International Journal of Engineering Materials and Manufacture (2017) 2(3) 58-66 
https://doi.org/10.26776/ijemm.02.03.2017.03 

 
A.H. Abdullah, D. Sujan  
CDT 250, Curtin University Malaysia 
98009 Miri, Sarawak, Malaysia 
E-mail: d.sujan@curtin.edu.my 
 
Reference: Abdullah, A.H., and Sujan, D. (2017). Mechanical Performance of Cockle Shell (CaCO3) Powder and Oil Palm Fibre 
Reinforced Epoxy Composites. International Journal of Engineering Materials and Manufacture, 2(3), 58-66. 

 
 

Mechanical Performance of Cockle Shell Particles (CSP) and Oil Palm Fibre 
(OPF) Reinforced Epoxy Composite 
 
 
Abdul Hamid Abdullah and Sujan Debnath 
 

 

Received: 15 August 2017 
Accepted: 13 September 2017 
Published: 15 September 2017 
Publisher: Deer Hill Publications 
© 2017 The Author(s) 
Creative Commons: CC BY 4.0 

 
 
ABSTRACT 
The effects of particle sizes (range 1, 2 and 3) and particle loading (5wt%, 10wt%, 15wt%, 20wt% and 25wt %) on 
the mechanical properties (tensile and flexural properties), water absorption properties and morphology analysis 
(optical microscope) of epoxy composites reinforced with cockle shell particles and hybrid epoxy based composite 
reinforced with cockle shell particles and oil palm fibres were investigated. Pre-chemical treatment of alkaline solution 
(NaOH) with 5% concentration was used to treat the oil palm fibre prior to the fabrication of composite. Based on 
the findings, the composite with smaller size and lower loading of cockle shell particle showed higher improvement 
in mechanical properties. Meanwhile, the hybrid epoxy based composite reinforced with smaller size of cockle shell 
particle and oil palm fibre showed enhancement in mechanical properties. For water absorption analysis, cockle shell 
particle-epoxy composites with lower particle loading showed less water uptake. 
 
Keywords: Cockle shell particle, oil palm fibre, epoxy composite 
 
 
1 INTRODUCTION 
There are various types of fibres and fillers that been used in the polymer composites such as glass, carbon, aramid, 
nylon, carbon black and silica etc. However, the movement towards environmentally sustainable engineering 
solutions has led to the rise of another class of composite material, commonly referred to as “green composites” that 
contain either naturally occurring and/or waste material as one of its component. The utilization of waste materials 
which are abundant and cheap, especially from clean resources, has become more popular nowadays. Seashell has 
been considered to be a good candidate to be used as a bio-filler for preparing polymer composites because it is 
inexpensive, abundant, environmental friendly and is a renewable resource. Moreover, it has very high content of 
calcium carbonate (CaCO3) plus organic matrix. Calcium carbonate (CaCO3) extracted from limestone, has been long 
been used as a filler in the plastic and rubber.  However, the mining and quarrying of limestone is not very sustainable 
in the long term compared to seashell which is renewable resource. Moreover, the quarrying of limestone is damaging 
the landscape, producing smoke and dust plus deteriorating the water quality. The large consumption of cockles 
generating a large volume of shell waste which contributes to the deterioration of environment as it needs to be 
disposed at the landfill site. Recycling of shell waste is very good way to reduce the garbage that need to be processed 
at the landfill site, and offers an opening to develop this waste material into useful products. The aim of this study is 
to investigate the effect of different cockle shell particle loading and size reinforced polymer composites and the 
hybrid polymer based composites reinforced cockle shell particle and oil palm fibre in term of mechanical, water 
absorption and morphology properties. 
 
2 METHODOLOGY 
2.1 Materials 
The cockle shells used were collected from restaurants, and the oil palm fibre is supplied by Sarawak Oil Palm 
Company. The cockle shell particles were extracted by grinding the shell using ball mill machine. While oil palm fibres 
were extracted from oil palm empty fruit bunch (OPEFB) through retting process. The epoxy resin was selected as 
matrix phase and hardener used as curing purposes from Miracon Sdn. Bhd was procured together.  
 



Mechanical Performance of Cockle Shell (CaCO3) Powder and Oil Palm Fibre Reinforced Epoxy Composites 

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2.2 Preparation of Cockle Shell Particles 
The cockle shell particles were separated in three ranges size depending on size of the particles. Three series of samples 
(epoxy reinforced by cockle shell particles) were prepared: 
• First series with 5, 10, 15, 20 and 25 wt% particles belonging to particles size (≥ 63 and < 212 (µm) range 1. 
• Second series with 5, 10, 15, 20 and 25 wt% particles belonging to particles size (≥ 212 and < 425 (µm) range 

2. 
• Third series with 5, 10, 15, 20 and 25 wt% particles belonging to particles size (≥ 425 and < 500 (µm) range 3. 
 
2.3 Fibre Treatment 
The oil palm fibres were treated with 5% concentration alkaline solution. Then, the fibres were immersed into 5% 
concentration of sodium hydroxide (NaOH) for 5 hours at room temperatures. Subsequently, the fibres were washed 
with distilled water until the pH 7 value was reached. Finally, the fibres were dried in an oven at 80 °C for 8 hours 
and then sealed in plastic bag. 
 
2.4 Fabrication of Composite  
Hand lay-up process was chosen in the fabrication of the composites. Prior to fabrication of Frekote 770-NC (release 
agent) was applied on the surface of the mould. The masses of 5 wt%, 10 wt%, 15 wt%, 20 wt% and 25 wt% of 
cockle shell particles was prepared and measured. The ratio of epoxy resin to hardener was 100:30 according to the 
manufacturer guidelines. Then the cockle shell particles was mixed with epoxy resin and stirred thoroughly for 5 
minutes until the filler was completely mixed with the resin by using scrap- rotate- scrap-mixing method. This method 
was to reduce the trapping of air bubbles. Next, was degasified using a vacuum chamber. After that, the mixture was 
poured into the mould and left for solidification. After solidification, composites were post–cured in an oven for 2 
hours at 80oC. For reference purpose, pure epoxy specimens were also fabricated. 
 

 
 

Figure 1: Hand lay- up technique [3] 
 
 
2.5 Mechanical Property Analysis 
The mechanical properties of the composites (tensile and flexural properties) were tested by using the universal testing 
machine. The tensile testing was conducted accordance to ASTM D638 while flexural testing was conducted 
accordance to ASTM D790. The crosshead speed was fixed at 5mm/min and 5 KN of load cell was applied until the 
specimen was failed. Five identical specimens of every sample were used for each test. 

 
2.6 Water Absorption Property Analysis 
The water absorption of composite specimen was conducted accordance to ASTM D570. The initial weight of three 
identical composite specimens for each sample was recorded before immersed in the distilled water. The composite 
specimens were taken out from the distilled water for every 24 hours to study the water absorption for each 
specimen.  
 
2.7 Morphology Analysis 
The morphological analysis of the fracture surface of cockle shell particles-epoxy composites and cockle shell/oil palm 
fibres-epoxy composites were conducted by an optical microscope. By means of this observation, it restricted the 
view to only observe the dispersion and agglomeration of particles and fibre pull out of the composite specimen 
after fracture and the weak matrix bonding can also be seen.  
 



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3 RESULTS AND DISCUSSION 
3.1 Mechanical Property  
Figure 2 and Figure 3 illustrated the tensile and flexural strength for the composites as a function of particle loading. 
It was observed that decrease in tensile and flexural strength with the increasing of particle loading for all three 
different particle sizes composites. One of the factors for poor mechanical properties at higher particle loading was 
due to the poor adhesion between the epoxy resin and particles. This poor adhesion increases with the increasing of 
particle loading. This poor adhesion would lead to inefficient of stress transfer at the particle filled epoxy interface, 
thus caused de-bonding to occur and generates stress concentration and affects the particles not able to carry any 
load, finally accelerates the specimen of the composite to break. Furthermore, the poor dispersion of cockle shell 
particles, presence of void or porosity and de-wetting of epoxy resin inside the composite specimens, decreased the 
tensile and flexural strength of composite at higher particle loading by generating stress concentration points which 
lead to a crack initiation spot under the applied stress [4]. Moreover, decrease in tensile and flexural strength was 
observed when the particle size increases. This was due to particles with smaller size have a higher total surface area, 
thus providing higher strength of particles filled epoxy composites, in other words, tensile and flexural strength 
increase with the increasing of surface area filled particles, so a more effective stress transfer from the epoxy resin to 
the particles are able to be achieved [5]. Besides, increasing in particle size caused the reduction of wettability between 
the adhesion of particles and epoxy resin. Thus, the effectiveness number of bonds between particles and epoxy resin 
would decrease. Consequently, the surface area of compatibility would decrease, thus the tensile and flexural strength 
decrease with increasing particle size [6]. As referring to figure 4 and figure 5, it was observed that tensile and flexural 
modulus increase linearly with the increasing of particle loading until an optimum was reached. The improvement 
can be indicated to good adhesion between the particles- matrix. 
 

 
Figure 2: Tensile strength versus various particles loading 

 
 

 
 

Figure 3: Flexural strength versus various particles loading 



Mechanical Performance of Cockle Shell (CaCO3) Powder and Oil Palm Fibre Reinforced Epoxy Composites 

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Figure 4: Tensile modulus versus various particles loading 

 
 
 

 
Figure 5: Flexural modulus versus various particles loading 

 
 
Figure 6 and figure 7 illustrated the effect tensile and flexural strength on the cockle shell particle/oil palm fibre hybrid 
epoxy composites. It was observed that the tensile strength of hybrid composite is inversely proportional to the 
cockle shell particle size. According to figure 6, the tensile strength of hybrid composites with particles size in range 1 
(33.83 MPa) and range 2 (28.03 MPa) showed an improvement of 35.3% and 21.9% respectively as compared to 
particles size in range 3 (21.88 MPa). In the figure 7, the flexural strength with improvement of 54.3% and 47.8% 
was observed at composites with particles size in range 1 (96.78 MPa) and range 2 (84.74 MPa) as compared to 
particles size in range 3 (44.21 MPa) respectively. Apart from that, it was also observed the flexural strength of hybrid 
composites were higher as compared to the cockle shell epoxy composites in range 1 and 2 respectively as shown in 
figure 7. For example, the flexural strength of hybrid composites in range 1 and 2 had increased 19% and 12% as 
compared to the cockle shell particles - epoxy composites in range 1 and 2 respectively. 
 



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Figure 6: Tensile Strength of epoxy composites 

 
 

 
Figure 7: Flexural strength of epoxy composites 

 
 

 
Figure 8: Tensile modulus of epoxy composites  



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Figure 9: Flexural modulus of epoxy composites 

 
 
 
The theory behind the tensile and flexural strength of hybrid composite were inversely proportional to the particle 
size were mainly due to the good interaction between the particle, fibre and matrix with the decreasing of particle 
size. According to the research by Packham, the quality of interface adhesion for fibre-reinforced composites plays 
an important character for the strength of particulate composites. The strength of interface adhesion determines the 
stress transfer between the mechanisms [7]. Furthermore, for well bonded particles composite, the applied stress is 
able to transfer sufficiently to the particles from the matrix, hence this improves the strength of composite [8]. Besides, 
the flexural modulus of hybrid composites with particle size in range 1 and 2 had increased 9.6% and 18% as 
compared to hybrid composites in range 3. As referring to figure 8, it showed that the tensile modulus of hybrid 
composite decrease with decreasing the size of cockle shell/oil palm fibre-epoxy composite. The reasons for decrease 
in strength and modulus were due to the poor interaction caused by the hydrophilic properties of particles and oil 
palm fibres (some waxy substances, natural fats and impurities were still entrapped on the surface of oil palm fibres 
after chemical treatment) and the hydrophobic properties of epoxy resin. This poor interaction resulted in debonding 
of filler and fibres from the matrix. The increase in flexural modulus as shown in figure 9 can be attributed to good 
interfacial adhesion between constituents of the composite [9]. 
 
3.2 Water Absorption Property 
Figure 10, figure 11 and figure 12 showed the effect of particle size on the percentage of water absorption for the 
epoxy composites. It was observed that the percentage of water absorption of composites increased constantly with 
the increasing of immersed time and particle loading for all three different particle sizes. After few days of immersion, 
“white layer substance” was observed on the top of water surface. The white layer substance became thicker and the 
void became clearer on the surface of the composites with the increased of immersion time. This was due to the 
loosing of resin after the long immersion of time, with the loosing of resin which could lead to larger interfacial area 
between the particle and matrix, hence caused the increasing of water absorption [10]. Besides, high percentage water 
absorption of composites was due to the hydrophilic nature of natural filler. One of the reasons for higher water 
absorption at higher particle loading was due to the increasing formation of agglomerations causes by the difficulties 
of obtaining a homogeneous dispersion of particle within the matrix. The agglomeration of particles could lead to 
the trapping of air bubbles in the composite. Thus, the capacity of water absorption increases at higher particle 
loading. By comparing to the figure 10, figure 11 and figure 12, it shows that the composite with particle size in range 
1 (smallest particle size in this research) had higher percentage of water absorption than the particle size in range 2 
composite and 3 composite. This happened because smaller particle size has higher total surface area which leads to 
increase of water uptake. 
 



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Figure 10: Water absorption versus square root of hours (≥ 63 and < 212 (µm) 

 
 

 
Figure 11: Water absorption versus square root of hours (≥ 212 and < 425 (µm) 

 
 

 
Figure 12: Water absorption versus square root of hours (≥ 425 and < 500 (µm)   



Mechanical Performance of Cockle Shell (CaCO3) Powder and Oil Palm Fibre Reinforced Epoxy Composites 

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3.3 Morphology Property 
Referring to Figure 13(a), it can be observed that the cockle shell particle-epoxy composite with size in range 1 (≥
62 and < 212 (µm) had good dispersion of particles, as it also can be seen that the particles was surrounded by epoxy 
resin. This indicating good dispersion of particles filled epoxy resin in the composite, thus resulting in good particle-
matrix adhesion. As referring to figure 13(b), the cockle shell particle-epoxy composite with size in range 3 (≥
425 and < 500 (µm) experienced agglomeration between the particles in the composite, this represent poor interface 
adhesion between the particle and matrix, thus lead to debonding of particle in this composite. In Figure 14, it can 
observe that the oil palm fibre reinforced epoxy composite experienced fibre pull out. Moreover, it also showed that 
the oil palm fibre composite experienced poor distribution of fibre and the present of void in the composite thus 
caused debonding to occur and finally leads to decrease in mechanical properties. 
 
 

      
 

Figure 13: Optical microscope image of cockle shell particle epoxy composite with size in (a) Range 1 (≥ 62 and <
212 µm), and (b) Range 3 (≥ 425 and < 500 µm) 

 
 
 

 
 

Figure 14: Optical microscope of cockle shell particle and oil palm fibre reinforced epoxy composite 
 
 
 
4 CONCLUSIONS 
The summary is as follows: 

• The results show a major improvement in mechanical properties with the decreasing of particle size and 
particle loading.  

• The young’s modulus of cockle shell particle-epoxy composite was observed to be increased with increasing 
particle loading. 

• For hybrid composite, it was observed that the tensile and flexural strength increase with decreasing particle 
size.  

• Morphology analysis showed that smaller size of cockle shell particles composite had good dispersion of 
particle compared to larger size of particles.  

• The strength of composites is strongly affected by the particle size and loading. 
  



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ACKNOWLEDGEMENT 
The researchers would like to thank the Curtin University Sarawak for providing the research grant (CSRF) that has 
made this work possible 
 
 
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