Engineering, Technology & Applied Science Research Vol. 9, No. 1, 2019, 3786-3789 3786 
 

www.etasr.com Tunio et al.: Effect of Coarse Aggregate Gradation and Water-Cement Ratio on Unit Weight … 

 

Effect of Coarse Aggregate Gradation and Water-

Cement Ratio on Unit Weight and Compressive 

Strength of No-fines Concrete 
 

Zaheer Ahmed Tunio  

Department of Civil Engineering, Quaid-

e-Awam University of Engineering, 

Science & Technology, Pakistan 

zaheerahmedtunnio@gmail.com 

Bashir Ahmed Memon 

Department of Civil Engineering, Quaid-

e-Awam University of Engineering, 

Science & Technology, Pakistan 

basher_m@hotmail.com 

Noor Ahmed Memon  

Department of Civil Engineering, Quaid-

e-Awam University of Engineering, 

Science & Technology, Pakistan 

nahmedmemon@gmail.com 

Nawab Ali Lakho  

Department of Civil Engineering, Quaid-

e-Awam University of Engineering, 

Science & Technology, Pakistan 

nawablakho@gmail.com  

Mehboob Oad  

Department of Civil Engineering, Quaid-

e-Awam University of Engineering, 

Science & Technology, Pakistan 

engrmahboob04@gmail.com 

Abdul Hafeez Buller  

Department of Civil Engineering, Quaid-

e-Awam University of Engineering, 

Science & Technology, Pakistan 

engrabdulhafeezbuller@gmail.com 
 

 

Abstract—Self-weight of a structure comprises a major portion of 

the overall structural load which causes conservative structure 

design. Reduction of structures’ self-weight is an active area of 

research today. One of the options is to use lightweight concrete 

and no-fines concrete is one of its types. This type of concrete is 

made with coarse aggregates, cement, and water. From the 

density point of view, it is the lighter concrete compared to 

normal weight concrete but it exhibits less strength. Normally no-

fines concrete is manufactured with uniform size aggregates. The 

performance of no-fines concrete depends on the cement-

aggregate ratio and water-cement (w/c) ratio. This study focuses 

on investigating experimentally the effect of gradation of coarse 

aggregates and the w/c ratio on unit weight and compressive 

strength of no-fines concrete. NFC with two cement-aggregate 

ratios (1:6 and 1:8) having seven combinations of coarse 

aggregate gradations (10-5 mm, 16-13mm, 20-16mm, 20-13mm, 

20-10mm, 16-10mm and 20-5mm) were studied. Two w/c ratios 

are considered 0.38 and 0.42. The effect of coarse aggregate 

gradation, cement-aggregate ratio and w/c ratio are studied in 

terms of unit weight and compressive strength of NFC. The 

results reveal the pronounced effect of aggregate gradation on the 

compressive strength and unit weight of the concrete. Also, a 

substantial effect on the unit weight and compressive strength is 

observed with the variation in cement-aggregate ration and the 

w/c ratio. 

Keywords-no-fines;aggregate graddation;cement to agggregate 

proportion;compressive strength;texture 

I. INTRODUCTION  

No-fines concrete is a form of light weight concrete, which 
is made with only cement, water and coarse aggregates. The 
coarse aggregates are coated with cement paste and connected 
point-to-point with thin cement paste which holds the 
aggregates in a matrix. However, it is believed that it has less 

strength than the ordinary concrete [1, 2]. No-fines concrete 
has many advantages including its prime property of 
lightweight and no segregation due to its porous nature 
avoiding need of vibration during its manufacturing [3]. Due to 
its high porous nature it has many applications like permeable 
pavements [4], water purification plants [5], and parking for 
light weight vehicles. The ordinary concrete is impermeable 
which not only hinders the percolation of water to recharge the 
underground water but also causes high risks of flooding [6-8]. 
Thus, an increasing trend is observed to use porous concrete in 
environmental problems and sustainable construction. No-fines 
concrete is generally made with uniform and large size coarse 
aggregates which produce pours/voids in the concrete resulting 
in the lightweight capacity of the concrete but exhibiting low 
compressive strength and workability. However, it is reported 
that the gradation of coarse aggregates also affects the strength 
properties of concrete, therefore it is suggested that with 
controlling coarse aggregate gradation strength can be 
increased [9]. Tthe size of aggregates also affects its properties 
[10]. Many attempts have been made to study the durability 
and corrosion [11], porosity and permeability [12] of no-fines 
concrete. Strength of no-fines concrete is affected with amount, 
quality and type of cement. The cement-aggregate ratio of no-
fines concrete may vary from 1:4 to 1:10. The porous state of 
NFC causes decrease in workability [2]. Hence w/c ratio also 
plays significant role in manufacturing NFC and its strength 
properties. This study is focused on investigating strength and 
unit weight properties of no-fines concrete with various coarse 
aggregate grades, cement-aggregate ratio and w/c ratio. 

II. EXPERIMENTAL PROCEDURE 

The main aim of this study is to investigate the unit weight 
and compressive strength of no-fines concrete. Two cement-

Corresponding author: Z. A. Tunio  



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aggregate (c-a) proportions 1:6 and 1:8 of NFC were adopted. 
Seven different coarse aggregate gradations (10-5 mm, 16-
13mm, 20-16mm, 20-13mm, 20-10mm, 16-10mm and 20-
5mm) were used. NFC is cast with 0.38 and 0.42 w/c ratio to 
check its effect on the NFC behaviour. Ordinary Portland 
cement (OPC) as per standard of ASTM C150 was used to 
manufacture the NFC. Crushed stones obtained from the local 
market were used as coarse aggregates. They were washed and 
air dried up to SSD followed by accordingly sieving to achieve 
specified aggregate gradation. Water acceptable for drinking 
was used for specimen casting and curing. A total number of 
140 cube specimens of 150mm×150mm×150mm were cast. 
Table I gives the details of the cast and tested specimens. 

TABLE I.  SPECIMEN DETAILS 

S.No 

Aggregate gradation 

(cement-aggregate) 

(mm) 

Cement-

aggregate (c-a) 

proportion 

w/c ratio 
Number of 

specimens 

1 (10-5) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 

2 (16-13) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 

3 (20-16) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 

4 (20-13) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 

5 (20-10) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 

6 (16-10) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 

7 (20-5) 

1:6 
0.38 5 

0.42 5 

1:8 
0.38 5 

0.42 5 
 

All the ingredients of the respective mixes were batched 
accordingly in an electric operated mixer and casting of 
specimens was done accordingly. The specimens were 
demoulded after 24 hours of casting and kept in curing tank up 
to the age of testing. Wet curing was applied. All specimens 
were tested at 28 days of age. Before testing the specimens for 
compressive strength, all the specimens were weighed to 
determine their unit weight. To determine compressive 
strength, the cubes were tested in a universal testing machine 
(UTM). The cubes were placed with the cast faces in contact 
with platens of the testing. Then, compressive load was applied 
gradually. The ultimate load at the crushing failure of cube 
specimens was recorded. The load divided by the cross 
sectional area of the cube determines the ultimate compressive 
strength. Five cube specimens of each mix were cast from each 
batch. The ultimate compressive strength and unit weight of 

each of the five specimens was measured. The average of the 
five values represents the ultimate compressive strength and 
unit weight of the respective batch of no-fines concrete. 

III. RESULTS AND DISCUSSION 

A. Compressive Strength  

The results of average compressive strength tests are 
presented in Table II. 

TABLE II.  AVERAGE COMPRESSIVE STRENGTH AND UNIT WEIGHT 

S.No. 

Aggregate 

gradation 

(mm) 

Cement-

aggregate (c-a) 

proportion 

w/c 

ratio 

Comp 

(MPa) 

Unit 

weight(kg/m3) 

1 (10-5) 

1:6 
0.38 9.2 1889 

0.42 12.4 1965 

1:8 
0.38 7.1 1944 

0.42 6.1 1835 

2 (16-13) 

1:6 
0.38 4.7 1759 

0.42 7.1 1717 

1:8 
0.38 3.6 1734 

0.42 5.9 1769 

3 (20-16) 

1:6 
0.38 8.7 1878 

0.42 10.7 1778 

1:8 
0.38 6.8 1789 

0.42 6.5 1717 

4 (20-13) 

1:6 
0.38 8.9 1839 

0.42 12.1 1840 

1:8 
0.38 7.9 1860 

0.42 10.5 1924 

5 (20-10) 

1:6 
0.38 11.2 1906 

0.42 15.7 1881 

1:8 
0.38 8.8 1807 

0.42 12.4 1859 

6 (16-10) 

1:6 
0.38 9.6 1929 

0.42 10.7 1846 

1:8 
0.38 6.5 1807 

0.42 8.4 1833 

7 (20-5) 

1:6 
0.38 9.7 1902 

0.42 12 1924 

1:8 
0.38 7.9 1818 

0.42 7.5 1834 
 

Figures 1 and 2 compare the effects of aggregate gradation 
and cement-aggregate (c-a) proportion on the compressive 
strength of no fines concrete. 

 

 

Fig. 1.  Compressive strength v/s aggregate gradation and cement-
aggregate proportion at 0.38 w/c ratio. 

The results reveal the pronounced effects of aggregate 
gradation and the c-a proportion on the compressive strength. 



Engineering, Technology & Applied Science Research Vol. 9, No. 1, 2019, 3786-3789 3788 
 

www.etasr.com Tunio et al.: Effect of Coarse Aggregate Gradation and Water-Cement Ratio on Unit Weight … 

 

Figures 3 and 4 depict the effect of w/c ratio on the 
compressive strength of NFC. The significant effect of 
aggregate gradation is self-evident from the Table values and 
the Figures. 

 

 

Fig. 2.  Compressive strength v/s aggregate gradation and cement-
aggregate proportion at 0.38 w/c ratio. 

 

Fig. 3.  Compressive strength v/s water-cement of NFC with 1:6 cement-
aggregate proportion  

 

Fig. 4.  Compressive strength v/s water-cement of NFC with 1:8 cement-
aggregate proportion 

NFC manufactured with (20-10)mm gradation exhibited the 
highest and NFC with (16-13)mm gradation yielded the lowest 
compressive strength in the respective group of NFC having 
the same c-a proportion and w/c ratio. The compressive 
strength of NFC with 1:6 c-a proportion exhibited higher 
compressive strength than the NFC with 1:8 c-a proportion 
with the same aggregate gradation and w/c ratio. The NFC 
produced with 0.42 w/c ratio yielded higher compressive 

strength than that of NFC with 0.38 w/c ratio when compared 
to the respective batches of NFC with aggregate gradation and 
c-a proportion. Minimum compressive strength of NFC is 
found to be 3.6MPa manufactured with (16-13) mm gradation, 
1:8 c-a proportion and 0.38 w/c ratio while the maximum value 
of the same mix was 7.1MPa with 1:6 c-a proportion and 0.42 
w/c ratio. The same trend is observed in case of NFC having 
(20-10) mm aggregate gradation being 8.8MPa with 1:8 c-a 
proportion and 0.38 w/c ratio, increased to 11.2MPa (1:6, 
0.38), 12.4MPa (1:8, 0.42) and 15.7MPa (1:6, 0.42). Difference 
in compressive strength of the order of 336% is observed when 
highest compressive strength 15.7MPa of NFC having (20-10) 
mm aggregate gradation, 1:6 c-a proportion and 0.42 w/c ratio 
is compared to the lowest value of 3.6MPa of NFC having (16-
13) mm aggregate gradation, 1:6 c-a proportion and 0.42 w/c 
ratio. This infers the significance of aggregate gradation, 
cement-aggregate proportion and w/c ratio on the compressive 
strength of NFC. 

B. Unit Weight  

Table II also shows the values of average unit weight of 
NFC produced with different aggregate gradation, cement 
aggregate proportion and w/c ratio. The maximum unit weight 
of NFC observed is 1965kg/m3 and the minimum was found to 
be 1717kg/m3. The difference between maximum and 
minimum values is only 14.4%. The unit weight of NFC is 
affected by variations in aggregate gradation, c-a proportion 
and w/c ratio but it is not only marginal but also without any 
trend in terms of the gradation range, value of c-a proportion 
and w/c ratio (Figure 5). The effect of aggregate gradation, c-a 
proportion and w/c ratio may be considered as marginal if the 
unit weight is the major parameter of consideration while 
producing NFC otherwise their effect may be ignored.  

 

 

Fig. 5.  Unit weight of NFC with different aggregate gradation, c-a 
proportion and w/c ratio 

C. Texture of NFC 

In addition to compressive strength and unit weight, the 
apparent texture of the NFC is also observed in terms of 
variation in aggregate gradation. Figure 6 depicts texture 
pictorial comparison. As expected, NFC produced with 
aggregate gradation owing wider range of gradation and small 
size aggregates (e.g. 10-5mm and 20-5 mm) results in 
apparently dense and good looking texture with small voids as 
compared to the NFC having close range gradation and larger 



Engineering, Technology & Applied Science Research Vol. 9, No. 1, 2019, 3786-3789 3789 
 

www.etasr.com Tunio et al.: Effect of Coarse Aggregate Gradation and Water-Cement Ratio on Unit Weight … 

 

size aggregates (e.g. 16-13mm and 20-10mm). However, in 
case of no fines concrete, this factor may not be considered as 
important as it is compressive strength and unit weight. 

 

  

 
 

 

 

 

Fig. 6.  Pictorial views of the texture of NFC 

IV. CONCLUSIONS 

• Aggregate gradation, cement-aggregate proportion and w/c 
ratio significantly affect the compressive strength of no 
fines concrete. 

• A difference as high as 336% is observed between 
maximum and minimum compressive strength of no-fines 
concrete due to variation in aggregate gradation, c-a 
proportion and w/c ratio.  

• No-fines concrete produced with (20-10) mm gradation, 1:6 
c-a proportion and 0.42 w/c ratio exhibited the highest 
compressive strength of 15.7MPa. 

• Minimum compressive strength was found to be 3.6MPa in 
the case of (16-17) mm aggregate gradation, 1:8 c-a 
proportion and 0.38 ratio. 

• The unit weight of no-fines concrete is found to be 
marginally affected by the variation in aggregate gradation, 
c-a proportion and w/c ratio.  

• The maximum difference between the minimum and 
maximum unit weight is found to be only about 14%. 

• Apparent texture of the no fines concrete was also 
influenced by the aggregate gradation. No fines concrete 
with wide rage gradation and smaller size aggregates 
exhibited apparently good looking and dense texture. 

Based on the results of the conducted experimental study 
and the discussion and conclusions made above it may be 
concluded that while producing no fines concrete, gradation of 
aggregates, c-a ratio and w/c ratio may be chosen 
appropriately, particularly when the compressive strength is the 
major parameter of consideration. However, to a limited extent, 
unit weight and apparent texture also depend upon these 
factors.  

ACKNOWLEDGMENT 

Authors are grateful to the Quaid-e-Awam University of 
Engineering, Science and Technology, Nawabshah for 
providing the research facilities. 

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(16-13) mm
(10-5) mm

(16-10) mm

(20-10) mm 

(20-13) mm

(20-5) mm 

(20-16) mm