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Engineering, Technology & Applied Science Research Vol. 11, No. 2, 2021, 7041-7046 7041 
 

www.etasr.com Eloget et al.: The Effect of Sisal Juice Extract Admixture on Compressive and Flexural Strength of … 

 

The Effect of Sisal Juice Extract Admixture on 

Compressive and Flexural Strength of Cement 

Concrete 
 

Michael O. Eloget  

SMARTEC, Jomo Kenyatta University of Agriculture 

and Technology 
Nairobi, Kenya 

miklate2@gmail.com  

Silvester O. Abuodha 

Department of Civil Engineering 

University of Nairobi 

Nairobi, Kenya 

sochieng@yahoo.com 

Mathew M. O. Winja 

Department of Civil Engineering 

Jomo Kenyatta University of Agriculture and Technology 
Nairobi, Kenya 

mathewwinja@yahoo.com 
 

 

Abstract-The characteristics of concrete are influenced by the 

ratio of water to cementitious materials (w/c) used in the mixture. 

An increase in paste quality will yield higher compressive and 

flexural strength, lower permeability, increased resistance to 

weathering, improve the bond between concrete and 

reinforcement, reduced volume change from drying and wetting, 

and reduced shrinkage cracking tendencies. Admixtures are used 

to improve the properties of concrete or mortar. The current 

study investigates the effect of Sisal Juice Extract (SJE) as an 

admixture on concrete durability. SJE contains unrefined 
minerals which can be used as organic retarders to increase the 

rate of strength development at an early age. A total of 84 

concrete cubes were produced in 7 sets of 12 samples each. One 

set was the control mix which had zero SJE content. The 

remaining sets had varying dosages of SJ namely 5%, 10%, 15%, 

20%, 25%, and 30%. Twelve beam specimens were also cast and 

subjected to the three-point flexural test. To establish the effect 
on strength of concrete, compressive strength was tested at 7, 14, 

28, and 56 days while flexural strength was tested at 28 days. The 

highest compressive strength was achieved at 5% dosage beyond 
which a decrease in strength occurred for all the higher dosages. 

Keywords-sisal juice extract; compressive strength; flexural 

strength 

I. INTRODUCTION  

Concrete is one of the most commonly used construction 
materials [1]. The production of concrete is achieved by mixing 
predetermined proportions of cement and aggregates with 
water to form a plastic material which transforms to a hard 
strong and load bearing material when dried [2]. The hardening 
of concrete is attained through hydration which is an 
exothermic reaction between cement and water. The addition of 
water to concrete during mixing enables hydration to take place 

while the excess quantity forms a slurry with the cement which 
coats the aggregates in the mix, lubricating them and allowing 
easy movement during compaction [3]. The first stage of 
hydration that leads to stiffening is caused by the reaction 
between water and a chemical constituent of cement called 
tricalcium silicate (C3S) [4]. The time taken for concrete to 
harden after the addition of water to the cement–aggregate mix 
is referred to as setting time. The last stage occurs over a longer 
period, called final setting time, and is caused by the reaction 
of water with calcium silicate (C2S). It is during this stage that 
hardening occurs, as a result of the exothermic nature of 
hydration. The higher the rate of hydration is, the higher the 
rate of both heat generation and strength development [5-7]. 

The expansion and contraction of the hardened concrete are 
associated with the generated heat which causes stresses that 
lead to microscopic cracks within the concrete structure. This 
phenomenon causes problems when constructing large concrete 
structural members such as piers, dams and bridges and 
generally when concreting structures in hot climates [8, 9]. In 
order to slow both the rate of hydration and the generation of 
heat and strength development, admixture materials called 
retarders may be used as they have the effect of delaying the 
initial setting time of concrete thereby providing enough time 
for concrete operations [10, 11]. Retarding admixtures reduce 
the rate of hydration by blocking cement from reacting with 
water [12-15]. This happens because the retarding admixtures 
are mainly based on materials having lignosulfonic acids and 
their salts, hydroxyl-carboxylic acids and their salts, sugars 
including their derivatives, inorganic salts such as borates 
phosphates, and zinc and lead salts. [7, 16-19]. Admixtures 
come in various forms and are usually imported and expensive 
to acquire, hence cheaper admixture materials need to be 
established from locally available sources [20, 21]. The ability 

Corresponding author: Michael O. Eloget 



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of retarders to reduce the rate of heat generation and strength 
development when concreting large structural members also 
helps to prevent the occurrence of capillary cracks that 
compromise the durability of concrete structures [22]. 

In [23], the effects of sugar on the setting time of cement 
and the compressive strength of concrete were investigated. In 
all curing periods the compressive strength was found 
minimum for concrete with 0.3% sugar and maximum for 
concrete with 0.08% sugar. Only in 0.3% sugar, the 
compressive strength was found less than the strength found for 
concrete with 0% sugar. The compressive strengths of all the 
other sugar percentages were found increased in comparison 
with plain concrete's. The authors concluded that the concrete 
compressive strength was maximum for 0.08% sugar in all 
curing periods among the sugar percentages used. Authors in 
[24] evaluated the effect of sugar on the compressive strength 
of concrete. Ordinary Portland Cement-OPC (ACC cement) of 
43 grades was used for the cube casting. The cubes having 
sugar dosages of 0%, 0.06%, 0.08% by weight of cement were 
cast and the compressive strength of cubes for 7, 21, and 28 
days were tested. It was observed that the setting time and 
workability of concrete increased with the increase in sugar 
dosage and that there was an increase in the compressive 
strength of about 16.02% at 28 days compared to ordinary 
concrete [24]. Authors in [25] studied the effect of sugar on 
strength and durability of HVFAC concrete with similar 
results. It was observed that the addition of sugar increased the 
workability and compressive strength of concrete. 

Waste materials can be used to produce new products or 
can be used as admixtures so that natural resources are used 
more efficiently and the environment is protected from waste 
deposits [26]. Kenya, like many other countries, grows sisal in 
large quantities for extraction of fiber but the remains after 
extraction are not fully utilized. The objective of this paper is to 
study the potential of utilizing SJE that is generated from sisal 
waste as an economical admixture. Statistical assessment on 
compressive strength, flexural strength, and setting time has 
been conducted in order to investigate the effectiveness of SJE 
as an admixture. In addition, the utilization of the sisal waste 
will address the environmental pollution by making good use 
of sisal fiber waste material 

II. MATERIALS AND METHODS 

A. Materials 

1) Cement 

OPC class 53 conforming to KEBS SRN 103 was used in 
the production of the concrete for all mixes. 

2) Fine and Coarse Aggregates  

Natural river sand obtained from local suppliers was used 
as fine aggregates. Coarse aggregates originated from crushed 
stone type of nominal size of 10/20 mm. Their properties can 
be seen in Table I. 

3) Sisal Juice 

The SJ used for the experiment was obtained from sisal 
leaves harvested from a local single plantation to ensure the use 
of a single species. The juice was extracted by squeezing the 

leaves in a cleaned improvised machine that allowed collection 
in a container.  

TABLE I.  PROPERTIES O F FINE AND COARSE AGGREGATES 

Properties River sand Coarse aggregates 

Fineness modulus 2.70 4.82 

Silt content 0.5 - 

Specific gravity 2.48 2.50 

Water absorption (%) 2.1 3.10 

 

4) Water 

Water conforming to the requirements for concreting and 
curing as per IS: 456-20009 was used. 

B. Test Methods 

The preparation of specimens was done by measuring the 
required proportions of fine and coarse aggregates and cement 
and thereafter mixing was done in dry state before the addition 
of water and SJ. Water was mixed with different dosages of SJ 
before addition to the concrete mix. A homogenous mix was 
achieved through thorough mixing of the concrete ingredients. 
Two concrete mixes were produced. Mix "A" was produced 
without any addition of SJE while mix "B" had different 
dosages of SJE. Batched concrete mixes were prepared by 
replacement of 5%, 10%, 15%, 20%, 25% and 30% water with 
SJE in six sets as shown in Table II. 

TABLE II.  DETAILS OF MIX PROPORTIONS CLASS 25 CONCRETE 

 
Mix A 

(OPC) 

Mix B 

(OPC + SJ) 

Mix Set 1 2 3 4 5 6 7 

Dosage (%) 0 5 10 15 20 25 30 

TABLE III.  CONCRETE SPECIMEN DETAILS 

 

No. of cubes 

(specimen size: 

(150×150×150mm) 

No. of beams 

(specimen size: 

(150×150×530mm) 

Mix A 12 2 

Mix B 72 10 

 

1) Sisal Juice PH Test 

The PH value of the fresh SJ was tested in the laboratory 
using the universal PH scale. SJE was subjected to chemical 
analysis using XRF technology (X-Ray Florescence spectra 
analysis).  

2) Compressive Strength Test  

Concrete specimens were compacted into a detachable 
mould with dimensions of 150×150×150mm. The specimens 
were demoulded after 24 hours and were immersed in water to 
cure. A total of 84 cubes were cast, and they were cured for 7, 
14, 28, and 56 days. Compressive strength tests were 
conducted after the respective curing days. A compression 
machine was used in the laboratory, in accordance with BS EN 
12390. 

3) Flexural Strength Test  

The test was carried out to determine the strength of 
concrete according to BS EN: 12390-5: 2009. The specimens 



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for various SJ dosages were prepared and cast in moulds 
measuring 150×150×530mm and were cured for 28 days. A 
total of 12 beams were tested using the three point flexural test 
method. The beam specimens were placed between two 
supports in the universal testing machine and load was applied 
at the center until failure occurred.  

4) Setting Time of Cement Mortar 

The setting time of cement mortar made with replacement 
of water with SJ by 0%, 5%, 10%, 15%, 20%, 25% and 30% 
were obtained in accordance with BS EN 196-3:1995. 

III. RESULTS AND DISCUSSION 

A. Chemical Analysis of Sisal Juice Extract 

The fresh SJE was subjected to a litmus test giving a PH of 
5, which is acidic. The decrease in compressive strength of 
concrete cubes with increase in the quantity of SJE was caused 
by the fact that the components of concrete break down during 
contact with acid [18]. From the results in Table IV, it can be 
noted that the content of calcium oxide (CaO) is the most 
predominant element at 35% followed closely by potassium 
oxide (K2O). These two ingredients are also found in gypsum 
which is a mineral used for retarding the setting of cement 
during manufacture. Other elements found in both gypsum and 
SJE include magnesium oxide (MgO) and sulphur (S) [27, 28]. 

TABLE IV.  CHEMICAL COMPO SITION OF SISAL JUICE 

Element Percentage by Weight (%) 

Calcium oxide (CaO) 35.88 

Potassium oxide (K2O) 32.40 

Magnesium oxide (MgO) 13.74 

Aluminum oxide (AL2O3) 4.19 

Silicon dioxide (SiO2) 4.08 

Iron (Fe) 3.55 

Sulphur (S) 2.95 

Phosphorous pentoxide (P2O5) 1.48 

Chlorine (Cl) 1.00 

Zinc (Zn) 0.62 

Manganese (Mn 0.38 

Titanium (Ti) 0.23 

Strontium(Sr) 0.11 

 

B. Effects of SJE on Compressive Strength 

TABLE V.  EFFECT OF SISAL JUICE ON COMPRESSIVE STRENGTH 

Mean strength (N/mm) 

 
Percentage 

0% 5% 10% 15% 20% 25% 30% 

Days 

7 17.02 20.18 16.74 15.63 11.86 12.43 9.76 

14 22.10 24.87 20.85 19.55 17.29 14.97 11.92 

28 25.00 26.08 21.97 22.79 20.27 18.07 17.96 

56 28.90 30.47 25.03 23.38 21.21 19.53 18.69 

 
The test results in Table V indicate an increase in strength 

between control and cement with 5% of SJ but beyond 5%, the 
strength decreased steadily. The steady decrease in 
compressive strength can be attributed to the fact that SJE is 
acidic and an increase of SJE breaks down the components of 
concrete during contact as shown in [18]. The results in Figure 
1 point out a strength gain trend with 5% dosage attracting the 

highest compressive strength while 30% SJE gained the least 
strength at all ages. In Figure 2, the compressive strength 
difference between the control mix and 5% SJ dosage is 4.32%. 
The results show that there is a low rate of decrease in strength 
between 10% and 15% of SJ dosage but beyond 15% to 25% 
SJ, the rate increases. This result is in line with the results 
demonstrated in [23]. 

 
Fig. 1.  Strength of concrete at different ages. 

 
Fig. 2.  Effects of SJ dosage on concrete's strength. 

C. Flexural Strength Test 

The test was conducted in accordance with BS EN 
12390:2009 by using the three point load system. Beams, with 
a size of 150×150×550mm were used (Figure 3). 

 
Fig. 3.  Three point load system. 

The results for flexural strength of SJE concrete are plotted 
against various percentages of SJE dosage. In Figure 4, it can 
be seen that when SJE dosage is increased, a significant 
increase in flexural strength is obtained. The predominant 
increase in flexural strength is found at 20% SJE dosage. The 
percentage of increase in flexural strength is 18% compared to 
control concrete. There was a slight decrease in flexural 
strength at 25% and 30% dosage. 



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TABLE VI.  FLEX URAL STRENGTH TEST RESULTS  

 

 
Fig. 4.  Flexural strength of concrete at different SJ dosages. 

The outcomes demonstrated that beam flexural 
performance increased rapidly by the addition of SJ, up to 20% 
and then it decreased slightly which is in line with results 
presented in [29]. Furthermore, diagonal cracks were observed 
on all the beams, including the control. Ultimate collapse 
occurred by concrete crushing within the compression zone for 
all the beams. 

 

 
Fig. 5.  Ultimate collapse of a concrete beam. 

D. Comparison between Flexural and Compressive Strength 

Table VI shows the relationship between the flexural and 
the compressive strength of concrete with SJE.  

TABLE VII.  FLEX URAL AND COMPRESSIVE STREN GTH COMPARISON 
AT 28 DAYS 

Sisal dosage 

(%) 

Flexural strength 

(N/mm
2
) 

Compressive strength 

(N/mm
2
) 

0 4.3 25.00 

5 4.4 26.08 

10 4.6 21.97 

15 4.9 22.79 

20 5.1 20.27 

25 4.9 18.07 

30 4.5 17.96 

 

 
Fig. 6.  Comparison between flexural and compressive strength at different 

sisal dosages. 

Flexural strength must be between 10 to 20% of 
compressive strength depending on the type, size and volume 
of coarse aggregates used, see Table VIII.  

TABLE VIII.  ACCEPTABLE RAN GE OF FLEX URAL STRENGTH 

Sisal 

dosage 

(%) 

Flexural 

strength 

(N/mm
2
) 

Compressive 

strength 

(N/mm
2
) 

Acceptable 

range of flexural 

strength 

Remarks on the 

range of flexural 

strength 

0 4.3 25.00 2.2 to 4.4 Acceptable 

5 4.4 26.08 2.6 to 5.2 Acceptable 

10 4.6 21.97 2.3 to 4.4 Unacceptable 

15 4.9 22.79 2.3 to 4.6 Unacceptable 

20 5.1 20.27 2.0 to 4.1 Unacceptable 

25 4.9 18.07 1.8 to 3.6 Unacceptable 

30 4.5 17.96 1.8 to 3.6 Unacceptable 

 

High flexural strength is essential for stress-bearing 
restorations, when high pressure/stress is exerted on the 
material or restoration. From Table VIII, an increase of about 
4.32% in compressive strength is witnessed and a significant 
improvement in flexural toughness is observed in the case of 
replacing water by 5% SJE. The flexural strength of 4.4N/mm

2
 

falls within the required range of 10% to 20% of compressive 
strength. The appropriate SJ dosage for the production of SJE 
concrete was found to be 5%. The water replacement by SJE 
enhanced the flexural strength compared to control mix. 

E. Effects of SJE on Setting Time 

Figure 7 shows that both the initial setting time and the 
final setting time increased at an average of 14% and 23% 
respectively with increase in SJ dosage. According to Table IX, 
the initial setting time of the cement paste increased with 
increase in SJ dosage when compared to the reference value. 
The final setting time also increased exponentially with 
increase in replacement of water by SJE. This can be attributed 
to the adsorption of the retarding SJ on the surface of cement 

SJ 

dosage 
S/No 

Load 

(N) 

Flexural strength 

(N/mm
2
) 

Avg. 

0% 
Specimen 1 32.21 4.29 

4.3 
Specimen 2 32.40 4.32 

5% 
Specimen 1 33.00 4.40 

4.4 
Specimen 2 33.00 4.40 

10% 
Specimen 1 33.75 4.50 

4.6 
Specimen 2 34.88 4.65 

15% 
Specimen 1 36.00 4.80 

4.9 
Specimen 2 36.75 4.90 

20% 
Specimen 1 39.98 5.33 

5.1 
Specimen 2 36.98 4.93 

25% 
Specimen 1 37.95 5.06 

4.9 
Specimen 2 36.00 4.80 

30% 
Specimen 1 31.50 4.20 

4.5 
Specimen 2 36.00 4.80 



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particles, forming a protective skin which slows down the 
process of hydration hence the reason why there is a steady rise 
of setting time. The layer of retarding admixture around the 
cement particles acts as a diffusion barrier. Due to this 
diffusion barrier, it becomes difficult for the water molecules to 
reach the surface of the un-hydrated cement grains and hence 
the hydration slows down, and the dormant period (period of 
relatively inactivity) is lengthened and thus the paste remains 
plastic for a longer time. 

TABLE IX.  INITIAL AND FINAL SETTING TIMES OF CEMENT MORTAR 
WITH VARYING DOSAGES OF SISAL JUICE EXTRACT 

SJE dosage 

(%) 

Initial setting 

time (min) 

Percentage 

increase (%) 

Final setting 

time (tin) 

Percentage 

increase (%) 

0 179  334  

5 214 20 467 40 

10 234 31 521 56 

15 237 32 620 86 

20 242 35 893 167 

25 265 48 1767 429 

30 372 107 1840 451 

 

 
Fig. 7.  Effects of SJE on initial and final setting time. 

IV. CONCLUSIONS  

The following conclusions can be drawn from the 
experimental study: 

• SJE is acidic in nature and contain elements like calcium 
oxide (CaO) and potassium oxide (K2O) which are 
predominant in retarders.  

• Early compressive strength development is achieved at all 
ages with replacement of water by 5% SJE. 

• The gradual replacement of water by SJE dosage enhanced 
flexural strength. 

• The optimum water replacement by SJE that achieved high 
compressive strength and appropriate flexural strength is 
5%. 

• The replacement of water by SJE retarded the setting time 
of concrete. 

V. RECOMMENDATIONS 

The 22.79N/mm
2
 concrete strength achieved at 28 days for 

15% dosage can be used for low loading retaining wall with 
low surcharge. The 5% replacement of water by SJE concrete 
can be used to improve site capacity by increasing formwork 
rotation and also fasten construction time. 

It is hereby suggested that further work on SJE should be 
carried out at controlled conditions. It is also recommended that 
prior to the acceptance of SJE as a retarder, the properties of 
different species of sisal leaves need to be studied. 

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