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Engineering, Technology & Applied Science Research Vol. 13, No. 1, 2023, 10165-10169 10165  
 

www.etasr.com Helis et al.: Behavior of a Circular Footing resting on Sand Reinforced with Geogrid and Grid-Anchor 

 

Behavior of a Circular Footing resting on Sand 
Reinforced with Geogrid and Grid Anchors 

 

Rima Helis 

LGC-ROI Civil Engineering Laboratory, Department of Civil Engineering, Faculty of Technology, 
University of Batna 2, Algeria 
helis.r@univ-setif.dz 
(corresponding author) 
 

Tarek Mansouri 

LGC-ROI Civil Engineering Laboratory, Department of Civil Engineering, Faculty of Technology, 
University of Batna 2, Algeria 
t.mansouri@univ-batna2.dz 
 

Khelifa Abbeche 

LGC-ROI Civil Engineering Laboratory, Department of Civil Engineering, Faculty of Technology, 
University of Batna 2, Algeria 
k.abbeche@univ-batna2.dz 
 

Received: 23 December 2022 | Revised: 3 January 2023 | Accepted: 7 January 2023 

 

ABSTRACT 

This study used finite element analysis to investigate the influence of using two reinforcing systems, the 

geogrid and the grid anchor, on the bearing capacity of a circular footing resting on sand. The parameters 

studied were the effect of the number of reinforcement layers (N), the depth ratio of the topmost layer of 

reinforcement (u/d), the vertical spacing ratio between consecutive layers (h/d), and the effect of 

reinforcement length (L). The results showed that the reinforcement layout had a very significant effect on 

the behavior of the reinforced sand foundation. The maximum bearing capacity for single-layer inclusion 

was obtained when reinforcement was placed at a depth of u/d=0.42. Bearing capacity was also found to 

improve when increasing the number of reinforcement layers from 1 to 3. Additionally, the analysis 

showed that the sand reinforced by grid anchors performed better than that reinforced by geogrid. Finally, 

an improvement in load capacity was obtained by increasing the length of the inclusions, and the optimal 

length of the reinforcements was determined at 5d for both inclusions. 

Keywords-geogid; grid anchor; finite element analysis; circular footing; sand 

I. INTRODUCTION  

Geosynthetic reinforcing techniques is used to reinforce 
shallow foundations, improve bearing capacity, and reduce soil 
settlement below the foundation. Several studies investigated 
the bearing capacity of geosynthetic reinforced foundation soils 
using experimental, analytical, and numerical methods. One of 
the first experimental studies to analyze the bearing capacity of 
reinforced soils with metal strips was presented in [1-2]. Since 
then, many studies investigated the improvement of the load-
bearing capacity of shallow foundations supported by sand and 
reinforced with different materials, such as metal strips and 
metal bars [3-5], rope fibers [6], geotextile [7], and geocells [8-
10]. In addition, considerable studies were conducted to 
evaluate the bearing capacity of the reinforced soil by geogrid 
[11-18]. These studies confirmed the beneficial effect of 
reinforcement on improving the bearing capacity and reducing 

the settlement of footing. More recently, the use of geogrid in 
geotechnical engineering applications was considerably 
increased due to advantages such as cost reduction, simplicity, 
and ease of construction [19-20]. Laboratory scale model tests 
on a circular embedded footing supported on geogrid-
reinforced sand beds were presented in [21], reporting an 
increase in ultimate bearing capacity with the embedding depth 
ratio of the foundation. In [22], the behavior of circular footing 
on sand was studied, showing that bearing capacity increased 
when the number of reinforcement layers increased if the 
reinforcements were placed within a range of effective depths. 
This study also showed that increasing the stiffness of the 
reinforcement did not always have a better effect on bearing 
capacity. A numerical study was conducted in [23] using finite 
element analysis to investigate the behavior of circular footing 
resting over reinforced sand, showing that the depth of the top 
layer plays an important role in the behavior of the reinforced 



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soil, and reporting that the optimum depth of the top layer was 
0.19 times the diameter of the footing. In [24], a small-scale 
laboratory model test was carried out on two closely spaced 
interfering footings resting on the surface of unreinforced and 
geogrid-reinforced sand bed, finding that the optimal depth of 
the geogrid layer for both interfering and isolated footings was 
one-third of the footing width. Therefore, footing interference 
had negligible or no effect on the optimum depth of the 
reinforcement layer for a single-layered reinforced sand bed. In 
[25], resting on a semi-infinite layer of reinforced sand with 
geotextiles was used to experimentally study the behavior of 
circular footings. Furthermore, analytical and numerical 
analyses were carried out to predict load-settlement behavior 
and compare them with the experimental observations. In [26], 
model plate load tests were conducted on various types of sand 
beds reinforced with geogrid, showing that substantial 
improvement in the load-settlement behavior can be obtained 
by increasing the number of geogrid layers (N) and decreasing 
the spacing between them. It was also shown that the load 
improvement ratio for the reinforced coarse sand was higher 
than that of the reinforced fine and medium sand. In [27], the 
behavior of geosynthetic-reinforced sandy soil foundations was 
investigated using laboratory model tests, showing that the 
settlement can be reduced by 20% at all footing pressure levels 
with two or more layers of geogrid. In [28], the upper bound 
theorem of limit analysis was used in conjunction with finite 
elements and linear optimization to determine the bearing 
capacity of a circular foundation embedded with horizontal 
layers of circular geogrid sheets. The optimal diameter and the 
critical positions of the reinforcement layers were established 
to achieve maximum bearing capacity, and a marked 
improvement in the bearing capacity was evident in the case of 
using two layers of reinforcement rather than a single. A 
laboratory model test of a surface strip footing on reinforced 
sand beds was presented in [29] to investigate the effects of 
reinforcement length with various types and numbers of 
reinforcements. An experimental study was conducted in [30] 
to assess the influence of the geogrid extension and embedment 
depth below strip footing rested on fine loose sand. In [31], a 
regression model was developed to determine the bearing 
capacity of a circular foundation supported on sand reinforced 
with geogrid. The results showed that the parameters studied 
had a significant influence on the performance of the footing in 
terms of bearing capacity. In [32-33], the bearing capacity of a 
strip footing subjected to inclined load and resting over a 
geogrid-reinforced sand bed was studied experimentally and 
numerically, showing that the footing performance could be 
substantially improved by including layers of geogrid, leading 
to an economic design of the footing. The effects of load 
eccentricity and inclination on the ultimate bearing capacity of 
shallow rectangular foundations placed over geogrid sand were 
studied in [34], finding that multiple geogrid-reinforced layers 
increased the ultimate bearing capacity by 75%. In [35], a strip 
foundation in weak soil was replaced with a granular trench 
and reinforced with geogrid, showing that the bearing capacity 
of a strip foundation could be significantly improved by 
replacing sand with granular materials up to 3 times. In 
addition, it was shown that placing the geogrid in the trench 
indicated a rise in the bearing capacity ratio. A new generation 
of reinforcement named grid-anchor was introduced in [36-37], 

showing its effect on the increase of bearing capacity of the 
foundation. 

This study aims to evaluate the performance of using 
ordinary geogrid and grid anchor reinforcement in increasing 
the bearing capacity and reducing the settlement. To achieve 
this objective, a numerical model was determined using the 
Plaxis finite element software to investigate the bearing 
capacity of a circular footing resting over reinforced sand. 
Different parameters that affect the behavior of the 
reinforcement sand layer are discussed. 

II. FINITE ELEMENT MODELING 

The Plaxis software was utilized to perform a numerical 
finite element analysis by simulating a circular footing resting 
on sand reinforced by two reinforcement systems, GeoGrid 
(GG) and Grid Anchors (GA). Also, an axisymmetric analysis 
was performed. For all models, the boundary conditions in 
displacements were similar, such that the bottom boundary was 
assumed to be fixed and the vertical boundaries were 
constrained in motion in the horizontal direction. However, 
sand's behavior was supposed to be elastic and perfectly 
plastic, the Mohr-Coulomb rupture criterion was used, and the 
nonassociated flow rule was considered. A rigid circular 
footing with a 12cm diameter was simulated by applying a 
uniform downward displacement on the surface of the sandy 
soil. Table I shows the properties of the sand adopted in the 
model. Fifteen triangular plane strain elements were selected to 
model the soil, while the GG reinforcement was simulated with 
5 node elastic elements. The GA was modeled using the fixed-
end anchor option. Table II shows the physical and mechanical 
properties of GG and GA. The mesh refinement was adopted in 
the vicinity of the loading area around the foundation and GG 
layers to improve the accuracy of the numerical results. 

TABLE I.  SOIL PARAMETERS 

Physical and Mechanical Property Value 

Maximum unit weight (kN/m
3
) 16.4 

Minimum unit weight (kN/m
3
) 14.4 

Maximum void ratio 0.890 

Minimum void ratio 0.658 

Specific gravity 2.72 

Coefficient of uniformity 2.36 

Coefficient of curvature 1.01 

Classification SP 

Cohesion (kN/m
2
) 0 

Internal friction angle 39˚ 

TABLE II.  PHYSICAL AND MECHANICAL PROPERTIES OF 
GEOGRID AND ANCHORS 

Description Geogrid CE 131 

Polymer High-density polyethylene 

Form Sheet 

Color Black 

Mesh aperture size 27×27mm 

Mesh thickness 5.2mm 

Structural weight (+5%) 660g/m
2
 

Elastic normal stiffness of geogrid 28.0KN/m 

EA axial stiffness of anchors 0.18KN 

Length of anchors (mm) 50mm 



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Figure 1 shows the prototype soil model with two systems 
of reinforcement, finite element mesh, and boundary 
conditions. 

 

 
Fig. 1.  The numerical model. 

III. RESULTS AND DISCUSSION  

Numerical tests were carried out to study the effects of 
inclusion reinforcement elements on a circular footing, 
constructed on unreinforced and multi-layered reinforced sand 
beds, and investigate the improvement of bearing capacity. A 
non-dimensional factor called the Bearing Capacity Ratio 
(BCR) was considered, defined as the ratio of the reinforced 
soil bearing capacity to the unreinforced soil: 

BCR=
��

��
     (1) 

where qR and qU are the bearing capacity values for reinforced 
and unreinforced soil foundations, respectively. 

A. Effect of Reinforcement’s Top Spacing 

A numerical study was carried out to investigate the effect 
of the depth of the first reinforcing layer from the footing on 
the bearing capacity for different depth ratio values (u/d) with a 
single reinforcement layer in each reinforcing system, GG and 
GA. Figure 2 shows the variation of the BCR of the soil versus 
the different reinforcement depth ratios u/d. In the case of GG, 
as the depth ratio u/d increases from 0.2 to 0.42, the BCR also 
increases. However, between 0.42 and 0.8, a clear reduction in 
the BCR was found for both GG and GA.  

 

 
Fig. 2.  Variation of BCR with depth ratio in single-layer reinforced sand. 

Similar results were found in [31], where there is no 
increase in soil carrying capacity that exceeded u/d>0.75. 
Hence, the optimal value of the depth ratio was obtained when 
the reinforcement was placed at u/d equal to 0.42 in both 
systems. Therefore, it can be concluded that the results 
obtained for GG reinforcement are in good agreement with 
[38]. Figure 2 also shows that the effect of the presence of GA 
reinforcement on the bearing capacity of the circular footing on 
sand becomes important compared to those obtained by GG. In 
addition, a considerable improvement of about 52% was 
observed for the anchorage of the grids.  

B. Effect of Vertical Spacing of Reinforcement Layers 

This study aims to investigate the effect of the spacing 
between the reinforcing elements on the performance of 
reinforced sand under the circular footing. The GG and GA 
layers were tested with a top layer spacing at 0.42d and varied 
vertical spacing between the layers. Figure 3 shows the 
variation of the BCR with the vertical spacing ratio (h/B). The 
results showed that for GG reinforcement, the BCR increased 
to a maximum value at h/d=0.3d, but the GA had a critical 
value at u=0.42d. Then, a remarkable decrease was observed 
for both reinforcements until 0.6d. Beyond this value, BCR 
seems to stabilize, showing that adding inclusions is 
insignificant in this region. The trend of the curves is similar to 
that of [38]. Furthermore, in [28-31] it was shown that the 
increase in BCR was obtained when the vertical spacing 
between the reinforcement layers was between 0.25 and 0.40d, 
which justifies the present case study. Therefore, the variation 
in amplitudes and the modest divergence can be attributed to 
the adapted reinforcement pattern. 

 

 
Fig. 3.  Variation of BCR with the vertical spacing ratio of reinforced sand. 

C. Effect of the Number of Reinforcing Layers 

Α series of numerical tests were conducted to study the 
influence of the variation of the number of reinforcement 
elements (N) on the behavior of a circular footing on reinforced 
sand. The depth of the first layer (u) was taken equal to 0.42d, 
while the vertical distance between the reinforcement layers (h) 
was equal to 0.3d for the GG and 0.42d for the GA. Figure 4 
shows the variation of the BCR as a function of the number of 
reinforcement elements N. It can be observed that the increase 
in the BCR results from a considerable increase in the 
reinforcement elements up to an optimum value N=3, and a 
slight increase is observed over that. This confirms the findings 



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of several studies [22-34, 37] that showed that increasing the 
number of reinforcement layers beyond a certain number 
would not increase the BCR. 

 

 
Fig. 4.  Variation of BCR with the number of reinforcement layers. 

D. Effect of the Length of Reinforcement 

A circular foundation resting on sand was studied by 
keeping the number of geogrid layers N to 1 and depth of 
reinforcement at the optimal 0.42d, while the length of the 
reinforcement layer (L) varied between 4d, 4.5d, 5d, and 6d to 
investigate its effect on BCR. Figure 5 illustrates the variation 
of BCR with the different reinforcement length ratios (L/d).  

 

 
Fig. 5.  Variation of BCR with the reinforcement layer's length. 

As can be observed, BCR increases linearly with 
reinforcement length up to L/d=5, while reinforcement length 
beyond this value is ineffective on BCR for both reinforcement 
types. Therefore, the optimal length of reinforcement is 
obtained at 5 times the length of the footing, as in [39]. 

IV. CONCLUSION  

This study caused finite element analysis to assess the 
behavior of a circular footing constructed on unreinforced and 
reinforced sand soil, drawing the following conclusions: 

 An increase in bearing capacity was obtained when the 
depth of the first reinforcing layer to the footing diameter 

was equal to 0.42. This was considered an optimal depth of 
the top reinforcement layer from the bottom of the footing.  

 A visible reduction was noted in the bearing capacity 
beyond 0.42d for both types of reinforcement. 

 The effect of reinforcement cannot be seen when the 
installation depth is deeper than a certain depth (u/d≥0.80). 

 There is an optimal value for the vertical spacing of the 
reinforcement layer where the BCR was the highest. This 
optimal value was found to 0.3d for Geogrid and 0.42d for 
Grid Anchors. 

 The bearing capacity of reinforced soil increases with 
increasing the number of layers. In this study, the optimal 
number of layers obtained was 3 in both reinforcement 
types. 

 The analysis clearly showed that using the Grid Anchor 
system reinforcement of circular footing on a sand bed 
causes a significant increase in the bearing capacity in 
comparison with the ordinary Geogrid. 

 An improvement in the load capacity was obtained by 
increasing the length of the inclusions. The optimal length 
of the reinforcements was determined at 5d for both 
inclusions. 

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