J. Build. Mater. Struct. (2020) 7: 255-261 Original Article  
DOI : 10.34118/jbms.v7i2.775  

 

ISSN  2353-0057, EISSN : 2600-6936 

Experimental Investigation of the Effect of Sisal Fiber on the Partially 
Replaced Cement with Groundnut Shell Ash in Concrete 

Sani J E*, Afolayan J O, Wilson U N, Eze OC, Nyeri J 

 

 
Abstract.  An investigation on the effect of sisal fiber on the partially replaced cement with 
Groundnut Shell Ash in Concrete was carried out. Sisal fiber of 3.5cm length which forms 1% 
of the mix by weight with groundnut shell ash as a partial replacement for cement was used 
in preparing the concrete specimen. Compressive strength test was carried out using 0%, 
5%, 10%, 15%, 20%, 25% and 30% of Groundnut shell ash as replacement of cement at 
different curing ages of 7, 14, 21 and 28 days. It was observed that at 7 and 14days of curing, 
it is needless introducing the GSA since the maximum compressive strength obtained were at 
0% GSA. At 21 and 28days of curing, a considerable increase in compressive strength was 
observed for 5% and 10% of GSA. However, 5% of GSA can be regarded as the optimum 
content since it gives the maximum compressive strength value of 30.1N/mm2 at 28days of 
curing. This is followed by 10% replacement of GSA yielding 28.10N/mm2 and then 0% GSA 
replacement yielding 25.01N/mm2. 

Key words: Sisal fiber, Groundnut shell ash (GSA), Compressive strength, Curing ages, Concrete. 

1. Introduction 

The use of cement for construction in developing countries cannot be overemphasized. Also, the 
incessant increase in the price of Portland cement is attributable to possible overwhelming rate 
of demand in the construction industries. This has consequently compelled researchers to 
search for total or partial alternative building materials among several pozzolanic materials. 
Buari  et al., (2013) describes groundnut shell ash (GSA) as a good pozzolanic material which 
reacts with calcium hydroxide forming calcium silicate hydrate. The specific gravity of the GSA 
was found to be less than that of the Ordinary Portland Cement (OPC) it replaced, this means 
that a considerable greater volume of cementitious materials will result from mass replacement 
of the OPC with the GSA. The investigation also showed that the compressive strength value of 
the GSA-OPC blended concrete at 10% replacement level performed better and would be 
acceptable and considered as a good development for construction of masonry walls and mass 
foundations in low cost housing in Nigeria. Olutoge et al., (2013) investigated the Characteristics 
Strength and durability of GSA blended with cement concrete in Sulphate Environments.  From 
the result of the tests and analysis carried out, it was deduced that the Groundnut Shell Ash 
blended with cement concrete has a proven resistance to magnesium sulphate, sodium sulphate 
and calcium sulphate media and would exhibit a better performance in soils containing these 
media (MgSO4, Na2SO4, CaSO4.). It was also observed that there was a decrease in slump value 
with increase in GSA replacement which is reflective of the fact that GSA can reduce the 
consistency and ultimately, the workability of concrete. Alabadan et al., (2006) having used 
higher percentage of GSA reported that there is a decrease in the compressive strength of 
concrete produced as the percentages of GSA increases resulting in maximum strength of 
16N/mm2   at 28 day of curing for 70%/30% replacement. Likewise, Mujedu. and Adebara 
(2016) also carried out the experimental investigation using GSA as partial replacement in 
concrete varying the percentage from 0% to 75%, at intervals of 15%. The results presented 
showed that 15% GSA replacement produced concrete of 20.10N/mm2 compressive strength at 
28 days of curing. Similarly, Ikumapayi (2018) worked on GSA as partial replacement of cement 

      Department of Civil Engineering, Nigerian Defence Academy, Kaduna, Nigeria. 
* Corresponding Author: jesani@nda.edu.ng  

Received: 25-08-2020 
 

 Accepted: 05-12-2020 

mailto:jesani@nda.edu.ng


256 Sani et al., J. Build. Mater. Struct. (2020) 7: 255-261  

 

 

in concrete using lower percentage of replacement from 0% to 16%. He reported that 4% 
replacement produced 16N/mm2  strength of concrete after 28days of curing. 

It is important to mention that the limitations inherent in concrete as a building material for 
example, being poor or weak in tension, is also a reason for the litany of researches for how else 
it can be improved other the use of steel rods to reinforce it or complement its tensile strength. 
Many researches have been carried out in order to investigate the effect of addition of fibers on 
many strength properties of concrete such as tensile strength, compressive strength and flexural 
strength. Researches into the types of fibers to be used in concrete applications have been 
intensified since the 1950s alongside researches on the improvement of the composite materials 
technologies. Various types of fiber materials such as steel, carbon, glass, plastic, polypropylene, 
nylon, and cotton were tested. From the results of these researches, American Concrete 
Institute’s (ACI) Committee 544 (2002) classified fiber reinforced concrete into four groups 
based on the fiber materials: steel fiber reinforced Concrete (SFRC), glass fiber reinforced 
concrete (GFRC), synthetic fiber reinforced concrete (SNFRC), and natural fiber reinforced 
concrete (NFRC). Synthetic fibers such as polyester, acrylic, polyethylene and polypropylene are 
further subdivided into micro- synthetic fibers (for diameter less than 0.30 mm) and macro-
synthetic fibers (for diameter greater than 0.30 mm). Glass and natural fibers show vulnerability 
to temperature variation and environmental conditions, respectively, leaving steel and synthetic 
fibers as the most viable concrete reinforcement options. The focus of this experimental 
investigation is to establish the effect of sisal fibre on the properties of harden concrete partially 
replaced with groundnut shell ash. Having taking into consideration the experimental results of 
other researchers using GSA as partial replacement of cement in concrete without addition of 
Sisal fibre. 

2. Materials and methods 

2.1. Materials used for the experiment 

The major materials used for this research work include the following fine aggregate, coarse 
aggregate, cement, sisal fiber, ground nut shell ash and clean water. 

2.1.1. Fine aggregate 

Fine aggregate sample was obtained from tipper garage at Sabon Yelwa Chikun LGA Kaduna, 
Kaduna State. It free from silt and debris that can inhibit the strength development of concrete. 
The coefficient of absorption of the fine aggregate used was 1% and the fineness value was 2.2 
which indicate that it good for concrete since is not up to 3.2 value which is not suitable for 
concrete material. The maximum size of the fine aggregate is sizes less than 4.75mm. 

2.1.2. Coarse aggregate 

Crushed granite gravel having the minimum size of 7mm and maximum size of 12mm was 
chosen as the coarse aggregates, sample is obtained from tipper garage at Sabon Yelwa Chikun 
LGA Kaduna, Kaduna State. 

2.1.3. Cement 

Ordinary Portland cement of 53grade (ASTM C150 type I (2020)) with specific gravity of 3.25 
was used for preparing the concrete mix. The cement used have the fineness of 3.65% which is 
below the value of 10% as specified by BS 4550: Part 3 (1978) which stated that percentage of 
cement sample retained on 45, 90 band 300 micro meters sieve should not exceed 10%. 



 Sani et al., J. Build. Mater. Struct. (2020) 7: 255-261 257 

 

 

2.1.4. Sisal fibre 

Sisal fiber sample was obtained from Tudun Wada market, Kaduna south LGA Kaduna, Kaduna 
State. 

It was cut into 4cm length. The sample of the sisal fibre used in this study is presented in Figure 
1. The results of the research work carried out by Sani et al., (2017) on the properties of sisal 
fibre was adopted for this investigation as presented in Table 1. 

 

Fig. 1. Sample of Sisal fibre. 

Table 1. Properties of the sisal fibre, (Sani et al., (2017)) 

Property Quantity 

Natural humidity % 14.48 
Average diameter, mm 0.13 
Water absorption, % 340 

Specific gravity 0.22 
Tensile Strength of 1 strand N/mm2 10.60 
Tensile strength of 2 strands N/mm2 24.45 
Tensile strength of 3 strands N/mm2 30.60 

Elongation at break, mm 5.58 
Colour Shiny white 

2.1.5. Groundnut shell 

Groundnut shell sample is obtained from Television market Kaduna south LGA Kaduna, Kaduna 
State. The groundnut shell was sun dried and put in the open drum and burnt in ashes. This was 
grinded and sieved with 25mm micro sieve. The sample of groundnut shell burnt to obtain the 
ash is shown in Figure 2 and the chemical composition of the groundnut shell ash (GSA) is as 
shown in Table 2 and it has the fineness of 7.8%.  

Table 2. Chemical Composition of Groundnut Shell Ash (GSA) 

Oxide Percentage Composition OPC (BS 12 Ranges) 

SiO2 24.32 17- 25 
Al2O3 5.31 3- 8 
Fe2O3 1.01 0.5- 6.0 
CaO 8.93 60- 67 
MgO 5.34 0.1- 4.0 

 



258 Sani et al., J. Build. Mater. Struct. (2020) 7: 255-261  

 

 

 

Fig. 2. Sample of Groundnut shell 

2.2. Methods 

The mix proportion of 1:2:3 was adopted using a mould size of 100x100x100mm. The mix 
proportion by mass constituted 3.63kg of cement, 7.27kg of fine aggregate (sand) and 11.76kg of 
coarse aggregate with a water-cement ratio of 0.65. Adequate mixing was done  in order to 
produce a cement mortar of homogenous consistency as seen in Figure 3. The concrete was first 
cast with 0% GSA, this is to serve as a control. Groundnut shell ash was then introduced as 
partial replacement of cement using 5%, 10%, 15%, 20%, 25% and 30% with sisal fiber of 3.5cm 
length subsequently introduced of up to 1% of the concrete cube.  A thin film petroleum jelly 
was used to the clean mould and also the contact surfaces of the bottom of the mould. After 
placing the concrete in the mould, the concrete was compacted using a rammer or tampering rod 
for 25 blows in 3 different layers. The cast cube in the mould was covered with an impervious 
sheet and allowed to set at room temperature for 24 hours. The concrete cube was removed 
from the mould, marked for identification and immersed in clean water for curing. The concrete 
cubes were tested at 7days, 14days, 21days and 28days of curing without fiber and 0% of GSA 
content to serve as control. Other concrete specimen were prepared containing 1% Sisal fiber as 
recommended by Sani et al., (2019) of average 3.5cm length being added and the cement content 
being replaced partially with groundnut shell ash at 5%, 10%, 15%, 20%, 25% and 30% . The 
cubes were then tested at 7days, 14days, 21days and 28days of curing. A slump test was also 
carried out for all the varied proportions containing GSA replaced with cement. 

  

Fig. 3. Some procedures in the Experiment 

 



 Sani et al., J. Build. Mater. Struct. (2020) 7: 255-261 259 

 

 

2.2.1. Statistical analysis 

Statistical analysis was carried out on results obtained using analysis of variance (ANOVA) with 
the Microsoft Excel Analysis Tool Pak Software Package to determine the levels of significance of 
the effect of sisal fiber on partially replace Cement with groundnut shell ash in concrete. 

3. Results and discussion 

From the slump test carried out, the following results can be observed as seen in Figure 4. From 
the relationship between the percentage groundnut shell ash and the slump value, it can be 
deduced that the increase in the groundnut shell ash reduces the consistency and ultimately the 
workability of the concrete produced. This is traceable to the fact that increase in percentage 
addition of GSA requires higher water /cement ratio to produce a workable concrete without 
adding any water reducing agent. 

 

Fig. 4. Relationship between Slump value and the GSA percentages 

It was observed that the inclusion of groundnut shell ash and sisal fiber in a concrete increased 
the compressive strength of concrete and the highest value of compressive strength was 
obtained at 5% replacement of GSA in a sisal fiber-reinforced-concrete as seen in Figure 5. 
Significant increase in the compressive strength is recorded in 21 and 28 days of curing whose 
peaks are at 5% replacement in fiber reinforced concrete. This is different from other research 
findings whose assertion that 10% replacement level performs better and would be acceptable 
and considered as a good development for construction of masonry walls and mass foundations 
in low cost housing in Nigeria. The 5% optimal replacement arrived at in this research is 
apparently owing to the sisal fibre introduced. 

Two-way analysis of variance (ANOVA) 

Two way analysis of variance tests was carried out to determine the level of significance of the 
effect of sisal fiber on partially replace Cement with groundnut shell ash in concrete and also the 
level of significance of the influence of curing age(days) on the compressive strength of the 
concrete. Table 3 shows the result of the two way analysis of variance. The two-way analysis of 
variance (ANOVA) for compressive strength of GSA replaced cement cured at different curing 
age (see Table 3) shows that the effect of GSA and curing period (days) on the compressive 
strength of concrete were statistically significant (FCAL = 31.06699> FCRIT = 2.661305) for GSA 

0

10

20

30

40

50

0 5 10 15 20 25 30

S
lu

m
p

 V
a

lu
e

 

GSA Content (%) 



260 Sani et al., J. Build. Mater. Struct. (2020) 7: 255-261  

 

 

replaced cement and (FCAL = 129.459> FCRIT =3.159908) for curing age (days). The effect of 
curing age (days) was more pronounced than that of GSA replace cement. 

 

Fig. 5. Compressive Strength- Concrete Age Relation 

Table 3. Two-way analysis of variance results for compressive strength of GSA replaced cement at different 
curing age (days). 

 

SUMMARY Count Sum Average Variance 

 

0% GSA 4 83.99 20.9975 14.96602 
5% GSA 4 92.02 23.005 45.57903 

10% GSA 4 82.78 20.695 47.03663 
15% GSA 4 72.18 18.045 36.33097 

20% GSA 4 65.28 16.32 41.66947 
25% GSA 4 57.61 14.4025 28.61603 
30% GSA 4 52.11 13.0275 23.45023 

  

 

7 Days 7 84.8 12.11429 9.504662 
14 Days 7 101.2 14.45714 17.93752 
21 Days 7 151.38 21.62571 12.50953 
28 Days 7 168.59 24.08429 19.8152 

ANOVA 

Source of Variation SS df MS F P-value F crit 
GSA 327.0224 6 54.50373 31.06699 1.49E-08 2.661305 

Curing Days 681.366 3 227.122 129.459 2.27E-12 3.159908 
Error 31.57909 18 1.754394 

   Total 1039.967 27 
    

4. Conclusion and Recommendation 

From the results of the study, it can be concluded that Groundnut Shell Ash used as partial 
replacement for cement with 1% of sisal fiber can significantly increase the compressive 
strength of a concrete. The compressive strength obtained between 5%, 10% and 15% at 21 and 
28 days of curing are satisfactory however, 5% replacement of cement with GSA yields the 
highest compressive strength value and can hence be regarded as the optimal GSA content 
required for a sisal-reinforced-concrete. The strength at 10 - 15% groundnut shell ash 
replacement at 28 days of curing satisfies BS 4550 Part 3 section 3.4 requirements hence, the 
use of sisal fiber of up to 1 % of the weight of concrete and 10% - 15% of replaced cement with 



 Sani et al., J. Build. Mater. Struct. (2020) 7: 255-261 261 

 

 

GSA at 28 days of curing provides compressive strength that is adequate and therefore can be 
recommended for mass concrete production. 

5. References 

ACI Committee 544 (2002). Design considerations for steel Fiber Reinforced Concrete, ACI 544.4R-88. 
American Concrete Institute, ACI Farmington Hills  

Alabadan, B. A., Njoku, C. F., & Yusuf, M. O. (2006). The potentials of groundnut shell ash as concrete 
admixture. Agricultural Engineering International: CIGR Journal. Manuscript BC 05 012, Vol. VIII. 

ASTM C150: (2020). Standard Specification for Portland cement, American Society for Testing and 
Materials. 

BS 4550 Part 3 (1978): Method of testing cement, British Standard Institution, Milton Keynes, London. 

Buari, T. A., Ademola, S. A., & Ayegbokiki, S. T. (2013). Characteristics Strength of groundnut shell ash 
(GSA) and Ordinary Portland cement (OPC) blended Concrete in Nigeria. IOSR Journal of Engineering 
(IOSRJEN), 3(7), 1-7. 

Ikumapayi, C. M. (2018). Properties of groundnut shell (Arachis hypogaea) ash blended Portland cement. 
Journal of Applied Sciences and Environmental Management, 22(10), 1553-1556. 

Mujedu, K. A., & Adebara, S. A. (2016). The Use of Groundnut Shell Ash as a Partial Replacement for 
Cement in Concrete Production''. International Journal of Sciences, Engineering and Environmental 
Technology (IJOSEET), 1(3), 32-39. 

Olutoge, F. A., Buari, T. A., & Adeleke, J. S. (2013). Characteristics strength and durability of groundnut 
shell ash (GSA) blended cement concrete in sulphate environment. International Journal of Scientific 
and Engineering, 4(7), 2122-2134. 

Sani, J. E., Afolayan, J. O., Chukwujama, I. A., & Yohanna, P. (2017). Effects of wood saw dust ash admixed 
with treated sisal fibre on the geotechnical properties of lateritic soil. Leonardo Electronic Journal of 
Practices and Technologies, (31), 59-76. 

Sani, J. E., Hadiza, A. and Rintong, I. B. (2019). Effect of Inclusion of Randomly Oriented Jute Fibre 
Reinforcement on the Compressive Strength of Concrete. Nigerian Building and Road Research 
Institute International Conference Series.  Theme: Construction Practices in Nigeria: Issues, 
Prospects & Solutions 2 – 4 July, NAF Conference Centre, Kado, Abuja, Nigeria, Book of Abstracts, p. 
37.