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Engineering, Technology & Applied Science Research Vol. 11, No. 5, 2021, 7653-7657 7653 
 

www.etasr.com Nguyen &Nguyen: Effects of Shaft Grouting on the Bearing Behavior of Barrette Piles: A Case Study in … 

 

Effects of Shaft Grouting on the Bearing Behavior of 

Barrette Piles: A Case Study in Ho Chi Minh City  
 

Phu-Huan Vo Nguyen 

Infrastructural Technique Department 

Faculty of Civil Engineering 
Ho Chi Minh City Open University 

Ho Chi Minh City, Vietnam 
huan.vnp@ou.edu.vn 

Phu-Cuong Nguyen 

Advanced Structural Engineering Laboratory 

Structural Engineering Department 
Faculty of Civil Engineering 

Ho Chi Minh City Open University 
Ho Chi Minh City, Vietnam 

cuong.pn@ou.edu.vn 
 

 

Abstract—The shaft-grouted method has been applied on high-
rise buildings in Ho Chi Minh City for the purpose of increasing 

the bearing capacity of barrette piles. The Exim Bank Building 

foundation, using two kinds of shaft-grouted barrette piles, was 

65m (TP1) and 85m (TP2) in depth. To assess the bearing 

capacity, this project assembly used the O-cell tools installed at 

49m depth below the pile head level. Shaft grouting was 

performed from -25m to the TP1 pile toe level and -65m to the 
TP2 pile toe level. This work is based on the data from the O-cell 

experiments at the construction site and the results of finite 

element simulation in Plaxis software. The effectiveness of shaft 

grouting was analyzed and the length and position of the ejector 

were evaluated and compared in order to find the best solution 

for applying shaft grouting with the aim to ensure safety and 
mitigate economic problems. 

Keywords-bearing capacity; barrette pile; shaft grouting; O-cell 

test; Plaxis 

I. INTRODUCTION  

High-rise building foundations in Ho Chi Minh City are 
constructed by using bored piles and barrette piles to ensure the 
total loads of structures. The shaft resistance using the grouting 
method has been reported in [1-3, 7, 8, 11]. Authors in [7] 
carried out laboratory tests in sand to find the behavior of 
density, soil gradation, and stress on the shaft resistance in 
grouting methods. The increase of shaft resistance was 
indicated by the low mobility grout. Authors in [2, 3] studied 
the bored piles in Ho Chi Minh City. In the results, the shaft 
resistance development in bored piles gains maximum 
resistance after a movement of only 3mm to 4mm. The 
Osterberg test (O-cell test) in principle is exactly the same as 
the static compression test, and it is dedicated to bored piles 
and barrettes. The testing principle is to apply the load directly 
on the pile tip or the pile body using a device called Osterberg 
cell. It is quite possible to use the pile load, the lateral soil 
friction, and the tip resistance as counterweights to increase the 
load. The Osterberg test method will give a result in which the 
two curves of load and displacement at the pile tip and pile 
head are built independently. The purpose of this paper is to 
evaluate the effectiveness of shaft grouting method on the 
barrette piles in Ho Chi Minh City and compare it with the no 

shaft-grouted method in order to find the best position to install 
the ejector using the Finite Element Method (FEM). 

II. PROJECT INFORMATION 

The Eximbank building is located at District 1, Ho Chi 
Minh City. It consists of 5 basements and 40 storys with a 
construction area of 3518m

2
. Its design adopts 2 barrette test 

piles of 2800×800mm size and 15MN load [3]. The TP1 pile is 
65.3m in depth near the borehole no. 2. The TP2 pile is 85.3m 
in depth near the borehole no. 8. Their designed to be grouted 
lengths are 40m for TP1 and 21m for TP2 respectively from 
their upward tips. The geological survey report states the soil 
condition at the test piles as follows: soft clay stratum at a 
depth of 7m, sandy stratum at the tips at 41m, mixed clay at 
52m and finally a dense and very dense sandy stratum. O-Cell 
hydraulic jack is installed 16m from the pile tip and 
strainometers are installed along its body as shown in Figure 4 
of [3]. Figure 1 shows how to install the equipment on the 
cross-sectional area of the two piles in which the main 32-dia 
steel bar of each pile is joined with the loop reinforcement to its 
frame. The total main steel bar area of the pile is 289cm

2
 and 

the pile cross-sectional area is 2.24m
2
. The grout pipe with a 

diameter of 60mm is mounted around the perimeter of the steel 
frame throughout the length of the pile and 39.7m and 21.2m 
lower than the lengths of TP1 and TP2 respectively. The grout 
pipe must be perforated to allow the grout to escape and it can 
be capped to ensure a secure grouting. 

 

 
Fig. 1.  Cross section and details of installation equipment for piles. 

Corresponding author: Phu-Huan Vo Nguyen



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III. PILE LOAD-BEARING ANALYSIS 

A. Test Results in Site 

The results of the force-displacement relationship curve of 
the O-cell test performed on the two test piles TP1 and TP2 can 
be seen in Figure 7 of [3]. The force acting on the O-cell is 
evaluated and adjusted subjecting to the pile self-load and the 
water pressure at the depth of the O-cell placement. After the 
duration of holding the maximum load is over, the 
displacement values of the lower O-cell are 9.0mm and 5.9mm, 
and the pile tip displacement values are 4.6mm and 2.2mm 
respectively. The displacement values of the upper O-cell are 
6.7mm and 6.9mm and the pile end displacement values are 
1.2mm and 0.8mm. 

B. FEM Analysis 

The determination of the input data for the model is made 
on the basis of the correlation equations and empirical 
researches [9, 12-14] as follows: 

• The Young’s modulus, E50ref, is determined from the 
drained 3-dimensional (3-D) consolidation test with the 
selected chamber pressure level σ3 in accordance with the 
actual state of the soil profile. 

• Drained shear strength parameters are taken from the 
drained 3-dimensional consolidation test or as the effective 
shear strength values in the undrained 3-D consolidation 
test. For the soil profile without the 3-D CU test, CD can be 
obtained from the direct shear strength test, but its 
reliability is not high. The undrained shear strength 
parameter also does not take the friction angle of the ground 
soil, φu = 0, into account but only the adhesion force of the 
soil Cu. Cu values are obtained through the undrained 3-D 
test, the in-situ shear vane test, or the 1-dimensional 
unconfined compressive test. 

• For dense layers of sand or over-consolidated layers of clay, 
the expansion angle ψ exists. Normally, according to the 
instructions of Plaxis software, ψ = φ - 30

0
. In other cases, 

the expansion angle is equal to 0. 

The parameters of the Hardening Soil model are determined 
directly from the geological survey report test results or from 
the correlation equations of the previous researches to obtain 
the values summarized in Table I. 

TABLE I.  SOIL PARAMETERS IN FEM 

No. Backfill 
Layer 

1 

Layer 

2 

Layer 

3 

Layer 

3b 

Layer 

4 

Layer 

6 

Type HS HS HS HS HS HS HS 

γunsat (kN/m
3
) 18.56 14.61 18.42 18.35 19.23 20.38 19.93 

γsat (kN/m
3
) 18.80 15.59 19.31 19.21 19.94 20.66 20.62 

E
ref

50 (kN/m
2
) 11210 4000 18000 60000 80000 95000 90000 

E
ref

oed 

(kN/m
2
) 

11210 4000 18000 60000 80000 95000 90000 

E
ref

ur (kN/m
2
) 56030 20000 90000 250000 370000 350000 330000 

m 0.75 1 0.85 0.5 0.5 0.75 0.6 

νur 0.2 0.2 0.2 0.2 0.2 0.2 0.2 

c (kN/m
2
) 22.41 13.77 36 4.1 4.1 218.4 1.7 

φ 
(o)

 0 0 4.8 32.49 32.49 0 37.00 

ψ 
(o)

 0 0 0 2.49 2.49 0 7.00 

Rinter 0.85 0.7 0.7 0.85 0.85 0.85 0.85 

To make load capacity comparison easier, the 4 used 
models in Plaxis 2D software were: 

• Model 1: TP1 pile with grouting 

• Model 2: TP1 pile without grouting. 

• Model 3: TP1 pile with grouting only from -26.3m to  
-48.5m. 

• Model 4: TP1 pile with grouting only from -48.5m to  
-65.5m. 

Firstly, the TP1 pile with grouting will be simulated, 
because it is most similar to the actual observation. After 
obtaining its results (note that the load level is gradually 
adjusted until failure) the parameters change. Pile TP1 becomes 
a non-grouted pile, and also from that model, the set of 
parameters change in order to simulate the models 3 and 4 (the 
grouting length from -26.3m to -48.5m and -48.5m to -65.5m 
respectively). The obtained results are used to draw the 
relationship graph of the curve and the load of the four 
investigated models. We convert the test load of the Osterberg 
method into the conventional static test load using an 
equivalent method, from which we have enough basis to 
evaluate the increase in the load capacity of the TP1 pile 
according to the four different models. 

 

 
Fig. 2.  Movement and load curves obtained from actual and simulated 

observations. 

The O-cell upper displacement is 7.44mm/9.82mm on site. 
The O-cell lower displacement is -10.08mm/-6.27mm on site. 
The total strain of the O-cell is 17.52/16.09mm. This result 
from Figure 2 shows that the measured results and the finite 
element modeling have high accuracy. However, in terms of 
displacement between the upper and lower O-cells, there is an 
inversion. The field displacement value is smaller than that of 
the Plaxis model, i.e. 7.44/9.82mm. It should be noted that the 
lateral friction is enhanced due to the better grouting ability 
(regarding the safety issue). For the lower O-cell, in fact, the tip 
resistance has not been applied to the load-carrying capacity of 
the pile, so the actual displacement is larger than that of the 
Plaxis model -10.08/-6.27mm). 

IV. DISSCUSION 

This analytical model is rather similar to the investigated 
field, so the authors take this set of soil parameters to continue 
to simulate the remaining models with the condition of 



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increasing load until the failure of the pile. The results of 
models 1-4 are displayed in Figures 3-6. 

 

 
Fig. 3.  Model 1. The TP1 pile with grout reaches 305% of maximum load. 

 
Fig. 4.  Model 2. The TP1 pile without grout reaches 255% of maximum 

load. 

 
Fig. 5.  Model 3. The TP1 pile with grout from -26.3m to -48.5m reaches 
280% of maximum load. 

 
Fig. 6.  Model 4. The TP1 with grout from -48.5m to -65.5m reaches 280% 

of maximum load 

The ultimate load capacity is determined based on the shape 
of the load-displacement relationship curve: 

S = f(P), logS = f(logP)    (1) 

In many cases, it is necessary to combine with other curves 
like: 

S = f(logt), P = f(S/logt)    (2) 

With the load-displacement relationship curve, the ultimate 
load-carrying capacity is determined as follows: 

• Case 1: the P-S relationship curve has a clear bending point. 
The ultimate load-carrying capacity is determined directly 
on the curve, the load corresponding to the point where the 
curve begins to change suddenly or the curve is closely 
parallel to the displacement axis. 

• Case 2: the P-S relationship curve changes slowly. It is 
quite difficult or impossible to accurately determine the 
bending point. The ultimate load-carrying capacity is 
determined by different graphical methods. 

The analysis and evaluation of the test results by the 
Osterberg method are still based on the principles of 
conventional static testing, in which the Q-S relationship curve 
is an important tool of the quantitative analysis of the load-
carrying capacity of the piles that a mechanical problem 
usually covers. The goal of load testing in most cases is not 
only to determine the bearing capacity of the pile foundation, 
but also to get a more specific view than the one from the 
general theory and the calculated results about the interaction 
between the pile and the composing ground so that we can 
offer more appropriate behaviors in the design of the pile 
foundation and in the future construction processing. We can 
build a load-settlement curve (similar to a conventional static 
compression test curve) in the following way: 

At any displacement S, the downward force affecting the 
soil is: 

Q’↓ = Q↓ + w2’    (3) 

where Q↓ is the downward force by the O-cell at the 
displacement S and w2 is the self-load of the pile from the O-
cell downwards (buoyancy must be taken into account if we are 
below the groundwater level). 

At the same displacement S, the upward force carried by 
the soil is: 

Q’↓ = (Q↓ - w1’) × F    (4) 

where w1’ is the self-load of the pile from the O-cell upwards 
(buoyancy must be taken into account if we are below the 
groundwater level) and F is the coefficient that takes into 
account the difference in the lateral friction between the normal 
static compression and the Osterberg compression. With  
F = 1.00 for the pile in the rock and F = 0.95 for the pile in the 
loose soil. 

At the displacement S, the sum of the upward and 
downward forces will be subjected by the soil: 

P = Q’↓ + Q’↓ = Q↓ + w2’ + (Q↓ - w1’) × F    (5) 



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However, in the case of downward compression, the soil is 
already partially imposed by the self-load of the pile, so the 
applied load at the top of the pile is: 

Pe = P – w1’ – w2’ = Q↓ + (Q↓ - w1’) × F – w1’    (6) 

At a load of Pe (loading downwards), the settlement of the 
pile is S + ∆δ where the increment ∆δ refers to the elastic 
compressive strain of the pile. 

Repeating the above steps with different positions S, we 
can draw a static compression curve corresponding to the data 
pair (Pe, S + ∆δ). If at a certain position that goes beyond the 
range of a curve (for example, the lateral resistance curve of the 
pile segment on the jack), we choose one of the following two 
solutions: 

• Take the upward force as constant (regarded as the extreme 
value) and equal to the tested maximum lateral resistance. 

• Extrapolating the next segment of the lateral resistance 
curve. However, this extrapolation has errors, because if the 
pile body is very rough (convex), then the lateral resistance 
reaches its ultimate value more slowly. Conversely, the less 
convex and concave the pile body is, the faster the lateral 
resistance reaches its ultimate value.  

 

 
Fig. 7.  Load capacity of the pile in the models 2 and 4. 

 
Fig. 8.  Load capacity of the pile in the models 1 and 3. 

From the above analysis, we will convert equivalently the 
test results of the Osterberg method into those of the 
conventional test method to plot the P-S relationship curve 
from the data pair (Pe, S +∆δ) and then use the graphical 
method to determine the load capacity. The results of the shape 
of the load-displacement relationship curve are displayed in 
Figures 7-9. 

 

 
Fig. 9.  Summary of the pile load-carrying capacity of the 4 models. 

V. CONCLUSION 

Through the experimental study from the O-cells of the TP1 
pile in the Eximbank building on the ability to improve the 
load-carrying capacity of the lateral walls, the following 
conclusions can be drawn: 

• Improvement of the bearing capacity of the pile by the 
lateral grouting method is highly effective with results of 
61.7MN and 41.8MN with and without grout respectively. 
The friction performance of the pile body with grouting 
increases by 1.48 times. It is different from the previous 
studies that we compared the analytical equations and the 
field results. 

• Grouting of each segment at depths of 22.2m (from  
-26.3m to -48.5m) and 16.8m (from -48.5m to -65.3m) 
corresponding to the maximum load of 59.2MN and 
59.4MN is evaluated as being similar to the load-carrying 
capacity. The FEM simulation results show that the bigger 
grouting length and the bigger grouting depth will give 
higher values of bearing capacity. Simulating grouting in 
each segment is very beneficial for the design of allowable 
loads, both in terms of safety and cost aspects. 

• The FEM (Plaxis) can simulate and evaluate the O-cell and 
the lateral grouting tests of piles. This method can be used 
for computational correction after the field results are 
available for detailed design. 

ACKNOWLEDGMENT 

The current research is supported by the Ho Chi Minh City 
Open University (Project No. E2019.08.3). 

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