TECHNICAL PAPER

On settlement prediction of soft clay reinforced by a groupof stone columns

Seifeddine Tabchouche1 • Mekki Mellas1 • Mounir Bouassida2

Received: 23 August 2016 / Accepted: 24 December 2016 / Published online: 19 January 2017

� Springer International Publishing Switzerland 2017

Abstract This paper studies the behavior of a foundation

on a soil reinforced by a group of end-bearing stone col-

umns in terms of settlement reduction in oedometer con-

dition. The group of stone columns has been reduced to

equivalent concentric crowns using a finite-difference

FLAC3D modeling. The obtained numerical results were

compared to existing analytical and numerical methods for

the prediction of the settlement of reinforced soil. It was

found that the prediction of the settlement by the 3D

numerical modeling of equivalent concentric crowns is less

than that obtained by the actual 3D model of group of stone

columns. These results have been validated through com-

parison between numerical, analytical, and in situ mea-

surements collected from full-scale loading tests of stone

column from recent case history.

Keywords Soft soils � Stone columns � Settlement

reduction � Numerical method � Loading tests

Introduction

The need of construction on soft soils remains a big challenge

for geotechnical engineers. Several ground improvement

techniqueswere developed to render soft soils able to support

a variety of constructions with suitable stability conditions.

The stone columns revealed one of those techniques that

were widely practiced since the 70s.

The improvement by stone columns increases the

bearing capacity of weak soils, decreases their settlement,

and accelerates their consolidation. Hence, the prediction

of performances provided by stone columns should be

addressed with respect to all those benefits.

The vibro displacement technique represents a process that

contributes in the improvement of properties of soft clays

upon the installation of stone columns. The laterally expanded

stone material increases both the Young modulus and

undrained shear strength of soft clays as a result of the induced

horizontal consolidation favored by enhanced permeability of

stone material [15, 16]. However, the applicability of stone

columns technique can be sometimes subjected to restrictions.

As an example, after Bowles [8], granular piles are prohibited

in thick deposits of pears or highly organic silts or clays due to

the low degree of stiffening achieved in those soils. Wood-

ward [22] reported that theminimumundrained shear strength

of soft soil to be treated should equal 20 kN/m2.

The design of foundation on soils reinforced by col-

umns, first, involves two verifications [5]:

– Bearing capacity To check if the allowable bearing

capacity of reinforced soil complies with the applied

load.

– Settlement To check whether the predicted settlement

of reinforced soil subjected to the applied load verifies

the allowable settlement.

& Mounir Bouassida

mounir.bouassida@fulbrightmail.org

Seifeddine Tabchouche

tabchouche.seifeddine@gmail.com

Mekki Mellas

m_mellas@yahoo.fr

1 Faculty of sciences and technology, Laboratory of research in

civil engineering - LRGC, University of Biskra, BP 145,

07000 Biskra, Algeria

2 Universite de Tunis El Manar, Ecole Nationale d’Ingenieurs

de Tunis, LR14ES03-Ingenierie Geotechnique, BP 37 Le

Belvedere, 1002 Tunis, Tunisia

123

Innov. Infrastruct. Solut. (2017) 2:1

DOI 10.1007/s41062-016-0049-0

Handling both the bearing capacity and settlement ver-

ifications, an optimized area ratio can be determined.

Second, adopting the optimized area ratio, the study of

the behavior of foundation on reinforced soil can be tackled

by considering the acceleration of consolidation provided

by the stone columns, which play the role of vertical drains

[4].

Using numerical codes, the prediction of long-term

settlement, especially when reinforcement by floating col-

umns is decided, of unreinforced compressible layers is

crucial [7].

In this paper, the prediction of settlement of a founda-

tion resting on a soil reinforced by a group of end-bearing

stone columns in oedometer condition is investigated. The

oedometer condition fairly applies for foundations having

dimensions (width and length) quite greater than the

thickness of compressible layer(s).

The statement of the problem is presented with focus on

numerical modeling, the design parameters of reinforced

soil by columns, and enriched literature review from recent

contributions.

First, the numerical modeling using FLAC 3D code of

soil reinforced by end-bearing stone columns at constant

area ratio are presented: the unit cell model (UCM) as

reference case, the group of stone columns (GSC), and the

equivalent concentric crowns (ECC) with boundary con-

ditions. Obtained results are presented and compared. The

predictions made by the FLAC 3D code of settlement of a

large tank diameter in oedometer condition are compared

to results obtained by existing methods of design. Their

interpretation and synthesis are addressed in details. In

particular, due to their simple numerical implementation,

compared to actual group of stone columns, it is aimed to

quantify the efficiency of annular concentric approach, in

oedometer condition, for the prediction of settlement of

reinforced soil.

Second, the Algiers harbor case history is presented,

from which the recorded data are used for the validation of

numerical predictions by FLAC 3D code.

The effectiveness of two 3D modeling of column-rein-

forced foundation (CRF) is discussed by comparing

numerical predictions with measurements recorded from a

full-scale load test carried out in the framework of Algiers

harbor case history.

Statement of the problem

The settlement of a reinforced soil by stone columns occurs

when the foundation is subjected to its final loading. The

study of the behavior of foundations on a soil reinforced by

columns is carried out using two parameters, i.e., the area

ratio (g) and the settlement reduction factor (b) defined,

respectively, as follows:

g ¼ Ac=A ð1Þb ¼ SunreinfðpÞ=SreinfðpÞ: ð2Þ

Here, Ac denotes the total cross section of stone columns all

located under the loaded foundation of area A.

Sunreinf and Sreinf denote the settlement of the foundation

on unreinforced soil and reinforced soil, respectively,

subjected to the same allowable surcharge load p.

Several methods for predicting the settlements of a

reinforced foundation by stone columns have been devel-

oped [4].

The study of behavior of stone columns, with focus on

settlement prediction, has been investigated by several

researchers in the literature, Balaam and Booker [2].

Barksdale and Bachus [3] carried out a series of scaled

laboratory tests conducted on an isolated stone column in

undrained conditions from which the load-settlement

response was analyzed. This experimental investigation

evidenced that the bearing capacity and the settlement

behavior of a single stone column are significantly influ-

enced by the type of applied load and the support provided

by the surrounding soil.

Wehr [21] performed a finite-element analysis in plane

strain condition to simulate the observed behavior from

laboratory tests of loaded footing on soil reinforced by a

group of columns. The author suggested that beyond a

depth equals 1.5 the diameter of the footing, the expansion

behavior of columns is noticed. Beneath that critical depth,

central columns behave in punching failure, whilst edge

columns behave in buckling failure.

Serridge [20] conducted a series of field trial of partially

penetrating dry bottom-feed vibro stone columns support-

ing shallow narrow footings. The author investigated the

behavior and the settlement performance of vibro stone

columns installed within a deep soft clay deposit. In this

study, focus was made on the response of sensitive soft

clay to the method of installation of stone columns.

Killeen and McCabe [17] conducted a finite-element

analysis on small groups of stone columns loaded by pad

and strip footings. Authors have studied the influence of the

column stiffness and strength on the settlement behavior of

small loaded areas.

Castro [9] proposed an approximated solution to predict

the settlement of rigid footings resting on soft soil improved

by a group of stone columns. The proposed analytical solu-

tion converts the group of stone columns to equivalent single

column with the same cross-sectional area. The author aims

to convert the problem to be axially symmetric.

McCabe and Killeen [19] studied the behavior of small

groups of stone columns. Authors indicate that the mode of

1 Page 2 of 12 Innov. Infrastruct. Solut. (2017) 2:1

123

deformation of a column-reinforced foundation is governed

by the column spacing and length rather than the number of

columns. Authors also discussed the influence of a critical

length on the settlement performance of a CRF.

Consider the effect of stone column installation by lat-

eral expansion, Ellouze et al. [12] reported that an

improvement in the Young’s modulus of the initial soil

takes place due to the horizontal consolidation owed to the

presence of stone columns. Then, prior to the final loading

due to the construction of oil tank, the averaged improve-

ment in Young’s modulus of loose silt sand can attain by

30% around each stone column over a horizontal distance

of about 1.5 times its diameter.

In the following, focus is made on numerical settlement

predictions by the FLAC 3D code in oedometer condition

and their assessment with data collected from the very

recent Algiers harbor stone columns project.

The improvement in Young’s modulus of the initial soil

due to the installation of stone columns is not considered.

Investigated 3D numerical modeling

Three modeling in oedometer condition of soil reinforced

by stone columns is investigated by performing a three-

dimensional explicit finite-difference method (FDM),

incorporated in Fast Lagrangian Analysis of Continua

(FLAC). Those numerical models are considered for the

study of the behavior of loose sandy silt layer reinforced by

a group of end-bearing stone columns subjected to an oil

tank uniform load of 120 kPa having large diameter. The

properties of the initial soil and constitutive material of

end-bearing column are taken from a real stone column

project built at Zarzis terminal (Tunisia). The column’s

diameter is equal to 1.2 m and length of Hc = 7 m. As

reported by Bouassida and Hazzar [7], the related data of

this case history are given in Table 1.

The reinforcement is controlled by an area ratio of

g = 20% that was adopted after the method of design of

column-reinforced foundations proposed by Bouassida and

Carter [5]. This reinforcement is kept constant, while the

number of stone columns (modeled by a stone crown) and

the area of loaded foundation are varied. The settlement of

reinforced soil is, first, predicted by the unit cell model

(UCM) and, then, by the group of stone columns modeling.

Then, the load-settlement curves are predicted using

different reinforcement configurations where the number of

stone columns and equivalent concentric stone crowns is

increased.

The predictions obtained by the reinforcement using the

concentric crowns are compared to the one predicted by the

actual group of columns modelings.

Unit cell model (UCM)

According to Bouassida [4], the UCM is built from the

distribution of a group of columns installed in a regular

pattern. Geometrically, the UCM is a reproducible volume

which includes a single column with a circular cross sec-

tion surrounded by a given volume of the initial soil. In

case the columns are installed in squared pattern, the

periodic volume of UCM corresponds to a parallelepiped

cylinder. The axisymmetric condition is, then, adopted by

an equivalent unit cell with circular cross section. The area

ratio is written as follows:

g ¼ 4a2

D2eq

: ð3Þ

The diameter of unit cell model, Deq, is expressed as a

function of the axis-to-axis spacing between columns ‘‘Sp’’,

‘‘a’’ denotes the stone column’s radius, [1].

Figure 1 shows the considered UCM with zero hori-

zontal displacement at the lateral border as required in

oedometer condition.

Under the central axis of the loaded foundation, it is

obvious to assume that horizontal displacement within the

reinforced soil layer(s) is almost zero, in particular when

end-bearing columns are designed. Consequently, in the

central zone of loaded foundation, the settlement is quasi

uniform as usually assumed in the design of column-rein-

forced foundations [4].

The study of the behavior of the UCM is undertaken

using the FLAC 3D code by assuming the elastic perfectly

plastic Mohr–Coulomb model for the initial soil. This

model is still current to describe approximately the

behavior of granular soils (sands), cohesive soils (clay and

silt soils), and rocks. In very recent numerical investiga-

tions conducted by the FLAC 3D code, the Mohr–Coulomb

behavior model revealed satisfactory when predicting the

Table 1 Geotechnical parameters of the stone columns reinforced

foundation described by the Mohr–Coulomb model

Parameter Unit Soft soil Stone column

ch kN/m3 17 18

u Degree 0 42

C kPa 25 0

E kPa 3600 36,000

v – 0.33 0.33

G MPa 1.35 13.53

K MPa 3.53 35.29

Dc m – 1.2

ch unit weight, u friction angle, C cohesion, E Young’s modulus, mPoisson’s ratio, G shear modulus, K bulk modulus, Dc stone column

diameter

Innov. Infrastruct. Solut. (2017) 2:1 Page 3 of 12 1

123

behavior of loose silt soil reinforced by stone column, Klai

et al. [18] and Bouassida [4].

The numerical FLAC 3D model, sketched in Fig. 1,

comprises 672 finite-difference zones and 735 grid points

(at cycle 6609).

The settlements of unreinforced soil and reinforced soil

were predicted, by different methods, as a function of the

applied surcharge load at the surface of UCM. Figure 2

displays the variation of settlements as a function of the

applied load.

The settlement predicted by the GSC modeling UCM

and the analytical variational approach [6] appears identi-

cal. In turn, the French method [13] led to lower prediction

of the settlement of reinforced soil. Indeed, by this method,

the oedometer Young modulus of the initial soil is adopted

which provides more settlement reduction.

It is worth mentioning that Chow’s method [11] predicts

the lowest settlement, because it assumes the composite

ground deforms in one-dimensional compression condition,

i.e., horizontal deformation is zero, and therefore, the

oedometer Young modulus is both used for the initial soil

and column material.

The UCM was also adopted to predict the consolidation

of soft soil reinforced by stone column. Guetif and

Bouassida [14] and Castro and Sagaseta [10] used different

constitutive laws for the constituents of reinforced soil to

predict the evolution of settlement due to horizontal con-

solidation as the stone column behaves like vertical drains.

Group of stone columns (GSC)

The prediction of settlement is investigated by three

equivalent numerical modeling of soil reinforced by a

group of end-bearing stone columns. The 3D finite-differ-

ence analysis has been carried out by the FLAC 3D code to

analyze the variation of settlement reduction factor b ver-

sus the applied load using different configurations of stone

columns in triangular pattern. Figure 3 displays the three

numerical 3D modeling 1a, 2a, and 3a performed by FLAC

3D code.

The same area ratio adopted for the UCM is considered:

g = 20%; the stone columns of diameter Dc = 1.2 m are

installed along an average depth of Hc = 7 m in a trian-

gular pattern with an axis-to-axis spacing of 2.06 m

(Fig. 3). The characteristics of generated meshes for the

three numerical FLAC3D modeling are summarized in

Table 2.

Figure 4 shows the settlement reduction predicted by the

Chow and French methods which adopt the UCM and the

three modeling performed by FLAC 3D code and Bouas-

sida et al. [6] method which adopt the 3D modeling of soil

reinforced a group of stone columns.

The installation of stone columns with an area ratio

g = 20% provides a settlement reduction in the range of

3.5–3.9 times, this relatively significant reduction of set-

tlement is affected by the oedometer condition as consid-

ered by the studied three numerical FLAC 3D modeling.

The predicted settlement reduction by the numerical

modeling of soil reinforced by a group of 7, 19, and 37

stone columns appears almost identical with negligible

relative difference, of ±2.5%, of the settlement reduction

factor. Analytical predictions made by Bouassida et al. [6]

method fit well with those obtained from modeling 3a

Fig. 1 Numerical FLAC3D modeling of adopted UCM

0 20 40 60 80 100 120 1400

2

4

6

8

Set

tlem

ent (cm

)

Working Load (kPa)

Chow's method (1996) French method - CFMS (2011) Bouassida et al. (2003) FLAC 3D - Unit Cell Model Unreinforced soil

Fig. 2 Settlement predictions by the UCM

1 Page 4 of 12 Innov. Infrastruct. Solut. (2017) 2:1

123

using the reinforcement by a group of 37 columns. As

shown from the settlement predictions in Fig. 2, it is well

noted the significant overestimation of settlement reduction

by the Chow’s method.

Therefore, in oedometer condition, it is concluded that

increasing the number of stone columns, as shown in

Fig. 3, for the generated 3D numerical modeling does not

significantly affect the settlement prediction of reinforced

soil up to surcharge loads of 120 kPa.

Equivalent concentric crowns (ECC)

The group of stone columns has been reduced to equivalent

concentric crowns (ECC) using a full 3D finite-difference

FLAC3D modeling. The equivalent co-centric crowns

(ECC) modeling can be adopted, in case the reinforcing

columns are located in a regular pattern as investigated by

Ellouze and Bouassida (2009) and Ellouze et al. [12].

Major advantage of this geometrical transformation con-

sists in carrying numerical computations in axisymmetric

condition that is timeless consuming than 3D modeling.

Equaling between the area of columns, located at equal

distance from the axis of loaded foundation, and the area of

ECC, then the equivalent thickness of ECC, eCr, is calcu-

lated from Eq (4):

Modeling 3aModeling 2a

y z

14 m10 m6 m

10 m

7 m

14 m14 m

Triangular patternSp = 2,06 mDc = 1,2 m

= 20 %

x

7 m7 m

6 m

Modeling 1a

η

Fig. 3 Finite-difference discretization of a group of 7, 19, and 37 stone columns

Table 2 Characteristics of numerical modeling of group of stone

columns as implemented by the FLAC 3D code

Modeling of group of stone

columns

FD

zones

Grid

points

Cycle

1a 1680 1575 2722

2a 4592 4215 3146

3a 8960 7815 5926

0 20 40 60 80 100 120 1400

2

4

6

8

10

Set

tlem

ent r

educ

tion

fact

or β

Applied load (kPa)

Chow's method (1996) French method - CFMS (2011) Bouassida et al. (2003) FLAC 3D - Group of 07 columns FLAC 3D - Group of 19 columns FLAC 3D - Group of 37 columns

Fig. 4 Estimation of settlement reduction factors

Innov. Infrastruct. Solut. (2017) 2:1 Page 5 of 12 1

123

eCrðiÞ ¼ ðNðiÞ � AcÞ=ð2p� SpÞ: ð4Þ

Sp spacing between columns. N(i) number of columns

located on the circumference of the crown i.

Figure 5 illustrates the finite-difference discretization of

group of stone columns and its equivalent concentric

crowns as generated by the FLAC 3D code.

Table 2 presents the characteristics of three numerical

modeling implemented by the FLAC 3D code when the

group of stone columns is adopted.

Table 3 presents the characteristics of three numerical

modeling implemented by the FLAC 3D code when

adopting the ECC.

The interpretation of numerical predictions by the FLAC

3D code is given below.

(a) Group of stone columns (GSC)

Figure 6 compares between the settlement predictions

obtained by the three modeling 1a, 2a, and 3a of a

group of stone columns. From Fig. 6, when the

applied load is equal to or greater than 100 kPa,

Modeling 1a (7 stone columns) overestimates the

settlement of reinforced soil by 14.6–15% compared

to predictions byModeling 2a and 3a (19 and 37 stone

columns). The difference in predictions by Modeling

2a and 3a remains insignificant (less than 5%).

Fig. 5 Finite-difference

discretizations generated using

the FLAC 3D code-A zoomed

view: a group of stone columns;

b equivalent concentric stone

crowns

Table 3 Characteristics of numerical modeling of equivalent con-

centric crowns as implemented by the FLAC 3D code

Modeling of equivalent concentric

crowns

FD

zones

Grid

points

Cycle

1b 3136 3375 5644

2b 4928 5295 6237

3b 8512 9135 8560

1 Page 6 of 12 Innov. Infrastruct. Solut. (2017) 2:1

123

(b) Equivalent concentric crowns (ECC)

Figure 7 compares between the settlement predic-

tions when adopting the three ECC modeling. From

Fig. 7, the predictions of settlement of reinforced

soil are quasi similar by Modeling 2b and 3b (2 and 3

ECC), up to load of 130 kPa. Whilst the use of

modeling 2a (1 ECC) significantly overestimates the

settlement prediction from load of 60 kPa.

From Fig. 7, it is also noted the settlement prediction

by one ECC modeling is greater than those predicted

by the 2 and 3 ECC modeling.

(c) Comparing between GSC and ECC modeling

First, it is worth noted that the GSC represents the

more realistic modeling as the columns are usually

installed in regular pattern to cover the completely

loaded area.

0 20 40 60 80 100 120 1400

2

4

6

8

Set

tlem

ent (cm

)Load (kPa)

group of 37 columns group of 07 columns group of 19 columns

Fig. 6 Soil behavior of columns reinforced foundation with a group

of 7, 19, and 37 stone columns

0 20 40 60 80 100 120 1400

2

4

6

8

10

12

Set

tlem

ent (cm

)

Load (kPa)

1 concenrtric crown 2 concenrtric crown 3 concenrtric crown

Fig. 7 Soil behavior of columns reinforced foundation with 1, 2, and

3 equivalent concentric crowns (ECC)

0 20 40 60 80 100 1200

a

b

c

2

4

6

8

10

12

Set

tlem

ent (cm

)

Load (kPa)

Unreinforced soil group of 07 columns 1 concentric crown

0 20 40 60 80 100 1200

2

4

6

8

10

12

Set

tlem

ent (cm

)

Load (kPa)

Unreinforced soil group of 19 columns 2 concentric crowns

0 20 40 60 80 100 1200

2

4

6

8

10

12

Set

tlem

ent (cm

)

Load (kPa)

Unreinforced soil group of 37 columns 3 concentric crowns

Fig. 8 a Variation of applied load versus settlement using a group of

07 stone columns and ECC. b Variation of applied load versus

settlement using a group of 19 stone columns and two ECC.

c Variation of applied load versus settlement using a group of 37

stone columns and three ECC

Innov. Infrastruct. Solut. (2017) 2:1 Page 7 of 12 1

123

The predictions of settlement using the three ECC

modeling and respective GSC modeling are com-

pared from Fig. 8a–c.

Figure 8a shows that quasi-identical predictions of the

settlement of reinforced soil are obtained by adopting

either the modeling using a group of seven columns or the

respective one ECC modeling. The maximum difference of

settlement prediction between the two modeling equals

0.49 cm that is negligible for predicting the settlement

under surcharge load of 120 kPa.

In turn, Fig. 8b, c clearly shows that when the number of

stone columns increases, as well as for the number of

respective ECC, the difference between the settlement

predictions also increases, especially when the surcharge

load exceeds 80 kPa. Furthermore, an opposite trend is

marked for the difference between the two settlement

predictions, i.e., the two ECC modeling provides lower

settlement than that obtained by a group of 19 columns.

Figure 8 shows that Modeling 3b (three ECC) predicts

less settlement than that obtained by Modeling 3a (37 stone

columns) especiallywhen the applied load is beyond or equal

to 100 kPa. Such prediction is explained by the fact that the

ECC, as continuous walls having much higher stiffness than

that of soft soil, provides much better confining effect within

the surrounding soil in particular in the central part of the

loaded foundation. Hence, the settlement prediction by the

group of columns, which provides lesser confining effect, is

higher than that predicted by the 3 ECC modeling.

Algiers harbor case history—full-scale load testson a column-reinforced foundation

Local ground conditions of Algiers Harbor area

In the framework of the Algiers Harbor extension project,

the consolidation of the quays and creation of new docks

were recently launched at the end of 2015. After the

Algerian seismic standards RPA 2003, Algiers City

belongs to zone 1 that is classified with high potential

seismic risk. Furthermore, the soil profile of Algiers Harbor

comprises an intermediate sand layer that might be sub-

jected to the liquefaction phenomena. Hence, a ground

improvement solution of existing soil layers was decided to

mitigate the liquefaction risk and to reduce settlements of

compressible soil layers.

The investigation of underground conditions at the site

of project showed the ability in using the improvement by

the deep vibro-techniques. After Fig. 9, the grain size

distribution of the soil layers matches well with the known

recommendations in regard to the limits of applications of

deep vibro-techniques.

The soil profile illustrated in Fig. 10 shows a 1-m-thick

clay layer sandwiched between silt clayey sand and fine

sand layers. Several undisturbed samples were extracted

within the soil profile at various depths and then subjected

to laboratory tests.

0,001 0,01 0,1 1 10 1000

10

20

30

40

50

60

70

80

90

100

0

10

20

30

40

50

60

70

80

90

100

Depth 3,50m-3,95m Depth 5,85m-6,30m Depth 9,45m-9,90m Depth 11,50m-12,10m Depth 12,10m-12,55m Depth 14,55m-15m Depth 18,20m-18,65m

Per

cent

age

pass

ing

[by

wei

ght]

(%)

Particle size (mm)

limits of application for stone columns technique

Clay Silt Fine Sand Coarse Sand Gravel CobblesFig. 9 Grain size distribution

curves of the different layers in

Algiers harbor region

1 Page 8 of 12 Innov. Infrastruct. Solut. (2017) 2:1

123

Full-scale loading tests on soil reinforced by stone

columns

A series of full-scale load tests was undertaken to capture

the behavior of soil layers reinforced by stone columns.

Figure 11 displays: (a) the excavation at the top side of

installed stone columns confirms a diameter of 84 cm;

(b) stone columns were installed in triangular pattern with

axis-to-axis spacing equals to 1.8 m. The area ratio of this

trial test is 100%. The length of the installed stone columns

was 7.5 m. About the properties of sand layers and marl

stone layer underneath, the installed stone columns are of

end-bearing type.

The plot tests included the installation of 28 stone

columns, a single column is loaded. The column subjected

to the loading test is located at the center of area where the

28 SCs were installed. The full-scale loading test consisted

of incremental applied load with measurement of settle-

ment using three sensors. As such, the loaded stone column

surrounded by the 27 installed stone columns is assumed to

behave in oedometer condition due to the confinement

provided by those columns.

Load-settlement curves drawn from those loading tests

represent the best indicator to assess the predictions by the

FLAC 3D code to simulate the real behavior of CRF. The

unit cell model was, first, investigated by the finite-differ-

ence method implemented by the FLAC 3D code. The soil

layers and column material have been modeled by the

Mohr–Coulomb constitutive law with the properties sum-

marized in Table 4.

Figure 12a–c shows the respective numerical predic-

tions by the FLAC 3D code compared to measured load-

settlement data. It should be noted that the two numerical

modeling do not consider the improvement of mechanical

characteristics of the initial soil due to the installation of

stone columns.

In a second attempt, the simulation of numerical mod-

eling that comprises 28 installed stone columns with loaded

central stone column has been studied (Fig. 12b). Two

numerical models generated by the FLAC 3D code have

been tested to predict the load-settlement curve. Fig-

ure 12b, c shows that the real behavior of loaded single

stone column belonging to a group of stone columns is

much better predicted than the behavior of an isolated

column.

Fig. 10 Typical ground cross section of Algiers harbor area

Fig. 11 Stone column viewed

after installation

Innov. Infrastruct. Solut. (2017) 2:1 Page 9 of 12 1

123

The two FLAC 3D well illustrates the importance of the

group effect on the settlement reduction that results from

the installation of a group of stone columns.

Figure 13 shows the settlement predictions obtained

from the 3D group of stone columns and the equivalent

concentric crowns. As seen from this figure, the two gen-

erated FLAC 3D numerical modelings (GSC and ECC)

predict similar results up to uniform load of 120 kPa. In

this range of applied load, it is agreed that the ECC mod-

eling is favored because of its simplest numerical handling

Table 4 Geotechnical

parameters of soil layers at

Algiers harbor region

Parameters Unit Soil 1 Soil 2 Soil 3 Soil 4 Stone columns

c kN/m2 16.68 16 17.66 15.20 21

u Degree 32 0 32 15.04 40

C kPa 0 4.325 0 298 0

Pressure meter modulus EM MPa 10.27 13.39 44.1 62.9 60

v – 0.27 0.27 0.27 0.30 0.33

Constitutive model – Mohr

Dc m – – – – 0.84

(a)

(b) (c)

Fig. 12 Load vs settlement of the full loaded stone column: a FDM—isolated SC; b FDM—group of SC; c predicted vs measured settlement of

the loaded stone column

1 Page 10 of 12 Innov. Infrastruct. Solut. (2017) 2:1

123

about that required by the GSC modeling. However, for all

applied loads, the predictions made by the GSC modeling

fit well with full-scale load test measurements from the

Algiers harbor case history.

Summary and conclusions

The settlement prediction of a foundation on a soil rein-

forced by stone columns has been investigated in

oedometer condition. Three numerical modelings were

implemented by the FLAC 3D code: unit cell model

(UCM), group of stone columns (GSC), and equivalent

concentric crowns (ECC). The data from the Zarzis case

history (Tunisia) served for the validation of predictions

given by the UCM.

The data collected from the recent Algiers harbor stone

columns project were considered to validate the predictions

obtained by three configurations of the GSC and ECC

modeling at constant area ratio. The main findings from

this research work are summarized as follows.

• Settlements predicted in case of uniform stress load

with an isolated stone column (unit cell model) were

underestimated compared to those obtained by a group

of stone columns modeling. This is due to the

confinement imposed on the lateral border of the

UCM resulting from zero horizontal displacement.

• In oedometer condition and with identical area ratio, it

is concluded that increasing the number of stone

columns by the generated 3D numerical modeling does

not significantly affect the settlement prediction of

reinforced soil up to surcharge loads of 120 kPa.

Therefore, the behavior of a CRF is not greatly affected

by the variation of stone columns number.

• Predictions obtained by the UCM showed that the

settlement by Bouassida et al. [6]’s linear elastic

method fits well with predicted results by the GSC

modeling 3a.

• By comparing 3D settlement predictions, a good

agreement has been shown between the reduced

equivalent concentric stone crowns and the group of

vibro-replacement end-bearing stone columns. Indeed,

the maximum relative error of 9, 27, and 20% has been

registered in the case of 7, 19, and 37 stone columns

equivalent to 1, 2, and 3 concentric stone crowns,

respectively.

• From the Algiers harbor case history, the measurements

of settlement during the full-scale load test conducted

on soil reinforced by stone columns permitted the

validation of predicted settlement by the three equiv-

alent concentric crown FLAC 3D modeling.

Acknowledgements The authors would like to appreciate Professor

Ali Bouafia (University of Blida, Algeria) for his kind support in

providing the data of stone columns project at Algiers Harbor.

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0 50 100 150 200

0 50 100 150 200

-7

-6

-5

-4

-3

-2

-1

0

-7

-6

-5

-4

-3

-2

-1

0

Load (kPa)S

ettle

men

t (mm

)

Group of stone columns Equivalent Concentric crown Full loading test

Fig. 13 Settlement predictions of the full loaded stone column—

GSC vs ECC

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