of stone columns in soft fine-grained soil. Most important results show that operations of stone columns are faster and less costly comparing to piles.


Stone columns; Fine-grained soil; Numerical analysis; Subsidence; Bearing capacity

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Falsafi A, Motahari M. R. Improving the Bearing Capacity of Footing on Soft Soils Using Stone Columns. Special Issue of Curr World Environ 2015;10(Special Issue May 2015). DOI:http://dx.doi.org/10.12944/CWE.10.Special-Issue1.123

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Falsafi A, Motahari M. R. Improving the Bearing Capacity of Footing on Soft Soils Using Stone Columns. Special Issue of Curr World Environ 2015;10(Special Issue May 2015). Available from: http://www.cwejournal.org/?p=11440


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Article Publishing History

Received: 2014-11-06
Accepted: 2015-12-30

Introduction

Construction of stone column is so common to improve soft soils such as clay, silt and silty sands which have proven to be compatible with environment (Keykhosro poor, L, 2011). Stone columns were first used in France in 1830, and they are widely used in other countries since 1950. In Iran at first it was used by the Ramming method, and since 2004 vibration technique was used in building stone columns (Etezad, M., et al, 2005), (Hughes, J.M.O and withers, N.J, 1974). In 1974 behavior of stone columns was studied for the first time. Meanwhile many numerical and laboratory tests have been used and most important one is determining the subsidence of column and its surrounding soil which is the result of applying upright tension on the ground (Tabarsaz, S, 2008). Since the rigidity of stone column is more than the soil, tension concentration and result of decreased subsidence and increasing the bearing capacity of overall ground and stone column are benefits of using this method (Lo, S.R., et al., 2010), (Kempfert, H.G., Gebreselassie, B., 2006). In another study it is reported that in the single stone column faults as a result of sag in upper column, if in stone column group, sagging occurs in lower parts of column (Alexiew, D., Brokemper, S., 2005), (Gniel, J., Bouzza, A., 2009), (Khabazian, 2010). In the present paper performance of stone columns in improvement of bearing capacity, subsidence and different parameters such as sag effect in single column and columns group, number of columns, materials and soil's elasticity modulus ratio and Poisson coefficient of stone columns materials and soil upon the degree of soil's subsidence are investigated. Numerical analysis is carried out as plane strain using ABAQUS software.

Modeling procedure with ABAQUS

Single Stone Column

Numerical analysis for clayey soil reinforced by stone column with 0.6 m diameter is carried out in order to evaluate the behavior of single stone column. Loading has only been done upon the stone column by rigid foundation. Stone column and surrounding soil modeling is a two-dimension plane strain. the mentioned model is presented in Fig1.

Figure1: stone column and is surrounding soil 


Figure 1: stone column and is surrounding soil
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Stone column material and surrounding soil is modeled by Mohr-Coulomb. Physical and mechanical properties of stone column materials and surrounding soil are listed in Table 1. Rigid foundation applies the force by the value of 585 kPa only on the stone column. Fig 2 shows the deformation of stone column after exerting the whole load. This plot reveals that there is sagging and subsidence in upper parts of stone column. Fig 3 shows the level of sagging in column.

 Table1: Physical and mechanical properties of soil column materials
Table 1: Physical and mechanical properties of soil column materials
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Fig 2. Deformation of single stone column in numerical analysis 


Figure 2: Deformation of single stone column in numerical analysis
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 Fig 3. Deformation in stone column


Figure 3: Deformation in stone column
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Stone Column Group

In order to investigate the behavior of stone group, a four stone column group with 0.5 diameter and whose center to center distance is from 1.2m to 3.6 m, is placed below a 10 m long rigid square foundation. Geometric characteristic of stone column group are in Fig 4 and their mechanical characteristic listed in Table 2.

Table2: material properties of stone column group and surrounding soil 
Table 2: Material properties of stone column group and surrounding soil
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 Fig4: geometric characteristics of ground with stone column


Figure 4: Geometric characteristics of ground with stone column
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In Fig 5, behavior of each column in a group is independent from near columns and each column deforms as a single column.

 Fig 5. Deformation of stone columns without considering the group effect


Figure 5: Deformation of stone columns without considering the group effect
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Investigation of The Effect of Different Parameters

In this part the effect of different parameters including number of columns, effect of sagging in single column and column group, distance between columns, column material and soil's elasticity ratio and the Poisson coefficient of stone column materials and by producing various models are studied as follows.

Number of Columns

Subsidence variations of column caps with changing the number of columns are shown in Fig 6. Increasing the number of columns leads to more restriction of middle columns, thus decrease of subsidence. Numerical analyses have been performed for 3, 5, 7 and 9 stone columns with the diameter of 0.6 m. The pressures forced in all cases are the same and equal to 325 kPa. Number of columns, applied forces and the subsidence that occurs by these forces are listed in Table 3. As shown in figure 6, Subsidence decreases by increasing the number of stone columns.

Table 3: Comparison of the intensive load and subsidence of stone columns

Number of columns

subsidence (m)

Intensive load (kN)

3

0.274

975

5

0.23

1755

7

0.173

2535

9

0.147

3375

 

 Fig 6. subsidence vs. number of columns.


Figure 6: Subsidence vs. number of columns.
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Effects of the Change in Elasticity Module

Fig 7 shows the effect of changes in elasticity module of stone column material and clay assuming that soil's elasticity module is constant to 5 MPa for load of 165 kPa. As expected, increasing the ratio of stone column's elasticity module over soil's elasticity module cause decrease in subsidence of the soil reinforced with stone column.

 Fig7. variation in subsidence of column group vs. number of columns.


Figure 7: Variation in subsidence of column group vs. number of columns.
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Piosson Ratio

Poisson ratio of stone column materials and soil is one of factors that causes the subsidence of soils with stone columns. Fig 8 shows the effect of changing in Poisson coefficient of stone column materials and soils for 280 kPa weight.

Stone column material's Poisson coefficient varies from 0.2 to 0.35. And Poisson coefficient of soil varies from 0.3 to 0.45. As it can be seen in the Fig 8, increasing the stone material's Poisson coefficient has a slight influence on decrease of subsidence of reinforced ground, compared to increasing surrounding soil's Poisson coefficient.

 Fig 8. variations of stone group subsidence vs. Poisson ratio


Figure 8: Variations of stone group subsidence vs. Poisson ratio
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Effect of Stone Column Length

Fig 9 shows the influence of stone column’s length for 170 k Pa weight. Stone column length varies evenly in these analyses from 2 to 10 meters. A series of analyses are performed on stone column group that has 3 columns with 0.6m diameter and the center to center distance of 1.2 m. According to Fig 9, numerical analyzes results indicate that decrease of subsidence on top and bottom of columns is due to increase of column lengths. In addition, subsidence decrease rate reduces due to increase of column length from 0.6m to 10 m.

 Fig 9. Subsidence variation on vs. length of columns


Figure 9: Subsidence variation on vs. length of columns
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Conclusion

In this paper, by using ABAQUS, behavior of stone columns and the effect of important parameters on stone column- soil system were studied and the following results were obtained:

  1. Numerical analysis results indicate that sagging of columns which leads them to fail, occurs in upper part of column. Sagging of inner columns occurs in lower parts than side columns.
  2. Increasing the stone column's elasticity module compared to soil's module, decreases the subsidence of grounds with stone columns.
  3. Increasing the number of stone columns results in more inclosing if middle columns which decreases the subsidence by 50%.
  4. Poisson coefficient of soil and stone column is one of the factors that reduces the subsidence of grounds with stone columns however the effect of Poisson coefficient is low.
  5. Numerical analyses about the influences of stone column's lengths indicate that increasing the length of column group reduces the subsidence of the ground.

References

  1. Keykhosro poor, L, (2011), "study of effect of coated stone column on reinforcing soft soils with numerical analysis", Master dissertation, Amirkabir University, Tehran..
  2. Etezad, M., Hanna, A.M. and Ayadat.T., (2005), "Numerical model for group of Stone columns", Proc. 73rd Annual Meeting of ICOLD, Tehran. Iran No. 097-0T.
  3. Hughes, J.M.O and withers, N.J, "Reinforcing of Soft cohesive soils with stone columns" Ground Engineering, Vo11.N.3, 1974.PP42-49
  4. Tabarsaz, S, (2008), "numerical analysis of mechanical behavior for grounds with stone columns". Master dissertation, Amirkabir University, Tehran.
  5. Lo, S.R., Zhang, R., Mak, J., (2010), “Geosynthetic-Encased Stone Columns in Soft Clay: a Numerical Study,” Geotextiles and Geomembranes, No. 28, 292-302.
  6. Kempfert, H.G., Gebreselassie, B., (2006), “Excavations and Foundations in Soft Soils,” Springer, p.p. 474-481.
  7. Alexiew, D., Brokemper, S., (2005), “Geotextile Encased Columns(Gec): Load Capacity, Geotextile Selection and Pre-Design Graphs,”Gsp131, Contemporary Issues in Foundation Engineering, ASCE.
  8. Gniel, J., Bouzza, A., (2009), “Improvement of Soft Soils Using Geogrid Encased Stone Columns,” Geotextiles and Geomembranes, No. 27, p.p. 167-175.
  9. Khabazian, (2010), “3D Numerical Analyses of Geosynthetic Encased Stone Columns,” ASCE Proc.Conference, p.p. 201-208