Microsoft Word - Paper 2.docx


 
The Journal of Engineering Research (TJER) Vol. 13, No. 1 (2016) 22-32 

Effect of Sediment Density on the Bed Topography in a 
Channel Bend Using Numerical Modeling 

 
M. Vaghefi*, a, Y. Safarpoor and S.S. Hashemi 

Civil Engineering Department, Persian Gulf University, Bushehr, Iran 
 

Received 25 February 2015; Accepted 13 August 2015 
 

Abstract:  In this paper, the bed topography of a channel at a 90-degree bend was studied at the T-shaped 
spur dike installed at the middle of the outer bank. Numerical analyses were performed with the Sediment 
Simulation in Intakes with Multiblock Option (SSIIM) model. Three relative curvatures (R/B = 2, 3, and 4) 
related to the three sediment densities (P = 2.35, 2.5, and 2.65) were modeled in nine cases and the effects of 
sediment density on the bed scour patterns were studied.  It was observed that the maximum amount of 
scour occurred near the head of the dike wing at the dike’s upstream, and the maximum amount of 
sedimentation occurred at the inner bank of the bend exit.  By increasing the sediment density when R/B = 4, 
the maximum scour and sedimentation decreased to 27.41% and 46.15%, respectively. When R/B = 3, the 
maximum scour and sedimentation decreased to 25.93% and 23.91%, respectively. When R/B = 2, the 
maximum scour and sedimentation decreased to 25.98% and 10%, respectively. 
 
Keywords: SSIIM model, T-shaped spur dike channel bend, Sediment density, Relative curvature. 

 

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אא :SSIIM،א،א،אKאאK  
 

* Corresponding author’s e-mail: Vaghefi@pgu.ac.ir  



M. Vaghefi, Y. Safarpoor and S.S. Hashemi 

 

23 

1. Introduction 
 
One of the methods employed for river training is 
the use of spur dike structures. Spur dikes divert the 
mainstream and protect river banks from erosion 
and have been studied for many years by 
researchers. Numerical model simulations are 
usually more cost-effective and faster than physical 
model studies and have no inherent limitations on 
spatial extent (Hua et al. 2006).  
     To study the curved channels, it is necessary to 
first check the flow pattern affected by cross-flow 
and secondary flow. Shukry (1949) presented an 
equation for calculating the power of secondary 
flow in channel bends. Nouh and Townsend (1979) 
determined that the secondary flow after leaving the 
bend not only is lost, but continues a straight 
distance downstream. Gill (1972), by changing the 
radius of curve, depth of flow and diameter of 
particles in the direct and bend channels showed 
that the distance between spur dikes is dependent 
on the radius of the curve. Da Silva and Yalin (1997) 
discussed the locations of the sediments and erosion 
holes in two mild and sharp meander bends. Lian et 
al. (1999) found that the secondary flow in a 180-
degree bend is stronger than that in a 90-degree one. 
The curvature of the flow in river bends leads to 
secondary flow normal to the main flow’s direction. 
In a river bend, a large secondary flow cell develops, 
covering most of the cross-section. Moreover, in 
river bends with steep outer banks, a much weaker 
second, counter rotating, secondary flow cell 
appears along the upper part of the outside river 
bank (Booij 2002). One of the consequences arising 
from the installation of a spur dike is the creation of 
scour around the spur dike bed which is caused by a 
change in the flow pattern of the channel.  Elawady 
et al. (2001) concluded that the scouring around a 
submerged spur dike is affected by the submergence 
and opening ratios of a channel. A greater opening 
ratio leads to a reduction in scour and the erosion of 
downstream banks rarely occurs. 
     One type of spur dike is a T-shaped spur dike. 
Because of the cross section at the tip of the spur 
dike (the dike wing), it has a different impact 
relative to direct and normal spur dikes, and it has a 
unique effect on the pattern of flow and the scour. 
This effect occurs because the longer longitudinal 
section of the channel is blocked. In a T-shaped spur 
dike, the dike wing reduces the scouring in the bed 
of a dike web.  
     The effects of the dike and Froude number on the 
scour around a T-shaped spur dike in a 90-degree 
bend was examined by Ghodsian and Vaghefi 
(2009).  It was found that the dimensions of the 
scour hole increased as a result of an increase in the 

length of the spur dike. Additionally, it was 
determined that by increasing the Froude number 
and length of the spur dike, the amount of scour 
increases. For bank protection purposes, the 
spacing-to-length ratio of the spur dikes is limited to 
a maximum value of six due to the characteristics of 
the vortex system (Azinfar 2010).  
     Several numerical models have been used to 
calculate flow patterns and sediment but in this 
study, the SSIIM numerical model has been 
employed because of its ability to analyze the flow 
and scour patterns in the channel with complex 
geometry. An experimental and numerical 
simulation of flow using the Sediment Simulation in 
Intakes with Multiblock Option (SSIIM) model 
showed that the SSIIM model could accurately 
simulate the flow pattern in 90 degree bends (Abhari 
et al. 2010). In meander bends, the velocity 
distribution and angle of attack are indicative of 
secondary currents associated with channel 
curvature (Sclafani et al. 2012).  Vaghefi et al. (2014) 
studied the effect of the T-shaped spur dike 
submergence ratio on the water surface profile using 
the SSIIM model. They showed that the flow 
velocity over the spur dike crest level will be greater 
with the increase of T-shaped spur dike 
submergence. Vaghefi et al. (2015) calibrated the 
SSIIM numerical model based on the experimental 
model in a channel bend; therefore, in this study the 
SSIIM model was used.  There has been no thorough 
investigation of the effect of changes in sediment 
density on a river bed’s curved channels or a 
comparison of them in different relative curvatures. 
What makes this study important is the numerical 
study of scour pattern in channel bed under the 
influence of a T-shaped dike. The types of sediments 
in a river bed in order of density, diameter, and fall 
velocity affect the calculations of sediment transport; 
therefore, in this study, the variations of the bed 
topography were evaluated at the channel bend 
with three different relative curvatures due to 
changes in sediment density.  
 
2. Materials and Methods 
 
2.1 Numerical Model 
     The SSIIM numerical model addresses the 
Navier-Stokes equations with the k-ɛ model on a 
three-dimensional (3D) general non-orthogonal grid. 
In SSIIM, the Navier-Stokes equations for turbulent 
flow in a general 3D geometry are solved to obtain 
water velocity. The Navier-Stokes equations for non-
compressible and flow with constant density can be 
expressed as follows: 



Effect of Sediment Density on the Bed Topography in a Channel Bend Using Numerical Modeling 
 

24 

( )jiij
ii

i
j

i UUP
xx

U
U

t
U

ρδ
ρ

−−
∂
∂

=
∂
∂

+
∂

∂ 1
                 (1) 

 
where x1, x2, and x3 are distances and U1, U2, and U3 
are the velocities in three directions. P is pressure 
and δij is the Kronecker delta that is equal to unity 
for i = j, and zero otherwise. The first term on the 
left side of the equation is the transient term while 
the next term is the convective term. The first term 
on the right-hand side is the pressure term while 
the second term on the right side of equation is the 
Reynolds stress term and, to evaluate this term, k-ɛ 
turbulence model is used. The semi-implicit 
method for pressure-linked equations (SIMPLE) 
was used to compute the pressure term. The effect 
of the density variations on the water flow field is 
taken into account by introducing a modified eddy 
viscosity. The eddy viscosity from the k-ɛ model is 
multiplied with a factor, taking into account the 
velocity and concentration gradients. Sediment 
transport is traditionally divided into bed and 
suspended loads. For suspended load, Van Rijn 
(1987) developed a formula for the equilibrium 
sediment concentration,  Cbed,  close to the bed 
(Eqn. 2).  In addition to the suspended load, the bed 
load, qb, can be calculated.  In (Eqn. 3), Van Rijn’s 
formula for bed load is used (2007).  
 

( )
1.0

5.1

3.0

2

015.0











 −








 −

=

υρ
ρρ

τ
ττ

w
gwsa

d
C c

c

bed                              (2) 

( )
1.0

5.1

5.1
50 2

3.0
50

053.0











 −





 −

=








 −
υρ
ρρ

τ
ττ

ρ
ρρ

w
gws

c
c

g
w
ws

D

q

D

b       (3) 

The sediment particle diameter is denoted by d, a is 
a reference level set equal to the roughness height. τ 
is the bed shear stress, and τc is the critical bed 
shear stress for movement of sediment particles 
according to Shield’s curve. ρw and ρs are the 
density of water and sediment, υ is the viscosity of 
the water, and g is the acceleration of gravity 
(Olsen 1999, 2000, 2009). 
 
2.2 Initial Conditions 
     Analysis was performed in clear water 
conditions. The diameter of the bed particles (ds50) 
was 1.28 mm. The standard deviation (ϭ) of the bed  
 
 

particles was 1.3 mm. The discharge of flow was 
only from upstream (Q = 25 liter/second). The 
water depth in the channel upstream and the start 
of the straight run (y initial) was equal to 11.6 cm. The 
Froude (Fr) number of the flow in the straight 
direction of the upstream of channel was 0.34. 
Channel walls were rigid and erosion took place 
only through the channel bed. The spur dike was T-
shaped and 9 cm long, with an equal ratio of wing 
to web length. The dike was positioned at a 45-
degree angle to the channel bend. Three relative 
curvatures related to the three sediment densities 
(ρ = 2.35, 2.5, and 2.65 g/cm3) are analyzed in this 
study in nine cases. It took about eight hours to 
analyze each case for flow pattern and scour. The 
channel bend is shown as Fig. 1, in which Ɵ is the 
angle of each cross-section from the bend 
upstream. 
 
2.3  Boundary Conditions for Numerical 

Model 
    SSIIM-1, Version 1 uses a structured grid. In a 
structured grid, there will always be one more grid 
line than grid cells in any given direction. Because 
boundary conditions are also needed, there will be 
a grid cell with zero thickness at the walls. 
Boundary conditions are required on all 
boundaries for the sediment flow calculation. The 
two most used types of boundary conditions are 
zero gradient and Dirichlet.  
     Zero gradient boundary conditions means the 
derivative of the variable at the boundary is zero. 
In other words, the value at the boundary is the 
same as the value in the cell closest to the 
boundary. This boundary condition is often used as 
the outflow boundary for the sediment 
concentration calculation and can also be used at 
walls. A zero gradient boundary condition is a type 
of Neumann boundary condition, while a Dirichlet 
boundary conditions means the values of a variable 
are given at the boundary. The gradient of all 
parameters in the outputs boundary are zero. In 
addition, the output rates of discharge must be 
introduced in the outgoing boundary conditions. 
The gradient of loss of the kinetic energy as well as 
the value of the kinetic energy at the water’s 
surface is zero. The flux passing the bed and walls 
is zero. The discharge should be introduced in the 
bend entrance. The velocity gradient towards the 
wall is often very steep. If it is to be resolved in the 
grid, this will require too many grid cells. Instead, 
the wall laws area should be used. This means that 
it  is  assumed  that  the  velocity profile follows a  



M. Vaghefi, Y. Safarpoor and S.S. Hashemi 

 

25 

 

 

 

 
 

(a)                                                                                             (b) 
 
Figure 1.  (a) Channel bed plan view and (b) magnified spur dike details. 
  

 
Figure 2.  The boundary conditions at cross section. 
 
certain empirical function,called a wall law.  As 
Eqn. 4 shows, the wall law of Schlichting (1979) is 
used, where U is the velocity, U* is the shear 
velocity, k is a constant coefficient equal to 0.4, y is 
the distance from the wall to the center of the cell, ks 
is the roughness which is equal to 90% of the 
particles’ diameter in the bed grading curve (Olsen 
1999, 2000, 2001). 
 

( )3/30
1

kyLn
KU

U
=                                                     (4) 

 
2.4  Verification 
      For verification of the model, SSIIM parameters 
were calibrated using laboratory model results. The 
intended experiments have been carried out in 
Tarbiat Modares University’s hydraulics laboratory 
in Iran on a laboratory flume with a width of 60 cm 
and height of 70 cm in a compound straight and 
bent route (Fig. 3). The straight upstream route is 
710 cm and is connected to a straight downstream 
route of 520 cm via a 90-degree bend, with an 
external radius of 270 cm and an internal radius of  
 

 
210 cm. The spur dike used in this experiment is T-
shaped. The length of the wing and web are nine cm 
with a height of 25 cm.  This spur dike is vertical and 
non-submerged in a 45-degree position. Each 
experiment took the equivalent of 88% of the scour 
depth on experiment with an equilibrium time of 
120 hours. This amount was 24 hours for each 
experiment (Vaghefi et al. 2012).  Comparisons of the 
bed profiles in the cross sections at downstream and 
upstream of the spur dike are shown in Fig. 4. The 
model is capable of providing the bed topography. 
In other words, the SSIIM model could simulate the 
scour pattern in a 90-degree bend and is applicable 
in this study. 
     At a range of 0–10 cm from the outer bank, the 
bed profiles do not match with each other perfectly 
due to the presence of the spur dike in this area and 
the presence of the turbulent flow (Fig. 4). In the 
project’s execution, the spur dike bed is protected 
from erosion by a collar layer; thus, the difference in 
the position of maximum scour is not significant. 
The difference in scour amounts in all sections 
appears in Table 1, where de/ds is the dimensionless 



Effect of Sediment Density on the Bed Topography in a Channel Bend using Numerical Modeling 

26 

                                                (a)                                                                                         (b)       
 

Figure 3.  The laboratory schematic model (a) before the test and (b) after the test. 
 
 

                           
                                         (e)                                                                                (f) 

Figure 4.  The bed profile in the cross sections of (a) 37.750 (b) 400 (c) 41.250 (d) 420 (e) 43.750 (f) 46.250. 
 



V. Mohammad, S. Yaser and  H.S. Shaker 
 

27 

 
 
Table 1.  Difference in  scour  amounts   related to 
the numerical and laboratory models. 
 
Section 1 de/ds    Section de/ds

Figure 4(a)       1.5%  Figure 4(d) 0.85% 
Figure 
4(b) 

      0.9%  Figure 4(e) 0.02% 

Figure 4(c)       0.95%  Figure 4(f) 0.6% 
 
parameter, and de is the difference in maximum 
scour amounts for the two models and ds is the 
maximum scour depth. 
 

 
 
    Figure 5 illustrates that the two models are a 
good match in terms of the quantity and range of 
maximum scour so that the maximum scour occurs 
in the dike upstream near the tip of its wing. In 
comparison, results are in good agreement.  
     Figure 5 illustrates that Rc is the curvature 
radius of the bend.  X and Y are the distance of 
the coordinates from the center of curve.  To show 
the amount of bed changes, the dimensionless 
quantity (ds / y) is used which represents the ratio 
of the change in the bed depth to the initial water 
depth (yinitial = 11.6 cm). 

 

  

     (b)      (a) 
 

Figure 5.  Bed changes around in the spur dike (a) numerical data and (b) laboratory findings. 
 
 
3.  Results and Discussion 
 
To analyze the effect of the bed sediment density 
on bed changes, the current researchers modeled a 
90-degree bend channel with three relative 
curvatures, with R/B = 2, 3, and 4, where R is the 
radius of curvature and B is the width of channel. 
Sediment density (ρ) with respect to the empirical 
values and based on the gender of the river 
sediments were set at 2.35, 2.5, and 2.65 g/cm3. 
According to Figs. 6–8, in all relative curvatures 
(R/B), the bed topography varies by  increasing the  
sediment density, but  the  maximum  amount  of   
scour   always   occurs   near   the head of dike 
wing at the dike upstream, and the maximum 
amount of sedimentation occurs at the inner bank  
 

 
of bend exit. The laboratory study of Vaghefi et al. 
(2012) showed in this case that R/B = 4.  
     As the Figs. 6 and 7 illustrate, the bed sediments 
were moved to the channel downstream from 
around the spur dike. By increasing the sediment 
densities from 2.35 to 2.65, the maximum amounts 
of scour and sedimentation were reduced (Table 2). 
     In a channel bend with a relative curvature 
equal to 3 and 4, the second scour hole is formed at 
the inner bank of the bend exit; however, when R/B 
= 2, this hole is not formed because the bend length 
is less than when R/B = 3 and 4. When R/B = 2, the 
bend downstream is affected by the main scour 
hole which is formed at the upstream of the dike 
wing). This influence continues until the bend exit. 
 
 



Effect of Sediment Density on the Bed Topography in a Channel Bend using Numerical Modeling 

 

28 

(b) 
 

(a) 

     (c)

 
Figure 6.  Bed topography when R/B = 4 (a) ρ = 2.35 (b) ρ = 2.5 (c) ρ = 2.65. 

 
 

Table 2.  Redacting the maximum scour and sedimentation due to an increase in density. 

Relative curvature Reading the scour Redacting the sedimentation 
R/B = 2 25.98 10% 
R/B = 3 25.93% 23.91% 
R/B = 4 27.41% 46.15 

 

 

 
 
 

X /R c
0 0.2 0.4 0.6 0.8 1

0

0.2

0.4

0.6

0.8

1

ds/y
0.49
0.4
0.2
0

-0.2
-0.4
-0.6
-0.8
-1
-1.14

X/Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1
0

0.2

0.4

0.6

0.8

1

ds/y
0.52
0.4
0.2
0

-0.2
-0.4
-0.6
-0.8
-1
-1.2
-1.35

X/Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1
0

0.2

0.4

0.6

0.8

1

ds/y
0.28
0.2
0

-0.2
-0.4
-0.6
-0.8
-0.9
-0.98



V. Mohammad, S. Yaser and  H.S. Shaker 
 

29 

 
 
 

  
 

 
(b) 
 

(a) 

 

  
(c) 

 
Figure 7.  Bed topography when R/B = 3 (a) ρ = 2.35 (b) ρ = 2.5 (c) ρ = 2.65. 

 
 

     As Figs. 6–8 illustrate, for R/B =4 with an 
increases in sediment density, at the dike 
upstream the range of sedimentation decreases. 
This sedimentation was created by transferring a 
portion of the sediment from  the   spur  dike  bed  
due  to  the longitudinal vortices. Also, 
downstream of the spur dike and at an angle of 
about Ɵ = 600, a sedimentary bar expands in the 
middle of the channel width, such as when the 
density equals 2.65.  It has the highest quantity.  
Vaghefi et al. (2015), by investigating the changes 
in bed topography in different relative curvatures 
concluded  that  when  ρ = 2.35,  by  increasing   

the relative curvature, the maximum amount of 
scour increases in the dike upstream. In this 
paper, it can be seen that when ρ = 2.5 and 2.65 
g/cm3, by increasing the relative curvature 
according to Table 3, the maximum amount of 
scour increased as expected. 
     As Figs. 9 and 10 show, the maximum amounts 
of scour and sedimentation are reduced because, by 
increasing  the  sediment  density,  the  mass  of the  
Sediment increases; therefore, more force is needed  
to pick up and move the sediment. Since the 
conditions  are   the   same   for   all   analyses,   the

X / Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1
0

0.2

0.4

0.6

0.8

1

ds/y

0.38
0.3
0.2
0

-0.2
-0.4
-0.6
-0.8
-1
-1.13

X / Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1
0

0.2

0.4

0.6

0.8

1

ds/y
0.4
0.3
0.2
0

-0.2
-0.4
-0.6
-0.8
-1
-1.2
-1.31

X / Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1
0

0.2

0.4

0.6

0.8

1

ds/y
0.3
0.2
0

-0.2
-0.4
-0.6
-0.8
-0.97



Effect of Sediment Density on the Bed Topography in a Channel Bend using Numerical Modeling 

30 

 

   
     (b)      (a)   

 

  
    (c)  

Figure 8.  The bed topography when R/B = 2 (a) ρ = 2.35 (b) ρ = 2.5 (c) ρ = 2.65. 
 
Table 3.  The dimensionless of maximum scour due to increase in density and relative curvature. 

R/B = 4 R/B = 3 R/B = 2 Sediment density g/cm3 
ds/y = -1.35 ds/y = -1.31 ds/y = -1.27 Ρ = 2.35 (Results of Vaghefi et al. (2015)) 
ds/y = -1.14 ds/y = -1.13 ds/y = -1.10 Ρ = 2.5 (Results of this study) 

ds/y = -0.98 ds/y = -0.97 ds/y = -0.94 Ρ = 2.65 (Results of this study) 
 
maximum scour decreases.  By reducing the 
amount of scour, less sediment is transported at the 
bend downstream and the amount of maximum 
sedimentation is reduced. 
     By increasing the relative curvature of the 
bend, based on change in sediment density, the 
trend of change in the scour amount increases 
(Fig. 10) and the greater change of the diagram 
slope is evident when R/B = 4.  

 
4. Conclusion 

The effect of sediment density (ρ = 2.35, 2.5, and 
2.65 g/cm3) on the bed topography of the channel 
with three relative curvatures (R/B = 2, 3, and 4) 
illustrates nine cases of installing the T-shaped spur 
dike in the middle of the outer bank (three relative 
curvatures related to the three sediment densities). 
The following results were obtained: 

X / Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1 1.2
0

0.2

0.4

0.6

0.8

1

1.2

ds/y
0.29
0.2
0

-0.2
-0.4
-0.6
-0.8
-1
-1.1

X / Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1 1.2
0

0.2

0.4

0.6

0.8

1

1.2

ds/y
0.3
0.2
0

-0.2
-0.4
-0.6
-0.8
-1
-1.2
-1.27

X / Rc

Y
/R

c

0 0.2 0.4 0.6 0.8 1 1.2
0

0.2

0.4

0.6

0.8

1

1.2

ds/y
0.27
0.2
0

-0.2
-0.4
-0.6
-0.8
-0.94



V. Mohammad, S. Yaser and  H.S. Shaker 
 

31 

 
Figure 9.  Diagram of the maximum scour based 
on relative curvature and density. 
 

 
 
Figure 10. Diagram of the maximum  sedimentat- 
ion based on relative curvature and density. 
 
 
1. In all cases, the maximum amount of scour 

occurred near the head of the dike wing at the 
dike upstream, and the maximum amount of 
sedimentation occurred at inner bank of the 
bend exit. 

 
2. In a channel bend with a relative curvature 

equal to 3 and 4, the second scour hole was 
formed at the inner bank of the bend exit. 

 
3. When R/B = 4 by increasing the sediment 

density, at the dike upstream, the range of the 
amount of the sedimentation decreased. 

 
4. By increasing the sediment density from 2.35 to 

2.65 (gram/cm3) when R/B = 4, the maximum 
amounts of scour and sedimentation decreased 
to 27.41% and 46.15%, respectively. When R/B = 
3, the maximum amounts of scour and 
sedimentation decreased to 25.93% and 23.91%, 
respectively. When R/B = 2, the maximum 
amounts of scour and sedimentation decreased 
to 25.98% and 10%, respectively. 

 
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-1.4

-1.3

-1.2

-1.1

-1

-0.9

2.35 2.45 2.55 2.65

M
ax

im
um

 s
co

ur
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al
 d

ep
th

ρ (g/cm3)

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0.25

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M
ax

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 s
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t/
in

it
ia

l 
de

pt
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ρ (g/cm3)

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Effect of Sediment Density on the Bed Topography in a Channel Bend using Numerical Modeling 

 

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