11.[49 58]an experimental investigation on interference of piled rafts in soft soil

Civil and Environmental Research www.iiste.org
ISSN 2222-1719 (Paper) ISSN 2222-2863 (Online)
Vol 2, No.2, 2012

An Experimental Investigation on Interference of Piled Rafts
in Soft Soil
S.P.Bajad1* R. B. Sahu2
1.Applied Mechanics Department, Government Polytechnic, Amravati, 444603, INDIA
2. Civil Engineering Department, Jadavpur University, Kolkata – 700032, INDIA
* E-mail of the corresponding author: spbajad@gmail.com

Abstract
By using small scale model tests, the interference effect on the vertical load-deformation behavior of a
number of equally spaced rafts and piled rafts, placed in the artificially consolidated soft clay was
investigated. The effect of spacing (s) among foundations on the results was explored. A new experimental
setup was proposed in which uniform load was applied by using steel beam of adequate flexural strength
and ball bearings to transfer the vertical load equally on both the foundations. The bearing capacity
decreases continuously with decrease in spacing among the foundations. The interference effect becomes
further prominent with piled raft foundation. In contrast to decrease in the bearing capacity, with decrease
in spacing of foundations, an increase in the foundations settlement associated with the ultimate state of
shear failure was observed. The present experimental observations were compared to the results obtained
by using PLAXIS. The results of this laboratory investigation will be helpful in finding the minimum
spacing between the rafts and piled raft foundation for better performance.

Keywords: Piled raft; Model test; soft clay; Interference effect; spacing; PLAXIS

1. Introduction
When considering foundations for high-rise buildings in urban areas, a major task is to restrict the
settlement and differential settlement of the new structures and adjacent buildings to ensure their safety and
serviceability. Compared to traditional piled foundations, where building loads are assumed to be
transferred to the soil only by piles, the piled raft foundation is a new approach.
The study of the interference between closely spaced foundations of a particular structure is
of fundamental importance to both geotechnical and structural engineering. Information regarding
settlement, tilt and bearing capacity is required for an adequate design of the foundation. The mutual
interference of foundations in a group has a significant influence on these design factors.
Stuart (1962) examined the state of interference, between two parallel strip footings placed at varying
distances from each other on cohesion less soil. Mandel (1965) investigated a more general problem with
structures on either side of a footing using the method of characteristics for a c – φ soil. Both Stuart and
Mandel demonstrated that a decrease in spacing between strip footings produced an increase in bearing
capacity. They introduced factors reflecting the efficiency of interference for bearing capacity between
footings. Agarwal (1970) investigated the interference effect for both strip and rectangular footings. An
increase in the bearing capacity and simultaneous increase in the settlement characteristics was observed
when the centre to centre spacing between the footings was reduced. Verma & Saran (1987) studied the
effect of interference between two adjacent strip footings by using non- linear constitutive laws of soils. All
the three aspects i.e. bearing capacity, settlement and tilt has been studied in clays and sands. Saran &
Agrawal (1974) carried out two and three dimensional model tests to investigate the interference effect of
footings in dry sand on settlement and bearing capacity.
Singh et al. (1973) reported experimental investigations on the interference effect of two adjacent smooth,
square footings subjected to vertical load in cohesion less soil. It was observed that the interference changes
both the load at failure and the settlement characteristics to values different from those of isolated footings.
The interference of footings on dense sand was observed to cause an increase in bearing capacity and

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Vol 2, No.2, 2012

decrease in settlement with reduction of spacing. J.Kumar & P.Ghosh (2007) presented the ultimate bearing
capacity of two interfering strip footings by using the method of stress characteristics.
L.de Sanctis & G.Russo (2008) reported case histories of five storage tanks resting on piled rafts in Port of
Napoli for settlement and load sharing. They also studied the interaction effects between the different
foundations and compared the result with the program NAPRA. The tilting of foundations due to
interaction between adjacent piled rafts and the corresponding change in load sharing has been reported.
From the above review of literature it has been observed that interference effect of rafts and piled rafts have
great influence on the settlement and bearing behavior of the structures, but all the reported case studies as
well as laboratory models were either on stiff clay or sand bed. The study on piled raft foundations
embedded in soft clay has not, however, been well addressed in the literature. In recent years, a large
number of tall buildings are being constructed in and around Kolkata over soft alluvial deposits. For these
structures piled rafts are, in general, being adopted to support the superstructure. In some cases, a number
of piled rafts of small sizes are used under one building instead of a single large raft covering the whole
building area. In such cases it seems that small sized piled rafts may have interfering effects due to the
superposition of their pressure bulbs and may result in variation of settlements. Presently, no studies have
been reported on the increase in settlement of smaller piled raft due to interference effect. The present paper
highlighted increase in settlement of small piled raft due to interference effect obtained through a series of
model tests over piled rafts in artificially consolidated soft clay deposit.

2. Experimental Work
The interference effect of rafts and piled rafts were studied by conducting 17 tests of load-settlement and
time-settlement for different spacing.
Mild steel plate of size 200 mm x 200 mm and thickness 10 mm were used as model rafts. Model hollow
piles made of steel of uniform diameter 10 mm and length 200 mm were used in the present
investigation. External surface of the piles were glued with fine sand to simulate roughness of field concrete
piles. The model test program is given in Tables 1, 2 and 3.

2.1 Interference of Rigid rafts
Six tests on interfering rigid rafts with different spacing are conducted to understand the effect of
interference on load bearing capacity of rigid rafts. The details of tests are shown in Table 1.
Six tests on interfering rigid rafts with different spacing were conducted to understand the effect of
interference on time dependent settlement of rigid rafts. The details of tests are shown in Table 2.

2.2 Interference of Rigid piled rafts
Time dependent settlement behaviour of typical rigid piled raft with 36 piles of 200 mm length was used to
carry out the tests. Five tests with different spacing between the piled rafts were carried out. The details of
tests are given in Table 3.
For the purpose of analyzing the test results the working loads were normalized by using a normalized load
factor N* = P/cu B2, where, P – working load, cu – undrained shear strength (cohesion) and B – width of raft.
The normalized load factors computed corresponding to the working load at factor of safety of 2.5 for the
raft was 2.5. A detail of pile arrangement for model piled raft adopted in the present investigation is shown
in Fig. 1.
A model tank of size 700 mm x 1400 mm x 600 mm made up of mild steel plates of 5 mm thickness was
used for carrying out model tests on interfering rafts and piled rafts. The tank size was sufficiently larger
than the zone of influence to avoid edge effect. A new experimental setup was used in which uniform
load was applied by using steel beam of adequate flexural strength and ball bearings to transfer the vertical
load equally on both the foundations. Schematic diagram of the model test set up is given in Fig.2.
All the model tests were carried out following the procedure described below. The consolidated soil bed
was prepared in control condition for every test to get similar shear strength and other properties of soil.

2.2 Interference of Rigid piled rafts
Firstly large lumps of air-dried clay were broken; water was added and kept for 24 hours in order to prepare

50

Vol 2, No.2, 2012

soil slurry of water content nearly 55 %. Then, the soil was placed in the mild steel bin (tank) in three layers,
each being 150 mm to 200 mm in height and consolidated under the consolidation pressure of 30 kPa. A
high stack of dead weights were required to be placed over the clay layer in order to reach the specified
consolidation pressure. Consolidation period for the first two layers was 48 hours (2 days) for each layer
and for the third layer it was 7 days. Undrained shear strength of the consolidated clay as measured by vane
shear tests was found to be 8 ±0.5 kPa
Following the consolidation of the clay bed, model piles of specified lengths were driven vertically in the
consolidated clay bed with the help of the template of 20 mm thickness. Next, the model raft was placed
over the piles. The piles were connected to the raft by bolting, so that the piled raft acts as a monolithic
structure. Further, for tests on piled raft and individual raft, full contact between the soil bed and the raft
was ensured.
After the model set up is ready, the lever was placed over the piled raft for applying the load. To measure
settlement, two linear variable displacement transducers (LVDT) having a 50 mm range with 0.01 mm
sensitivity were used. For determining the immediate settlement, loads were applied in gradual increment
and settlements were recorded till there was no appreciable change in settlement for a particular load
increment. Then the next load increment was applied. The tests were continued until the settlement was
more than 10 % of width of the raft.

2.4 Interference of rafts and piled rafts
Tests were performed on two model rafts of size 200 mm × 200 mm placed at different spacing on clay bed
in a tank of inside dimensions 1400 mm long, 700 mm wide and 600 mm high. Vertical loads were
applied to each model footing by a lever arrangement. At any stage, all the foundations were assumed to (i)
carry exactly equal magnitude of load, and (ii) settle to the same extent. No tilt of the foundation was
permitted. The tests were performed at a center-to-center spacing between the footings as 1 B, 1.25B, 1.5B,
1.75B and 2B, where B is the width of rafts and rafts were loaded simultaneously.
The working loads were calculated by applying a factor of safety (F.S.) 2.5 to the ultimate load carrying
capacity of the corresponding unpiled raft. The ultimate load carrying capacity was determined from the
load settlement curves at an immediate settlement of 10 % of B (width of raft) as suggested by Cooke
(1986). These findings have been recently confirmed by centrifuge tests (Conte et al. 2003), as well as field
tests (Borel 2001). These working loads were applied on the piled rafts and rafts to study their time
dependent settlement behavior for a period of 48 hours, thereafter settlement ceases. During the experiment,
soil deformation was monitored and the settlement readings were taken at regular time intervals until the
relationship between settlement and the logarithm of time became nearly horizontal. In all the cases, the
tests were repeated to check their reproducibility.

3. Numerical Analysis

By using the PLAXIS 3D FOUNDATION Version 2.2 software, numerical investigation has been carried
out for the load settlement and time settlement behaviour of rafts and piled rafts of size 200 mm square.
The piles in the piled raft foundation were modeled using embedded piles. The Hardening Soil model with
Small-Strain stiffness (HSsmall) is used for simulating the soft soil behavior. The soil used in the present
investigation is of soft consistency with cohesion 8 ± 0.5 kN/m2. For this type of soil, the modulus of
elasticity under undrained conditions is in the range of 70 – 250 times cohesion coefficient (Bergado et al.
1990). Accordingly, Unloading/reloading stiffness has been considered to be 150Cu = 1200 kN/m2. As per
PLAXIS reference manual E50ref = Eoedref = Eurref / 3. Further, initial or small strain shear modulus has
been estimated by back calculating initial stiffness from the load settlement curve of the raft at very small
settlement. All other parameters are selected using the guideline of reference manual of PLAXIS.

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Vol 2, No.2, 2012

4. Test Results and Discussion

4.1 Load-Settlement Behavior

4.1.1 Interference of Rigid Rafts

The interference effect on the vertical load-deformation behavior of a number of equally spaced rafts,
placed in the artificially consolidated soft clay was investigated and is shown in Figure 3. The effect of
center-to-center spacing (s) among foundations on the ultimate bearing capacity of interfering rafts was
presented in the figure .The test results of load settlement tests carried out for interference of rigid rafts of
200 mm square size placed at centre to centre spacing of 1.0B, 1.25B, 1.5B, 1.75B & 2.0B are plotted in the
figure. The results obtained would serve for comparative analysis of the ultimate bearing capacity of
interfering rafts with respect to spacing between them.

4.1.2 Time-Settlement Behavior

The working load corresponding to a factor of safety (F.S.) 2.5 was applied on the rafts and piled rafts with
36 numbers of piles, seems to be optimum, of 10 mm diameter and 200 mm length and centre-to-centre
spacing of 1.0B, 1.25B, 1.5B and 2B to study the time dependent settlement.
The time settlement curves for interfering rigid rafts of 200 mm square size at working load
with normalized load factor of 2.5 are plotted for different spacing between rafts and are shown in figure 4.
Typical case of rigid piled rafts of 200 mm square raft size and 36 piles of 200 mm length are used for
studying the interference effect of piled rafts (Rarea=7.6%). The time –settlement curves for interfering
rigid piled raft with different spacing between them and at the normalized load factor, N* = 2.5 are shown
in figure 5.

4.2 Interference Effect of Raft and Piled Raft

The load on a footing resting on soil stresses a particular prism of the soil. Usually, at failure, this zone
extends to 2.5 times the width of the footing on either side of the footing in horizontal direction and twice
the width of the footing in the vertical direction. An adjacent footing placed at spacing less than 2.5 B, B
being the width of footing, the failure zones of two footings will interfere with each other. Due to this, the
bearing capacity and settlement characteristics of such interfering footings will be different from that of
isolated footings.This phenomenon of interference in foundations is of greater practical interest in closely
built in areas where there may be overlapping of pressure bulbs in the foundation soils. Similar thing may
occur when a large size raft/piled raft of a particular building is replaced by rafts/piled rafts of smaller sizes.
An attempt has been made to study the settlement characteristics of such foundation and the results are
discussed in the following section.

4.2.1 Load-Settlement Behavior
By using small-scale model tests, the interference effect on the vertical load-deformation behavior of a
number of equally spaced rafts, placed on the artificially consolidated soft clay was investigated. The effect
of center-to-center spacing (s) among foundations on the ultimate bearing capacity of interfering rafts were
presented in terms of interference factor and shown in Figure 6. The interference factor (If) is defined as the
ratio of ultimate bearing capacity of interfering rafts to the ultimate bearing capacity of isolated raft. From
the figure, it is clear that the interference factor (If) increases continuously with increase in spacing between
the foundations and is nearly 1.0 at s/B of 2.0 beyond which effect of interference seems to be negligible.

4.2.2 Time Dependent Settlement Behavior

The total settlement of interfering rafts and piled rafts of size 200 mm square and 200 mm pile length at

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Vol 2, No.2, 2012

N* = 2.5 and pile to raft area ratio = 7.6 %, for different spacing (s/B) between the foundations and are
presented in the Figure 7, as the ratio of total settlement of interfering raft/piled raft to total settlement of an
isolated raft/piled raft. From the figure it may be seen that the ratio of total settlement of interfering
raft/piled raft to that of an isolated raft/piled raft is maximum when the spacing between the interfering
model foundations is in the range of 1.0 - 1.25 times width of raft. The maximum value of this ratio for
only raft is found to be somewhat higher than that of piled raft. Beyond s/B 1.25 the ratio reduces with the
increase in spacing and become close to that of isolated one at s/B=2.0. In figure 7, PLAXIS results are also
presented. These numerical analysis results are in good agreement with experimental one.

5. Conclusion

By using small scale model tests, the interference effect on the load-deformation and time settlement
behavior of rafts and piled rafts placed on the artificially consolidated soft clay were investigated.

From the results of this study, the following conclusions can be drawn

The settlement of piled raft is initially higher at spacing below 1.25 times width of raft due to
interference effect, thereafter, reduces with the increase in spacing, and becomes close to that
of isolated one at spacing of twice the width of raft.
The bearing capacity of rafts due to interference effect decreases continuously with decrease in
spacing among the foundations.

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Vol 2, No.2, 2012

References

Alamsingh, Punmia B.C. & Ohri M.L. (1973), “Interference between adjacent square footings on
cohesionless soil”. Indian Geotechnical Journal 275-284.
Bergado DT, Sayeed Ahmad,Sampaco CL, Balasubramaniam (1990), “Settlements of Bangna-Bangpakong
Highway on soft Bangkok Clay”. ASCE Jr.of Geotech Eng Vol.116 No.1 ,137-155.
Cooke, R.W. (1986). “Piled raft foundations on stiff clays: a contribution to design philosophy”.
Géotechnique, 36, No 2, 169-203
de Sanctis, L., and Russo, G.(2008) “Analysis and Performance of Piled Rafts Designed Using Innovative
Criteria” Journal of Geotechnical and Geoenvironmental Engineering, Vol. 134, No. 8, 1118-1128
Hain, S.J. and Lee, I.K. (1978). “The Analysis of Flexible Raft-Pile Systems”. Geotechnique, 28 (1): 65-83.
Jyant Kumar and Priyanka Ghosh (2007),” Ultimate Bearing Capacity of Two Interfering Rough Strip
Footings” International Journal of Geomechanics, Vol. 7, No. 1, 53-62
Kumar, A., and Saran, S. (2003). “Closely spaced footings on geogrid reinforced sand.” J. Geotech.
Geoenviron. Eng., 129(7), 660–664.
Mandolini, A., Russo,G., and Viggiani, C. (2005). “Pile foundations: Experimental investigations, analysis
and design.” State-of-the-Art Rep., Proc., 16th Int. Conf. on Soil Mechanics and Geotechnical Engineering,
Vol. 1, Osaka, Japan, 177–213
PLAXIS, (2009), Reference Manual, PLAXIS B.V., Netherlands
Poulos, H.G. and Davis, E.H. (1980). Pile foundation analysis and design. John Wiley & Sons, New York
Saran S, Agarwal VC (1974) “Interference of surface footings on sand”. Indian Geotechnical Journal
4(2):129–139
Saran and A A A Amir.(1992). “Interference between Surface Strip Footings on Cohesive Soil”. IGC-92,
Calcutta, vol 1, 1992, pp 77-81
Stuart JG (1962) “Interference between foundations, with special reference to surface footings in sand”.
Geotechnique 12(1):15–22
Verma, G. S., and Saran, S. (1987), ‘‘Interference effects on the behaviour of footings.’’ Proc., 9th
South-East Asian Geotechnical Conf., 229–239.

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Figure 1. Pile arrangement for 200 mm square raft with 62 piles in groups in piled raft foundations.

1- Loading Frame

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Vol 2, No.2, 2012

2- Model Tank
3- Loading Arrangement Model Raft / Piled raft (Two )
4- Linear variable displacement transducers (LVDT) (Two)

Figure.2. Schematic Diagram of Model Test set up.

Load (N)
0 1000 2000 3000 4000 5000 6000
0

5
Settlement (mm)

10

15

s/B=0
20 s/B=1.0
s/B=1.25
25 s/B=1.5
s/B=1.75
s/B=2.0
30

Figure.3. Load-settlement for interference effect of rafts with different s/B
(Rigid rafts: 2 - 200 mm X 200 mm).

Time in minute (Log scale)

0.1 1 10 100 1000 10000
0

1
Settlement(mm)

2

3 s/B=0.0
s/B=1.0
s/B=1.25
4 s/B=1.5
s/B=1.75
s/B=2.0
5

Figure 4. Time -settlement of Interference of Rigid Rafts with
different spacing ratio (s/B) for Normalized load factor (N*) of 2.5.

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Vol 2, No.2, 2012

Time in minute (Log scale)

0.1 1 10 100 1000 10000
0

0.4
Settlement(mm)

0.8

1.2
s/B=0.0
s/B=1.0
1.6 s/B=1.25
s/B=1.5
s/B=2.0
2

Figure 5. Time -settlement of Interference of Piled Rafts 36-200(Rarea =7.6%)
with different spacing ratio (s/B) for Normalized load factor (N*) of 2.5.

1.00
Interference factor IF

0.95

Raft interference

0.90
1 1.25 1.5 1.75 2 2.25
Spacing (s/B) of rafts (s/B)

Figure 6. Variation of interference factor (IF) with spacing of rafts (s/B).

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Vol 2, No.2, 2012

Figure 7. Total settlement ratio vs spacing (s/B) for Interference of two PRF 36-200 (Rarea=7.6%)
& Rigid rafts for the normalized load factor (N*) of 2.5.

58

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11.[49 58]an experimental investigation on interference of piled rafts in soft soil