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Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7805-7808 7805 
 

www.etasr.com Nguyen et al.: Evaluating the Possibility of Replacing Natural Fine Aggregates in Concrete with … 

 

Evaluating the Possibility of Replacing Natural Fine 
Aggregates in Concrete with Recycled Aggregates 

 

Duy Duan Nguyen 
Faculty of Construction 

Vinh University 
Vinh, Vietnam 

duan468@gmail.com 

Dieu Thuy Nguyen 
Faculty of Construction 

Vinh University 
Vinh, Vietnam 

dieuthuy03@gmail.com 

Thi Hao Cao 
Faculty of Construction 

Vinh University 
Vinh, Vietnam 

haoxd13@gmail.com 

Van Tien Phan 
Faculty of Construction 

Vinh University 
Vinh, Vietnam 

vantienkxd@vinhuni.edu.vn 
 

 

Abstract-This paper presents an investigation on the possibility 
of replacing natural fine aggregates with recycled aggregates in 

concrete. The studied recycled aggregates were acquired from 

crushed waste concrete from demolishing works. The rate of 

replacement of natural fine aggregates was 10%, 20%, and 30% 

by weight. Compressive and flexural tensile strength of concrete 

incorporating recycled aggregates was investigated at 28 days of 
curing. The results show that the compressive and flexural 

strength of concrete is strongly affected by the percentage of 

recycled aggregates. It has been found that the strength decreases 

linearly with increasing recycled aggregate content. So, in order 

to apply recycled waste to concrete as fine aggregates, it is 

necessary to perform supplement research with appropriate 

additives to compensate for the loss of compressive and flexural 
strength. 

Keywords-compressive strength; flexural tensile strength; 

recycled concrete; fine aggregates 

I. INTRODUCTION  

The use of recycled materials instead of natural sources in 
concrete has been concerned by various researchers [1-6]. The 
influence of using recycled waste aggregates instead of natural 
fine aggregates to the modulus of elasticity, pulse velocity and 
long-term properties such as drying shrinkage and creep has 
been investigated in [1]. It has been found that the detrimental 
effects of using crushed concrete fines in concrete can be 
mitigated by a partial replacement of crushed concrete fines 
with pulverized fuel ash [1]. It was found that the rate of 
replacement of fine aggregates by recycled sources can be up to 
10% for producing C30 concrete [2]. By using recycled fine 
concrete aggregates, the environmental impact and the 
consumption of natural resources can be significantly reduced. 
The results in [5] indicate that recycled concrete has a suitable 
behavior according to the limits indicated by different 
international codes for structural concrete. The durability of 
concrete with recycled fine aggregates has also been 

investigated in [4], in which the recycled fine aggregates 
proved to be sustainable materials for construction works. The 
optimum replacement percentage of river sand by recycled fine 
aggregates was found to be 30%. Authors in [5] studied the use 
of recycled fine aggregates in concrete with durability 
requirements. Different percentages of recycled fine aggregates 
(0%, 20%, and 30%) were considered and evaluated. It has 
been found that the compressive strengths of recycled and 
conventional concrete are similar and the durable behavior of 
recycled concrete is as good as that of the conventional 
concrete. 

Many studies on the use of recycled coarse aggregates 
instead of natural coarse aggregates in concrete have been 
carried out [2, 6-11]. The effect of the amount of recycled 
coarse aggregates on the properties of recycled aggregate 
concrete has been investigated in [11], in which 4 different 
recycled aggregate concrete types were produced with the same 
design compressive strength in replacement ratios up to 100%. 
The influence of the type of recycled aggregates, namely 
unbound stone, crushed concrete, and crushed brick, to the 
properties of concrete has been studied in [12]. The results 
showed that the performance of concrete containing each type 
of recycled aggregates was largely influenced by the aggregate 
nature and quality, in addition to the attached mortar content. 

Studies on the use of recycled aggregates in concrete 
instead of natural coarse aggregates have been carried out by 
various authors. However, there are only a few published 
papers on the use of recycled aggregates instead of fine 
aggregate in concrete. In this paper, the possibility of replacing 
natural fine aggregates by recycled aggregates in concrete will 
be evaluated in terms of compressive and flexural strength of 
concrete. The results will give documented recommendations 
for further studies. 

Corresponding author: Van Tien Phan



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II. COMPOSITION OF RECYCLED CONCRETE 

Waste concrete obtained from demolishing works was 
crushed and then sieved through standard sized sieves to obtain 
fine recycled aggregates with diameter ranging between 
0.14mm and 5mm. The crushed aggregates were soaked in 
water until saturation, and then they were allowed to dry at 
room temperature. For evaluating the possibilities of replacing 
natural fine aggregates with recycled aggregates in concrete, a 
reference mixture was selected. Natural sand was then replaced 
by recycled aggregates at various rates, namely 10%, 20%, and 
30% by weight. After casting into molds, the samples were 
stored under normal conditions and the experiments were 
carried out at 28 days of curing. 

In the compressive strength experiment, normal force was 
applied on both surfaces of cylindrical concrete specimens with 
the loading speed set to 0.5kN/s. The maximum compression 
force was then recorded (Figure 1). Cylindrical samples sizes 
D150×H300 were cast and cured in normal conditions before 
being compressed to determine their compressive strength. The 
compressive strength of concrete was determined based on the 
Vietnamese standard TCVN 10303:2014. 

In the flexural bending test, 3 beam specimens with a size 
of 150×150×600mm were sampled following the standard 
TCVN 3105:1993, and were left to be cured for 28 days. The 
flexural strength of concrete beams was determined based on 
the TCVN 3119:1993 standard. The four-point bending test set-
up is shown in Figure 2. The bending load was continuously 
increasing at a constant rate equal to 0.6±0.4daN/cm2 for 1s 
until failure occurred. 

The replacement rates of recycled aggregates were 0%, 
10%, 20% and 30%. Mix components for 1m3 of concrete are 
presented in Table I. 

 

(a) 

 

(b) 

 

Fig. 1.  (a) An in-process experiment (CP20) and (b) the recorded 
destructive force. 

(a) 

 

(b) 

 

Fig. 2.  Flexural experimental set-up. 

TABLE I.  MIX CONTENTS FOR 1 m3 OF CONCRETE 

Cement (kg) Sand (kg) Coarse aggregates (kg) Water (kg) 

292.5 648.3 1216.3 195.0 
 

III. RESULTS AND DISCUSSION 

The peak normal load obtained in the compression 
experiment is shown in Table II. From the value of the 
destructive force P (kN) of each sample, the compressive 
strength (MPa) is calculated as follows: 

The bearing area S is calculated by (1) where R is the 
sample radius, which is half the sample diameter D = 15cm, so: 

S=π.R2= π.7.52= 176.71cm2    (1) 

The compressive strength is then calculated by (2): 

R=α.P/S    (2) 

where P is the destructive load of the sample, S is the 
compressive area, α is the coefficient of converting the 
experimental results when compressing samples with different 
size from the standard samples (150×150×150mm). With 
cylinder sample D150×H300, α = 1.2.  

TABLE II.  COMPRESSIV E STREN GTH EXPERIMENT RESULTS 

No. 
Replacement 

rate 

Sample 

destructive 

force (kN) 

Compressive 

strength (MPa) 

Average 

value 

(MPa) 

1 
0 % 

295.2 20.04 
19.98 2 293.5 19.93 

3 294.1 19.97 
4 

10 % 
288.1 19.56 

19.36 5 286.2 19.43 
6 281.3 19.10 
7 

20 % 
262.1 17.79 

17.82 8 259.4 17.61 
9 265.8 18.04 
10 

30 % 
251.2 17.05 

17.07 11 252.4 17.13 
12 250.8 17.03 

 



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The value of compressive strength of the experimental 
samples in shown in Table II. It can be observed that the 
replacement of recycled fine aggregates affects significantly 
the compressive strength of concrete. The decrease is recorded 
as 3% at the replacement rate of 10%, 10% at the replacement 
rate of 20%, and 14% at the replacement rate of 30%. The 
compressive strength of concrete at various replacement rates 
of recycled fine aggregate is shown in Figure 3. 

 

 
Fig. 3.  Compressive strength of concrete at various replacement rates of 
natural fine aggregates with recycled fine aggregates. 

The maximum force achieved in the bending test is the 
bending load that breaks the specimen. Table III shows the 
maximum bending force obtained in the flexural bending test. 
The flexural strength of beam specimens was calculated 
according to TCVN 3119:1993 by using (3): 

Rfs=ɣ.P.l/(a.b
2) (daN/cm2)    (3) 

where P is the recorded maximum force, l is the span length, a 
and b are the dimensions of the specimen and ɣ is the 
coefficient of converting the experimental results when 
compressing samples of different size from the standard 
samples. In the present flexural experiment, the beam specimen 
was cast in standard dimensions, therefore ɣ = 1. 

It can be seen from Figure 4 that the flexural strength of the 
specimens decreased linearly with increasing recycled 
aggregates percentage of replacement. 

TABLE III.  FLEX URAL BENDIN G EXPERIMENT RESULTS 

No. 
Replacement 

rate 

Maximum 

force (kN) 

Flexural 

strength 

(MPa) 

Average 

value (MPa) 

1 
0 % 

52.03 8.48 
8.56 2 53.12 8.66 

3 52.37 8.53 
4 

10 % 
52.28 8.52 

8.47 5 52.09 8.49 
6 51.50 8.39 
7 

20 % 
50.26 8.19 

8.27 8 50.96 8.30 
9 51.02 8.31 
10 

30 % 
50.12 8.17 

8.05 11 49.05 7.99 
12 48.98 7.98 

 

 
Fig. 4.  Flexural strength of concrete at various replacement rates of 
natural fine aggregates with recycled fine aggregates. 

The diminution of strength of recycled concrete with 
partially replacement of recycled aggregates has been reported 
by numerous authors [2, 3, 7 10, 12]. The present investigation 
on the influence of recycled fine aggregates on the compressive 
and flexural strength of concrete indicates that the compressive 
strength and flexural strength decrease linearly with the 
increasing content of recycled aggregates. Therefore, in order 
to apply recycled waste to concrete as fine aggregates, it is 
necessary to perform supplement research with appropriate 
additives to compensate for the shown above loss of strength. It 
is also possible to consider reinforcing concrete with fibers at 
appropriate concentrations. 

IV. CONCLUSION 

The current paper presented the results of a research on the 
compressive and flexural strength of concrete utilizing recycled 
fine aggregates from demolition works. The rates of 
replacement of natural aggregate with recycled aggregates were 
0%, 10%, 20%, and 30%. The experiments were performed at 
28 days of curing. The results show that the compressive 
strength and flexural strength of concrete are strongly affected 
by the percentage of recycled aggregates. It has been found that 
the strength decreases linearly with the increasing percentage 
of recycled aggregates. Additional studies are needed to 
evaluate more thoroughly the effectiveness of the use of 
recycled aggregates in concrete. 

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