Engineering, Technology & Applied Science Research Vol. 8, No. 2, 2018, 2796-2798 2796  
  

www.etasr.com Lakhiar et al.: Effect of River Indus Sand on Concrete Tensile Strength 
 

Effect of River Indus Sand on Concrete Tensile 
Strength 

 

Muhammad Tahir Lakhiar 
Faculty of Civil and Environmental 

Engineering  
Universiti Tun Hussein Onn  

Malaysia  
gf170030@siswa.uthm.edu.my 

Noridah Mohamad 
Faculty of Civil and Environmental 

Engineering  
Universiti Tun Hussein Onn  

Malaysia  
noridah@uthm.edu.my 

Muhammad Abu Bakar Shaikh 
Department of Civil Engineering 

Mehran University of Engineering and 
Technology 

Pakistan  
muhammad.abubakar@faculty.muet.edu.pk 

Anees Ahmed Vighio 
Department of Civil Engineering, 

Mehran University of Engineering and 
Technology 

Pakistan 
aneesahmedvighio08@gmail.com 

Ashfaque Ahmed Jhatial 
Faculty of Civil and Environmental 

Engineering  
Universiti Tun Hussein Onn  

Malaysia  
aajhatial@hotmail.com 

Abdul Aziz Abdul Samad 
Faculty of Civil and Environmental 

Engineering  
Universiti Tun Hussein Onn  

Malaysia  
azizs@uthm.edu.my 

 

 

Abstract—In the development of Pakistan construction industry, 
the utilization of River Indus sand in concrete as fine aggregate 
has expanded tremendously. The aim of this research is to study 
the effect of Indus River sand on the tensile strength of various 
grades of concrete when it is utilized as fine aggregate. Concrete 
Samples of M15, M20 and M25 grade concrete were cured for 7, 
14, 21 and 28 days. Based on the results, it is found that concrete 
became less workable when Indus river sand was utilized. It is 
recorded that tensile strength of concrete is decreased from 5% 
up to 20% in comparison with hill sand. The results were derived 
from various concrete grades. 

Keywords-tensile strength; workability; river Indus sand; hill 
sand 

I. INTRODUCTION 
Concrete is broadly utilized as building material because of 

it is highly durable, easily accessible and economical [1]. 
Basically, concrete is a blend of binder, aggregates (coarse and 
fine), water and admixtures [2-3]. Fine aggregate is an 
important ingredient in concrete occupying 25% to 35% of its 
volume. It is utilized as filler in concrete. The composition, 
shape, and size of the fine aggregates have great influence on 
the fresh and hardened properties of concrete [4-5]. In Indus 
River there is a siltation problem which causes negative effects 
on storage capacity, water quality and subsequently, reduces 
power and irrigation capability [6]. Normally, hill sand is used 
as fine aggregate in Pakistan construction industry, which 
makes the concrete un-economical in northern areas of Sindh. 
To overcome this problem, in this research River Indus sand 
was used as fine aggregate to make the concrete economical 
and solve the siltation problem. In the experimental work, hill 
sand was fully replaced by Indus River sand. The workability 
and tensile strength of concrete were examined with 

comparison to the conventional concrete which used hill sand 
as fine aggregates. 

II. LITERATURE REVIEW 
Authors in [7] analyzed the M25 grade concrete at different 

curing regimes (7, 14 and 28 days). Foundry sand replaced 
natural sand with 10%, 20%, 30%, 40% and 50% by weight of 
fine aggregate. The results indicated that the compressive 
strength increased up to 30%. However, further increment of 
replacement percentage showed a decrease in compressive 
strength. Authors in [8] experimented with the mechanical 
properties of concrete at different proportions of 0%, 15%, 
25% and 35% where natural sand was replaced by foundry 
sand. The results concluded that the optimum percentage was 
25 % which gave the maximum strength. Authors in [9] studied 
M25 grade concrete at different curing regimes (7, 14 and 28 
days). The sea sand was partially replaced by river sand at 
different percentages of 20%, 40%, 60%, 80% and 100%. The 
results demonstrated that the compressive strength of this 
concrete was decreased up to 6.5% compared to that of 
conventional concrete. Authors in [10] replaced natural sand at 
different percentages 10%, 20% and 30% with foundry sand to 
manufacture M20 grade concrete. The results concluded that 
the compressive strength increased significantly as the 
replacement percentage increased. Meanwhile, the tensile 
strength was maximum at 20% replacement. 

III. MATERIALS AND METHODS 

A. Materials 
Ordinary Portland cement CEM I 42.5 N that complies with 

ASTM C0150-04AE01, branded name as Falcon cement was 



Engineering, Technology & Applied Science Research Vol. 8, No. 2, 2018, 2796-2798 2797  
  

www.etasr.com Lakhiar et al.: Effect of River Indus Sand on Concrete Tensile Strength 
 

selected for this research work. In this research, the two types 
of fine aggregates (hill sand and River Indus sand) were used. 
Material properties like specific gravity, water absorption, fine 
modulus and color of hill sand and River Indus sand are shown 
in Tables I and II. 

TABLE I.  PROPERTIES OF HILL SAND  

S.NO Particulars of test Test results 
1 Specific gravity 2.56 
2 Fineness modulus 3.01% 
3 Water absorption 1.2% 
4 Color Light orange 

TABLE II.  PROPERTIES OF INDUS RIVER SAND  

S.NO  Particulars of test  Test results  
1  Specific gravity  2.50 
2  Fineness modulus  2.04%  
3  Water absorption  3.8%  
4  Color Dark grey 

 

B. Test Parameters and Mixture Proportions 
Three grades of concrete mixtures (M10, M15 and M20) 

were studied for this research. Two different kinds of concrete 
mix were cast, namely conventional concrete using hill sand as 
fine aggregate and concrete using Indus River sand as fine 
aggregate. Hill sand was fully replaced with Indus River sand. 
The cylinders were tested for concrete tensile strength at curing 
ages of 7, 14, 21, 28 days. Mixing was carried out using a 
rotary mixer. The concrete mix workability was checked by 
standard slump test using standard slump cone and procedure 
according to ASTM C 143. All the cylinders were extracted 
from the molds after 24 hours and cured for the required age of 
testing. The concrete tensile strength was tested using the 
Universal Testing Machine available in the Civil Engineering 
Department, MUET Jamshoro, and followed the overall 
procedure described in ASTM C496/C496M-17. 

IV. RESULTS AND DISCUSSION 

A. Slump Test (ASTM C 143) 
For slump test, the ASTM C 143 standard was followed. 

The workability results of both concretes are shown in Table 
III. It is seen that the Indus River sand concrete is low 
workable when compared to the conventional concrete. 

TABLE III.  WORKABILITY VALUES OF CONCRETE MIXES  

Mixture Slump Value (mm) 
Conventional concrete (M15) 31.75 

River sand concrete (M15) 25.4 
Conventional concrete (M20) 50.8 

River sand concrete (M20) 43.18 
Conventional concrete (M25) 63.5 

River sand concrete (M25) 50.8 

B. Tensile Strength 
Tensile strength test was conducted according to the ASTM 

C496/C496M-17 standard. The Tensile Strength results of both 
concretes are shown in Table IV and Figures 1-3. The results 

showed that there was a reduction in the tensile strength of 
river sand concrete because of the improper material bonding 
due to the larger amount of clayey particles present in River 
Indus sand. After 7 days curing, the tensile strength of M15, 
M20 and M25 river sand concrete decreased by 12.72%, 
10.21% and 5.88%, respectively. After 14 days water curing, 
the tensile strength of M15, M20 and M25 river sand concrete 
decreased by 6.87%, 3.87% and 2.79% respectively. At 21 
days water curing, the tensile strength of M15, M20 and M25 
river sand concrete decreased by 2.06%, 2.77% and 1.63%, 
respectively. At 28 days water curing, the tensile strength of 
M15, M20 and M25 river sand concrete decreased by 1.90%, 
1.68% and 1.08%, respectively. 

TABLE IV.  TENSILE STRENGTH OF M15, M20 AND M25 GRADE CONCRETE. 

Mixture 

T
en

si
le

 
S

tr
en

g
th

 a
t 

7
 

D
a

y
s 

(M
P

a
) 

T
en

si
le

 
S

tr
en

g
th

 a
t 

1
4

 D
a

y
s 

(M
P

a
) 

T
en

si
le

 
S

tr
en

g
th

 a
t 

2
1

 D
a

y
s 

(M
P

a
) 

T
en

si
le

 
S

tr
en

g
th

 a
t 

2
8

 D
a

y
s 

(M
P

a
) 

Conventional concrete (M15) 1.24 1.71 1.98 2.13 
River sand concrete (M15) 1.10 1.60 1.94 2.09 

Conventional concrete (M20) 1.51 1.92 2.22 2.41 
River sand concrete (M20) 1.37 1.85 2.16 2.37 

Conventional concrete (M25) 1.80 2.21 2.48 2.80 
River sand concrete (M25) 1.70 2.15 2.44 2.77 

 
 

 
Fig. 1.  Tensile strength vs curing regimes of M15 grade concrete  

 

 
Fig. 2.  Tensile strength vs curing regimes of M20 grade concrete  



Engineering, Technology & Applied Science Research Vol. 8, No. 2, 2018, 2796-2798 2798  
  

www.etasr.com Lakhiar et al.: Effect of River Indus Sand on Concrete Tensile Strength 
 

 
Fig. 3.  Tensile strength vs curing regimes of M25 grade concrete  

V. CONCLUSION 
Concrete becomes less workable when Indus River sand is 

utilized as fine aggregate. For better results of workability, 
certain admixtures will be required. The results showed the 
tensile strength of Indus River sand concrete 1% to 2% lower 
than the tensile strength of conventional concrete. Hence, it is 
concluded that M25 grade concrete gave better results for 
concrete with Indus River sand as fine aggregate. 

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“Distribution, production, and engineering characteristics of aggregates, 
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