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www.etasr.com Touahmia: Performance of Geosynthetic-Reinforced Soils Under Static and Cyclic Loading 
 

Performance of Geosynthetic-Reinforced Soils Under 
Static and Cyclic Loading  

 

Mabrouk Touahmia  
College of Engineering, Department of Civil Engineering 

University of Hail 
Hail, Saudi Arabia 

m.touahmia@uoh.edu.sa 
 

 

Abstract—This paper investigates and discusses the composite 
behavior of geosynthetic reinforced soil mass. It presents the 
results of a series of large-scale laboratory tests supported by 
analytical methods to examine the performance of geogrid 
reinforcement subjected to static and cyclic pullout loading. The 
testing equipment and procedures used for this investigation are 
outlined. The results show that geosynthetic reinforcement can 
mobilize great resistance to static pulling load under high 
confining pressures. The reinforcement exhibits gradual 
deformation under cyclic loading showing no sign of imminent 
pullout failure for all levels of applied loads. In general, the 
results demonstrate that geosynthetic can be used in situations 
where loads are non-static, although care will be required in 
ensuring that appropriate factors of safety are applied to control 
the resulting deformation. A simplified analytical model for 
calculating the pulling capacity of geosynthetic reinforcement is 
proposed. 

Keywords-geosynthetics; reinforced soil; geogrid; static 
loading; cyclic loading  

I. INTRODUCTION  
Geosynthetic-reinforced soil technology has become a 

significant part of civil and environmental engineering practice 
all over the world due to its numerous advantages such as, cost-
effectiveness, easy construction and time saving. It has proven 
to offer sustainable alternative solutions to many soft and 
unstable ground problems where the use of conventional 
construction techniques would be restricted or significantly 
expensive. Various types of geosynthetic products have found 
several aspects of earthwork applications such as in earth 
retaining structures, steep slopes, roadway embankments, 
railway tracks, load-bearing foundations, and subsurface 
drainage. The inclusion of geosynthetic reinforcement in soil 
mass improves the shear resistance of the soil due to the 
interlocking of the soil particles with the reinforcement 
apertures, thereby improving its structural capability. Under 
applied external load the reinforcement mobilizes resistance 
along its length according to the laws of bond and bearing. The 
transfer of stress between soils and various soil reinforcement 
systems involves two basic mechanisms: frictional resistance 
and/or passive resistance. A great deal of research has been 
undertaken to understand the interaction mechanisms and the 

operational behavior of the geosynthetic-soil composite 
material [1-3]. However, design methodologies used for 
geosynthetic reinforced soil systems have remained variable 
and sometimes confusing. Up to now, there are no uniform 
standards and specifications for reinforced soil systems, and in 
fact, there are different design criteria and procedures for each 
system. Most reinforced soil structures have been designed 
using limit equilibrium methods, which are generally 
considered to be very conservative [4-6]. These designs 
consider the peak strengths of the materials without regard to 
the strain compatibility between the two dissimilar materials 
and treat all types of loads as pseudo static loading [7]. To date, 
engineers are faced with many uncertainties regarding the 
selection of appropriate types of reinforcement and the 
evaluation of design parameters for these systems. 

Geosynthetic reinforced soil systems are frequently 
subjected not only to static loads but also to non-static loads 
such as repeated or cyclic loads. Such loading conditions can 
result from traffic loads on reinforced embankments and bridge 
abutments, pavements supported by reinforced soil retaining 
walls, reinforced earth structures subjected to significant tidal 
variations or to extremes temperature daily. The effect of cyclic 
loading on the interaction behavior of soil-geosynthetic 
systems has not yet been sufficiently addressed in research. It is 
considered however that the development of any reliable 
design methodology for geosynthetic reinforced soil systems 
will require a thorough understanding of the interaction 
mechanism and failure characteristics of the soil-geosynthetic 
composite material under different types of loading conditions.  

The main objective of this paper is to examine the pullout 
behavior of geogrid reinforcements under static and slow cyclic 
loading conditions. A large amount of laboratory test data has 
been generated in order to investigate the effects of various 
parameters on the interactive behavior of the composite 
material. The mechanics of load mobilization and 
reinforcement deformation under loading and unloading modes 
has been analyzed. 

II. EXPERIMENTAL INVESTIGATION 
The schematic diagram of the large-scale pullout apparatus 

used for the purpose of this experimental program is shown in 



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Figure 1. It consisted basically of a rigid soil container of inside 
dimensions 4.0m´0.3m´0.3m, a horizontal pullout loading 
system with the capacity to apply either static or slow cyclic 
loads to the reinforcement and a normal pressure setup.  

 

 
Fig. 1.  Pull-out test device. 

The static loading tests were carried out by adding dead 
weights to the load hanger situated at the rear end of the 
container and connected to the reinforcement. The cyclic loads 
were applied through lifting and releasing a moveable rider 
with weights on it by a reciprocating electrical motor. The 
repeated cycles of loading changed every 20 seconds between 
an upper and a lower load level to give a square-shaped pattern. 
The confining stress, which could be controlled from 0 to 300 
kN/m2, was applied to the top of the soil sample via a pressure 
plate loaded through a water bag. A data acquisition system 
was used to record the collected test results. The soil used in 
this investigation was a uniformly graded dry sand of medium 
size. The properties of the sand are given in Table I. 

TABLE I.  SOIL SAMPLE PROPERTIES 

Property Value 
Specific gravity 

Coefficient of uniformity 
Coefficient of curvature 

Maximum dry density (Mg/m3) 
Minimum dry density (Mg/m3) 

Maximum void ratio 
Minimum void ratio 

Friction angle 

2.67 
1.86 
0.84 
1.78 
1.42 
0.87 
0.49 
30.4 

 
The soil samples were prepared by raining method to a 

targeted relative density of 53%. To obtain a uniform density 
throughout the filling operation, the sand was poured into the 
pullout box from a constant height of 0.35 m and placed in 0.05 
m thick equal layers. The reinforcements used in this 
investigation were formed by cutting Tensar SR2 geogrid into a 
row of two ribs in width and 35 bars length (approximately 4 
m). Special axial movement gauges were provided at 5 
locations along the reinforcement to measure the axial strains 
with applied load. The test specimen was located at the mid-
height of the soil sample and connected to the loading levels 
system with a special clamp. The applied cyclic load levels 
were expressed as a percentage of the index load (PI = 3.25 
kN) of the geogrid, defined as the ultimate rupture load of an 
identical (4 bars x 2 ribs) geogrid element in air. 

III. STATIC LOAD TEST RESULT 
A series of static pullout tests were conducted to examine 

the load-deformation behavior of the geogrid reinforcement 
and assess its mode of failure under static loading. Four levels 
of normal stress namely 25, 50, 75 and 100 kPa were applied to 

the sand surface. The embedded geogrid was subjected to a 
series of  short-term incremental axial pullout loads of 0.196 
kN/5min. The collected data from the pullout tests includes the 
variation of the geogrid deformation with the applied load at 
the frontal end and along the reinforcement length. All tests 
were performed till the total pullout displacement of the 
geogrid reaches a maximum of 40 mm, which represents 1% of 
the reinforcement length. Figure 2 shows the pullout-
displacement relationships of the geogrid reinforcement under 
different confining stresses (σn). 

 

 
Fig. 2.  Load-displacement relationships of the geogrid. 

The general pattern of these relationships is characterized 
by a continuous increase in the geogrid movement with 
increase in applied loads showing no pullout failure from the 
beginning till the end of the test. No peak load could be 
observed with the system of loading used, and the relationship 
between load and deformation became linear at larger 
displacements. The surcharge pressure was found to have a 
great effect on the deformation of the geogrid. As shown, the 
reinforcement mobilized greater resistance to pulling loads 
when the surcharge pressure increased and that is clearly 
visible under the high loading increments. This resistance to 
pullout of the reinforcement is offered by two main 
components, the frictional resistance provided mainly by the 
longitudinal members of the geogrid, and the passive-bearing 
resistance provided by the transverse members of the geogrid. 

The recorded movements along the length of the geogrid 
reinforcement for different applied pullout loads are given in 
Figure 3. As shown, the total deformation of the reinforcement 
consists only of an extension of the front part of the 
reinforcement and neither slip nor extension along the rear 
segment of the geogrid length was observed. This means that 
the applied load was mobilized over the front part of the strip 
only, the parts towards the distal end being unstrained. The 
magnitude of deformation along the geogrid is highly 
dependent on the applied confining pressure, with higher 
surcharge pressures resulting in very small or no load being 
transmitted to the rear part of reinforcement. This observation 
would indicate that unless a very low confining stress be used it 
would be impossible to pull out the geogrid reinforcement. 
Consequently failure of the geogrid by rupture appears to be an 
easier mode. 



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Fig. 3.  Axial deformation along the geogrid. 

IV. CYCLIC LOAD TEST RESULT 
A large amount of cyclic loading tests has been performed 

in order to  obtain a better understanding of the effect of cyclic 
loading on the pullout behavior of geosynthetic soil 
reinforcements. A wide range of loading levels and amplitudes 
was chosen to examine the pullout behavior and the failure 
pattern of the geogrid under such loading condition. In some 
cases the tests were taken to 100000 load cycles while the 
confining pressure was kept constant at 100 kPa for 
comparison purpose. The cumulative movement of the 
reinforcement versus the number of loading cycles is presented 
in Figure 4. 

 

 
Fig. 4.  Displacement-log number of load cycles relationships. 

As shown, the general behavior of the reinforcement was 
characterized by a continual increase in displacements with ian 
ncrease in loading cycles from the starting till the end of the 
test. Despite the large number of load repetitions none of the 
tested strips failed by pulling out. All the geogrid 
reinforcements were gradually pulling through the soil, as the 
number of load cycles increased, showing no sign of absolute 
failure. 

The gradual deterioration of the geogrid performance can 
be attributed primarily to the bearing resistance developed by 
the bars of the grid which acted as a series of anchors and, 
secondly, to the high extensibility characteristic of the geogrid 
material. It can be noted that the behavior of the geogrid 
reinforcement was highly dependent upon the magnitude of the 

cyclic load, with higher amplitude causing a rapid deterioration 
of the reinforcement performance. The life span of the geogrid 
was prolonged from 400 cycles to a nearly 10000 cycles by a 
reduction in the load amplitude  from 50% PI to 35% PI and 
the reinforcement sustained more than 105 cycles when it was 
subjected to a loading amplitude of 25% PI. With further 
lowering of the loading amplitude to 10% PI, the geogrid 
remained stable for over 105 cycles showing a nearly linear 
relationship between the reinforcement frontal displacement 
and the log number of load cycles. 

For further examination of the geogrid failure mechanism, 
the rate of movement per cycle is plotted against the number of 
load cycles on log-log scale. As shown in Figure 5, all the 
curves showed a similar trend which is characterized by a 
linear relationship of a decreasing rate of movement with 
increasing number of load cycles from the beginning till the 
end of the testing period. Such behavior indicates no sign of 
imminent pullout failure despite the large number of load 
cycles and the large amount of displacement. 

 

 
Fig. 5.  Rate of displacement-log number of load cycles relationships. 

The effect of the loading condition is further clarified in 
these diagrams, where different load levels gave different 
straight lines. An interesting feature is that the slopes of all 
plots are predominantly the same which indicate that the 
relationship is essentially independent of the stress level, and 
increases in stress serve only to shift the line vertically 
upwards. Based on this series of constant lines the frontal 
deformation δΝof the geogrid reinforcement at N number of 
load cycles can be expressed as: 

( )1 log
(1)i p

s N

N
e

d
d

é ù+ +ê úë û=  
where δi is the deformation after one cycle and  sp is  the slop of 
the deformation-number of cycles relationship. 

The total deformation at any section along the geogrid and 
its variation with load reversals is shown in Figure 6. These 
movements were expected to comprise two components as the 
number of cycles increases, the slip movement of the 
reinforcement together with the extension of the geogrid 
material. However, as can be seen, the total deformation 
consists only of an extension of the front segments and neither 
slip nor extension along the distal end of the reinforcement was 



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observed even at the highest loading level 0.5 PI. This 
observation would indicate that no load was transmitted to the 
lattermost half of the reinforcement which remained unstressed 
during all the cyclic loading tests. 

 

 
Fig. 6.  Change in axial strain with number of load cycles. 

It can be noted that the load was mobilized over the front 
part of the strip only, the parts towards the distal end being 
unstrained. This observation would indicate that unless a very 
low confining stress be used it would be impossible to pull out 
the geogrid. Consequently, failure of this reinforcement by 
rupture appears to be an easier mode. 

V. ANALYTICAL MODEL 
Due to geometrical and mechanical characteristics, geogrid 

can only carry tensile stresses through contact zone and 
anchorage members. Under applied external load the 
reinforcement mobilizes progressively resistance along its 
length according to the laws of band and bearing. Thus, the 
pullout resistance of the geogrid reinforcement would consist 
of two parts; (i) frictional resistance due to skin friction (Fa) 
and (ii) passive-bearing resistance against traverse members 
(Fb). The overall pullout capacity of the geogrid (Tmzx) can be 
computed as: 

ba FFT max  (2) 

The frictional resistance is offered mainly by the 
longitudinal members due to interfacial shearing between soil 
and the geogrid surface and can be expressed as:   

 dxxBF
L

ana 



0

2   (3) 

Where σn the applied normal pressure at the soil-reinforcement 
interface,  τα(x) the soil adhesion at the interface and B  and 
L are the reinforcement effective width and length.  

The passive-bearing resistance results from the interlocking 
of the soil at the geogrid apertures, which are normal to the 
pullout direction. The transverse members of a grid 
reinforcement can be considered analogous to a series of strip 
footings in succession which have been rotated through 90o to 
the horizontal and pulled through the soil. The maximum 
bearing stress can be calculated by invoking the theory of 

bearing capacity [8-9] which can be expressed in cohesionless 
soil as: 

































2
45tan

tan
2 




enF nb  (4) 

where n is the number of transverse members in the geogrid 
and   is the frictional angle for soil. The total pullout 
resistance can be then expressed in general form as: 

 
































 245tan2
tan

2

0

max







endxxBT n

L

an
 (5) 

The experimental results showed that as the reinforcement 
is loaded the resistance available at the soil-reinforcement 
interface is gradually mobilized along the reinforcement 
surface. This means that at an applied load T adhesion is 
mobilized over a part of the reinforcement length only, the 
remaining part remains unloaded. At some average adhesion 
the strength of the interface is mobilized and failure migrates 
along a distance x of the reinforcement length. Increase of T by 
dT causes an additional displacement d of the reinforcement. 
This incremental displacement maybe expressed by: 

x
E

dFdF
d ba


  (6) 

where adF  is the additional frictional load over the length x, 
dFb is the load taken by the bearing members, and E is a 
constant which depends on the reinforcement stiffness and 
properties. 

Putting ba kdFdF   and rearranging (5) gives: 

a
an

a dF
kEB

F
d 












1
1

2 
  (7)       

Integration of (6) yields the displacement of the geogrid 
reinforcement   as: 













kEB

F

an

a 11
4

2


   (8) 

The unloading of the reinforcement may be studied by 
incrementally adding a reverse or negative loads until the gross 
effect is that of zero external applied load. Thus, the mechanics 
of unloading are similar to those described for the loading case, 
except the adhesion resistance is no longer τα but τα mobilized 
in the reversed direction. This will cause a reverse 
displacement   u  of the reinforcement, which can be 
expressed by: 













kEB

F

an

u
u

1
1

4

2


   (9) 



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hence, the residual displacement r under zero applied load 
can be computed as: 



























a

u

a

a

n
ur

FF

kEB 


22
1

1
4

1
(10) 

On reloading the displacement may not equal to the original 
displacement which resulted on first loading unless the 
interface adhesion remains constant. This indicates that the act 
of subjecting a reinforcing element to a package of cyclic 
loading modifies the stress state along the reinforcement which 
leads to a progressive pullout of the reinforcement. 

VI. CONCLUSION 
This study investigated the composite behavior and 

performance of geosynthetic reinforced soil mass under static 
and cyclic loading. A series of pullout tests were conducted on 
geogrid embedded in a uniformly graded dry sand of medium 
density under different vertical confining pressures. The tests 
provide a better understanding of the interaction mechanism 
and failure mode of soil-geogrid composite systems that can be 
used for validation of analytical models. The findings 
demonstrate that geosynthetics have great potential to be used 
in situations where loads are non-static, although care will be 
required in ensuring that appropriate factors of safety are 
applied to control the resulting deformation. The study brings 
the following conclusions for geogrid reinforcement: 

• Under static loading the geogrid mobilizes greater resistance 
to pulling load under higher confining pressure. 

• Under cyclic loading the geogrid exhibits a gradual 
deformation showing no sign of imminent pullout failure for 
all levels of applied load. The accumulation of deformation 
increases with increase in the number of load repetitions and 
load amplitude.  

• The deformation of the geogrid consists of an extension of 
the front part of the reinforcement only and neither slip nor 
extension along the rear segment was observed.  

• Based on the test results analysis, a simplified analytical 
model for calculating the pulling capacity and deformation of 
geogrid reinforcements under loading and unloading 
conditions is proposed. 

ACKNOWLEDGMENT 

The research reported herein was funded by the Deanship 
of Scientific Research at the University of Hail, Saudi Arabia,  
under the contract (0150215). The author would like to extend 
his gratitude to the Deanship of Scientific Research and to the 
College of Engineering at the University of Hail for providing 
all facilitations required for this research. 

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