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ETASR - Engineering, Technology & Applied Science Research Vol. 3, No. 6, 2013, 562-565 562  
  

www.etasr.com Abbad et al.: Interaction of Rupture Zones of Adjacent Anchor Plates in an Analogical Medium 
 

Interaction of Rupture Zones of Adjacent Anchor 
Plates in an Analogical Medium 

Hichem Abbad          
Djillali Liabes university       
Dept. Civil Engineering, 

Fac.Technology    Labo. Civil 
Engineering & Environment -

LGCE                      
Sidi Bel Abbes, Algeria   

hi_abbad@yahoo.fr 

Mourad Meghachou 
Djillali Liabes University 

Dept. Civil Engineering, 
Fac.Technology Labo. 
Civil Engineering & 
Environment -LGCE         

Sidi Bel Abbes, Algeria 
mourad_meghachou@univ-

sba.dz 

Chahinez Dekar      
 Djillali Liabes University 
Dept. Civil Engineering, 

Fac.Technology Labo. 
Civil Engineering & 
Environment -LGCE         

Sidi Bel Abbes, Algeria 
ch_gecicat@yahoo.fr 

Sidi Mohamed Daoud 
Djillali Liabes University 

Dept. Civil Engineering, 
Fac.Technology Labo. 
Civil Engineering & 
Environment -LGCE               
Sidi Bel Abbes, Algeria 
daoudmed22@yahoo.fr 

 
Abstract — In this paper, an experimental study which required 
the design and implementation of a model containing plastic 
granules powder to simulate a natural environment, is presented. 
The latter is subjected to the removal of anchor plates. For each 
test, several digital photographs are taken to materialize different 
deformed configurations during the pullout process. These 
photos processed in couples by the 7D software (image 
correlation) giving the evolution of the displacement field and 
plane strain analogical environment. Particular attention is paid 
to the discussion of the interference of rupture zones of 
neighboring anchors by reducing the axis between plates. 

Keywords- correlation of images; small-scale model; anchor 
plates; granular medium; shear; plane problem.  

I. INTRODUCTION 

The anchor plates are light structural elements employed to 
withstand uplift forces as experienced by transmission towers, 
masts and structures subject to buoyancy effects as offshore 
stations. Theoretical studies and experimental models of 
reduced contiguous plates embedded in granular soil [1-5] 
showed the influence of soil anchor, of the geometry of the 
plates, of the depth of the anchor and of the distance between 
two adjacent plates in their behavior. 

What actually happens in the environment of two adjacent 
anchor plates however, is always instructive. Kinematic 
analysis, through physical modeling, allows the investigation of 
actual behavior. For example, ask the following question: what 
happens in a medium surrounding two contiguous anchor 
plates positioned at different distances from each other? It 
would be interesting to analyze the interaction of the deformed 
plates around these areas. In this paper, we present an 
experimental study that describes the displacement field and 
the strain field in a medium subjected to the removal of two 
adjacent plates, answering the first question. The use of an 
analogical environment in this kind of modeling provides an 
approach to the understanding of the phenomenology of real 
soils, as both materials have certain properties in common such 
as incompressibility grain and rubbing character. 

II. EXPERIMENTAL MODEL 

The model on which we have carried out the tests, is a 
rectangular device of 100x80x5 cm dimension, designed to 
contain plastic granules (analogical material) simulating a 
granular medium. The front wall of the model is made of a 
glass plate 6 mm thick, with a constant refractive index 
throughout its surface. The other walls are formed by plates 
rigid with wood. Wooden smoothed  parallelepipeds of 5x5x2 
cm dimensions model the anchor plates. They are in contact 
with threaded rods of 50 cm in length. Nuts are welded to an 
attachment to the chassis of the model, and the tearing of the 
two plates can be controlled by unscrewing the rods. A strictly 
vertical movement is imposed on the anchor plates as they are 
guided by 5 mm thick rails, mounted on the rear wall, 
preventing any rotation, as shown in Figure 1. 

The plastic grains average diameter is 1 mm, different 
colors (red, blue, yellow, green and black) are mixed to 
materialize a visually contrasting environment (natural 
speckle). To obtain a compact and homogeneous medium, the 
material is deposited uniformly over the entire width of the tray 
by small 2 cm thick layers. Each layer is compacted through a 
metallic rammer compaction equal to 2.5 kg mass by 
exercising 75 blows with a drop height of 30 cm. The medium 
has a void index of 0.321, corresponding to a relative density of  
Dr=96% (emin=0.302, emax=0.855), the unit weight of the dry 
analogical material is γd=14,6 kN/m

3, its cohesion is null and 
its natural friction angle it φ=39°. In view of the very low 
stresses involved, plastic grains constituting the studied areas 
are considered indeformable.  

To describe the displacement field and strain over the 
anchor plates, several series of tests were conducted. 
 For each test performed, a series of digital photos, with a 
resolution of 3200x2400 pixels, is taken from the front and 
with the axis of the shooting perpendicular to the plane of the 
model. These photos materialize different deformations in the 
granular medium, caused by the tearing of the anchor plates. 
The recorded images are further processed to determine the 
strain field using the 7D software. It is a method of correlation 
between two images [6]: they are compared using the 
correlation coefficient of the gray level. In other words, the 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, No. 6, 2013, 562-565 563  
  

www.etasr.com Abbad et al.: Interaction of Rupture Zones of Adjacent Anchor Plates in an Analogical Medium 
 

points of the original image are found on successive images 
with a measurement uncertainty of about 0.1 pixel, or 0.01 
pixel in small deformation. The image for which the strain is 
analyzed is divided into a number of square grid elements of 
20x20 pixels. 

 
 
 









Fig. 1.  View of the model 

III. DISPLACEMENTS AND DEFORMATIONS OVER THE 
ANCHOR PLATES 

 Highlighting the influence of the distance between the 
centers of adjacent anchor plates on the behavior of the 
surrounding granular medium is deliberately kinematics, 
ignoring any measurement of the stress state. The tests in 
question were conducted for anchored at a depth of H=5B, 
where B is the width of the plates. The spacing axes distance S 
varied as follows: S=3B, S=4B, S=5B and S=7B. During image 
processing, a field of study is defined by the operator. We will 
follow in the evolution of displacements and deformations in 
this area. The tearing or lifting imposed on the anchor plates, 
occurs at constant pitches in the order of 0.266 mm that 
correspond to 1 pixel. 

A. Displacement field 

Figure 2 reproduces graphically the trajectories of grains for 
a tearing of 20 pixels and for a distance between the axes of 
respective anchor plates of 3B, 4B, 5B and 7B. Note that the 
grain movement is growing vertically along the axis of the 
plate, and horizontally to the edges of it. The displacement 
vectors are plotted with an amplification coefficient of 7 
(700%). First, we find that the displacement vectors are 
generally vertical and oriented upwards, the trajectories of 
grains damp, almost, approaching a horizontal plane parallel to 
the free surface of the massif, following an upwardly curved 
arc. 

 

 

 

 

 

Fig. 2.  Displacement vectors for a pullout of 20 pixels and for different 
distances between axes of plates. 

 

(a) S = 3B, 20 pixels 

(b) S = 4B, 20 pixels 

(c) S = 5B, 20 pixels 

(d) S = 7B, 20 pixels 

granular medium consisting of 
plastic granules 

Guide rails 
glass plate 

threaded rod 

Anchor plate Wood 

Chassis 

B=5cm 

S 
H = 5B 

100 cm 

80cm 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, No. 6, 2013, 562-565 564  
  

www.etasr.com Abbad et al.: Interaction of Rupture Zones of Adjacent Anchor Plates in an Analogical Medium 
 

Figure 3 represents the vertical displacement fields of the 
material applied by two anchorage plates with a space between  
axes respectively of 3B, 4B, 5B and 7B. Tear is 20 pixels. 
Locally over each plate, the medium behaves in a manner 
similar to an isolated plate. Note that the formation of a "rigid 
wedge" over each plate confirms the high compactness of the 
material. According to the tear's intensity of the plates, a large 
displacement gradient is set up on a slightly curved triangular 
outline confirming the existence of the rigid wedge above the 
plates. 

We note that beyond the distance of S=7B, plates act 
independently on the material. At the distance of S=3B, the 
interaction of rupture zones of each plate creates a bulb of 
vertical displacement which reaches the value of 2.76 pixels at 
the surface of the massif at midway between the axes of the 
plates. The bulge of the grains is limited by inclined lines 
passing by the edges of the plates. The inclination of these 
lines is about 41° relative to the vertical. This inclination is 
substantially equal to the internal angle of friction of an 
analogical soil (φ=39°). These lines materialized slip lines 
(rupture surfaces). This mode of rupture has been observed by 
several researchers who have studied the phenomenon of 
interaction of anchor plates in granular soils  [8, 9]. 

B. Deformation field (maximum shear) 

Figure 4 reproduces the strain fields (maximum shear) in 
the granular medium for a plate uplift of 20 pixels and for a 
spacing  between axes of  3B, 4B, 5B and 7B. It is noticed that 
the shear (bulb shear) at the surface of the massif, midway the 
plates axes is larger when the plates move towards each other. 
The shear intensity reaches the value of 1.02% for a spacing of 
3B whereas it does not exceed 0.23% for a spacing of 5B and 
0.12% for a spacing of 7B. Note the edge effect at the corners 
of bases of the upper faces of the plates. 

IV. CONCLUSION 

The experimental study we conducted was based mainly on 
the evolution of the granular medium subjected to the pullout 
of anchor plates. The pullout tests performed were used to 
quantify the vertical displacement field and the deformations of 
granular medium over "anchor plates" with the image 
correlation technique. The choice of a pullout of 20 pixels 
(imposed displacement) is justified by the need to present strain 
fields corresponding to a state of failure. A multitude of 
coupled photos were processed, up to a pullout of 35 pixels and 
more. Beyond 18 pixels, the deformed configuration is virtually 
unchanged, which shows that at this stage of sollicitation, the 
medium has reached a state of rupture and plasticity state 
occurs. The interaction of rupture zones of neighboring plates 
anchored at a depth of 5B is studied kinetically by varying the 
distance between the axes of the plates. It appears that a 
minimum distance between axes of approximately seven times 
the width of the plate (7B) is needed for the two adjacent 
anchoring plates to act independently on the medium. The 
formation of a "rigid wedge" on the top of each plate was 
demonstrated. The failure mode observed during the pullout 
process is in agreement with the previous results.  

 

 

Fig. 3.  Vertical displacement field for a pullout of 20 pixels and for 
different distances  between axes of plates. 

(a) S = 3B, 20 pixels 

(b) S = 4B, 20 pixels 

(c) S = 5B, 20 pixels 

(d) S = 7B, 20 pixels 



ETASR - Engineering, Technology & Applied Science Research Vol. 3, No. 6, 2013, 562-565 565  
  

www.etasr.com Abbad et al.: Interaction of Rupture Zones of Adjacent Anchor Plates in an Analogical Medium 
 

 

 

Fig. 4.  Deformation field (maximum shear) for a pullout of 20 pixels and 
different distances between axes of plates.  

 

REFERENCES 
[1] G. G. Meyerhof, J. I. ADAMS, “ The ultimate uplift capacity of 

foundations“, Canadian Geotechnical Journal, Vol. 5, No. 4, pp. 225-
244, 1968 

[2] E. J. Murray, J. D. Geddes, “Uplift of anchor plates in sand“, Journal 
of Geotechnical Engineering, Vol. 113, No. 3, pp. 202–215, 1987 

[3] T. H. Hanna, R. Sparks, M. Yilmaz, “Anchor behavior in sand“, Journal 
of the Soil Mechanics and Foundations Division, Vol. 98, No. 11, pp. 
1187-1208, 1972 

[4] J. D. Geddes, E. J. Murray, “Plate anchor groups pulled vertically in 
sand“, Journal of Geotechnical Engineering, Vol. 122, No. 7, pp. 509-
524, 1996 

[5] K. Kouzer, J. Kumar, “Vertical uplift capacity of equally spaced 
horizontal strip anchors in sand“, International Journal of Geomechanics, 
Vol.9, No. 5, pp. 230-236, 2009. 

[6] P. Vacher, S. Dumoulin, F. Morestin, S. Mguil-Touchal, “Bidimensional 
strain measurement using digital images“, Proceedings of the Institution 
of Mechanical Engineers, Part C: Journal of Mechanical Engineering 
Science, Vol. 213, No. 8, pp. 811-817, 1999 

[7] H. Abbad, M. Meghachou, P. Vacher, “Interaction of subjacent zones 
due to contiguous shallow foundations in analogical medium”, European 
Journal of Environmental and Civil Engineering, Vol.15,No. 3, pp. 391-
409, 2011. 

[8] K. M. Kouzer, J. Kumar, “Vertical uplift capacity of two interfering 
horizontal anchors in sand using an upper bound limit analysis”, 
Computers and Geotechnics, Vol. 36, No. 6, pp. 1084-1089, 2009 

[9] J. Kumar, K. M. Kouzer, “Vertical uplift capacity of a group of shallow 
horizontal anchors in sand “, Géotechnique, Vol. 58, No.  10, pp. 821-
823, 2008 

(a) S = 3B, 20 pixels 

(c) S = 5B, 20 pixels 

(d) S = 7B, 20 pixels 

(b) S = 4B, 20 pixels