Acta Polytechnica


doi:10.14311/AP.2018.58.0195
Acta Polytechnica 58(3):195–200, 2018 © Czech Technical University in Prague, 2018

available online at http://ojs.cvut.cz/ojs/index.php/ap

CHARACTERIZATION OF RECYCLED LINEAR DENSITY
POLYETHYLENE/IMPERATA CYLINDRICA

PARTICULATE COMPOSITES

Olusola Femi Olusunmadea, ∗, Sunday Zechariahb,
Taofeek Ayotunde Yusufa

a Department of Mechanical Engineering, University of Agriculture, Makurdi, PMB 2373, Makurdi, Nigeria
b Department of Mechanical Engineering, Federal Polytechnic, Mubi, Nigeria
∗ corresponding author: olusunmadeolusola@yahoo.com

Abstract. Water-sachets made from low density polyethylene (LDPE) form a bulk of plastic
wastes which creates environmental challenges, while certain species of plants like Imperata cylindrica
constitute large portion of weeds on farm lands. As a technological approach to the reduction and
utilization of these materials, composites of Imperata cylindrica (IC) particulate and synthetic polymer
(from recycled waste water-sachets) were produced and evaluated for several mechanical and physical
properties. The production of the composites and testing were done using the standard methods
available in the literature. The results showed an increase in tensile modulus, hardness, impact strength,
and water absorption of the composite in comparison with unreinforced polymer, as the IC particulate
loading increased from 5 wt% to 30 wt%. However, there was a decrease in tensile strength, percentage
elongation at break and density of the composite as the particulate loading increased from 5 wt% to
30 wt%. The combination of the recycled waste water-sachets and IC particulate is really promising
for composites development. This creates opportunities to reduce LDPE wastes and add economic
importance to an otherwise agricultural menace. It will mean creating an economic value from “wastes”.

Keywords: mechanical properties; physical properties; Imperata Cylindrica (IC); particulate; waste
water-sachets; composites and recycled linear low density polyethylene (RLDPE).

1. Introduction
The development of composite materials, particularly
natural fibre composites, has become increasingly pop-
ular. The volume and number of applications of com-
posite materials have grown steadily, reaching to and
conquering new markets. According to a market re-
port published by Lucintel [1], the future of natural
fibre composites market looks attractive with oppor-
tunities in the automotive as well as building and
construction industries. Modern composite materials
constitute a significant proportion of the engineered
materials market ranging from everyday products to
sophisticated applications. The efforts to produce eco-
nomically attractive composite components have re-
sulted in several innovative manufacturing techniques
currently being used in the composites industry [2].
These composite materials are sometimes produced
using waste resources. The fact that natural resources
are ever depleting calls for more responsible and ef-
ficient use of the available scarce resources. Besides,
creating products from “waste” will really add value
and help with environmental challenges posed by the
enormous waste being generated. In many countries
in Africa, potable water is being packed with sachets
made from linear density polyethylene (LDPE). This
has really become a big business in many cities. As
a result of increasing demand for the packed water,
there has been a rise in the amount of waste water-

sachets generated. These empty sachets often end
up thrown away on the streets creating large amount
of non-biodegradable waste. Responsible utilization
of these wastes will really be an advantage. The
water-sachets clog mini-water ways, thereby creating
a perfect breeding habitat for mosquitoes that are
responsible for spreading malaria parasite, which is a
major cause of illness on the African continent. Even-
tually, the water-sachets find their way to larger bodies
of water such as oceans and seas and pose a serious
threat to aquatic life, as these wastes can be around
for many years because of their non-biodegradable
nature. However, if the water-sachets are burnt, the
emissions from the burning process severely pollutes
the air and also contribute to the greenhouse effect,
which is responsible for the global warming that the
earth currently experiences as a result of the depleting
ozone layer. There is, therefore, a need for a respon-
sible handling of these wastes. One of such efforts
targeted at utilizing the waste water-sachets is by
incorporating natural fibres into them to produce a
usable composite materials. Natural fibres could serve
as viable and abundant alternatives to the expensive
and non-renewable synthetic fibres as reinforcement
in thermoplastic composites. These types of fibres
present many advantages compared to synthetic fibres,
such as low tool wear, low density, cheaper cost, avail-
ability and biodegradability [3, 4]. One of such natural

195

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O. F. Olusunmade, S. Zechariah, T. A. Yusuf Acta Polytechnica
Supplementary Materials 

 

 

Figure 1: Ground IC 

 

 

 Figure 2: Waste Water-Sachets 

Figure 1. Ground IC.

fibres is Imperata cylindrica. It is an aggressive and
difficult weed to control due to its short growth cycle.
It is abundant, yet unsuitable for grazing animals and
lacks a good commercial value [5]. When fully mature,
its overall nutrient decline and its sharp pointed seeds
and tangled awns may injure animals and humans [6].
They also act as a host for pathogens that affect the
yield of some food crops [7]. However, Imperata cylin-
drica possesses good stiffness properties, which, if
incorporated in a matrix, can enhance the composite
rigidity. Hence, Imperata cylindrica is proposed as a
fibre reinforcement for recycled water-sachets to pro-
duce a thermoplastic composite, thereby increasing
its economic importance and reduce the environmen-
tal challenges posed by improper handling of waste
water-sachets. This study, therefore, examined some
mechanical and physical properties of recycled water-
sachets/Imperata cylindrica particulate composite to
determine its viability for engineering applications.

2. Materials and method
The part of the Imperata cylindrica (IC) that was
used for this study is the stem and they were obtained
from Pilla village in Makurdi area of Benue State. The
waste water-sachets were gathered from the campus of
the University of Agriculture Makurdi, Benue State.

2.1. Polymer and fibre processing
The Imperata cylindrica stems were harvested and sun-
dried for two weeks. Subsequently, the finer strands of
the stems were handpicked and ground (see Figure 1).
The grounded particles were then filtered through a
sieve of a pore size of 300 microns. The waste water-
sachets (see Figure 2) were thoroughly washed, dried
and pulverized at Goshen Plastics Industry, Makurdi
(see Figure 3). These pulverized waste water-sachets
will be referred to as recycled low density polyethylene
(RLDPE) henceforth.

2.2. Composite preparation
The IC particulate and the RLDPE were weighed
to get the required weight using an electronic weigh-
ing balance (Ohaus Adventurer Pro Analytical bal-

Supplementary Materials 

 

 

Figure 1: Ground IC 

 

 

 Figure 2: Waste Water-Sachets Figure 2. Waste Water-Sachets.
 

 

Figure 3: Pulverized Water-Sachets 

 

 

 

 

 

 

 

 

 

 

 

Figure 4: Compression of mold and content 

 

 

 

 

Figure 3. Pulverized Water-Sachets.

ance). The IC particulate and the recycled polymer
were mixed such that the particulate weight ratio in
the matrix varied from 5 wt% to 30 wt% in steps of
5 wt%. The mould was preheated at 100 °C. Half of
the RLDPE was added to the mould because the cav-
ity of the mould could not accommodate the whole
mass of the RLDPE in an un-melted state. After one
minute, the IC particulate was added to the mould
and after that, the other half of the RLDPE was also
added. The combined IC particulate and RLDPE
were then heated in the Aluminium mould at a tem-
perature of 150 °C for 15 minutes, during which the
RLDPE showed a reasonable fluidity and the blend
was thoroughly mixed to ensure homogeneity. The
heating continued for another 5 minutes after which
the mould was removed from the heat source and com-
pressed using a 5tonnes hydraulic jack (see Figure 4).
It was then allowed to cool at a room temperature un-
til the composite took the shape of the mould cavity,
after which the composite sheet (295 × 210 × 5 mm)
was removed from the mould. Heating was carried
out using a QASA (QSG-505G) gas cooker.

2.3. Composite characterization
The IC particulate-reinforced plastic sheet was re-
trieved from the mould and cut into test specimens.
Characterization of the composites was achieved by
mechanical testing. Some physical properties of the
materials were also examined.

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vol. 58 no. 3/2018 Characterization of Recycled Particulate Composites

 

 

Figure 3: Pulverized Water-Sachets 

 

 

 

 

 

 

 

 

 

 

 

Figure 4: Compression of mold and content 

 

 

 

 

Figure 4. Compression of the mould and content.

2.3.1. Mechanical properties
Tensile test was carried out using the Instron 3369
(Universal Testing Machine) according to ASTM D
638, to determine the tensile strength, tensile modu-
lus, and elongation at break of the materials. The test
specimen had a dumb-bell shape with a gauge length
of 30 mm, grip width of 15 mm and thickness of 5 mm.
Specimens were placed in the grips of the universal
tester and pulled at a crosshead speed of 5 mm/min
until failure. The hardness of the materials was mea-
sured using a Computerized Micro-Vickers Hardness
Tester (MV-1 PC) with a load of 300g according to
ASTM E 384, which is a standard test method for
Vickers hardness testing of materials. The Vickers
indenter produces a geometrically similar indentation
at all test forces. The dimension of the hardness spec-
imens is 40 × 40 × 5 mm. The Charpy impact test was
carried out to determine the impact strength of the
composites according to ASTM D 6110, which is used
to determine the resistance of plastics to a breakage
by flexural shock produced by a pendulum type ham-
mer. The dimension of the impact test specimens was
100 × 10 × 5 mm. Three specimens from each of the
materials were used for each of the tests.

2.3.2. Physical properties
Water absorption test according to ASTM D-570 was
also carried out to determine the water absorption
characteristic of the composite. Three samples from
each of the materials, with dimensions 42 × 12 × 5 mm,
were cut, cleaned and weighed before immersion in
distilled water at a room temperature. The speci-
mens were removed from the water after 24 hours
and the surfaces wiped off and weighed. The differ-
ence between the weight before and after immersion
was noted. The water absorption was then calculated
using

A =
M2 − M1

M1
· 100 %, (1)

where M1 is the initial mass in grams and M2 is the
final mass in grams.

 
 

Figure 5: Tensile strength at varying IC particulate loading 

 

 

 

 

 

 

 

 

 

 

 

 

0

2

4

6

8

10

12

0 5 10 15 20 25 30

T
e
n

si
le

 S
tr

e
n

g
th

 (
M

P
a
)

IC Particulate Loading (wt%)

Figure 5. Tensile strength at varying IC particulate
loading.

The density of the composite was also determined
by comparing the mass of a given specimen with its
volume:

density (%) =
mass (m)
volume (v)

. (2)

The dimensions of the specimens used to determine
the density was 50 × 50 × 5 mm.

3. Results and discussion
3.1. Mechanical properties
3.1.1. Tensile strength
Figure 5 illustrates the average tensile strength of the
composite produced at different IC particulate load-
ings as compared to the RLDPE. It showed that the
RLDPE has an average tensile strength of 10.86MPa.
It was observed that there was a decrease of 16.48 %
to 34.07 % in the average tensile strength of the com-
posite as the IC particulate loading increased from
5 wt% to 30 wt% compared to the RLDPE. Though,
there was an increment of 6.39 % in the average ten-
sile strength of the composite for particulate loading
from 5 wt% to 15 wt%. The maximum average tensile
strength of the composite is nevertheless still lower
compared to that of the RLDPE. The decrease is
due to the poor interfacial adhesion between the hy-
drophobic RLDPE and hydrophilic IC particulate.
The Scanning Electron Microscope micrographs (see
Figures 6 and 7) showed that while the IC particulates
were fairly evenly distributed within the matrix, the
agglomeration of the particulate observed, however,
indicates a weak interfacial bonding. Poor interfacial
adhesion acts as a stress concentration point upon an
application of external forces leading to a premature
failure due to a poor stress transfer from matrix to
the fibre particulate. Higher tensile strength demon-
strated by the neat RLDPE is due to the flexibility
and plasticity of the RLDPE [3].

3.1.2. Tensile modulus
Figure 8 illustrates the average tensile modulus of
the composite produced at different particulate load-

197



O. F. Olusunmade, S. Zechariah, T. A. Yusuf Acta Polytechnica

 
 

Figure 6: SEM Micrograph at 20 wt% IC Particulate Loading 

 

 

                       
 

   Figure 7: SEM Micrographs at 30 wt% IC Particulate Loading 

 

Particles 

Polymer 

Matrix 

Agglomeration of 

particulates 

Figure 6. SEM Micrograph at 20 wt% IC Particulate
Loading.

 
 

Figure 6: SEM Micrograph at 20 wt% IC Particulate Loading 

 

 

                       
 

   Figure 7: SEM Micrographs at 30 wt% IC Particulate Loading 

 

Particles 

Polymer 

Matrix 

Agglomeration of 

particulates 

Figure 7. SEM Micrographs at 30 wt% IC Particulate
Loading.

 

 

 
 

Figure 8: Tensile Modulus at varying IC particulate loading 

 

0

50

100

150

200

250

0 5 10 15 20 25 30

T
e
n

si
le

 M
o
d

u
lu

s 
(M

P
a
)

IC Particulate Loading (wt%)

Figure 8. Tensile Modulus at varying IC particulate
loading.

ings as compared to the RLDPE. It showed that the
RLDPE has an average tensile modulus of 116.44MPa.
It was observed that as the particulate loading in-
creased from 5 wt% to 30 wt%, there was an increase
of 8.78 % to 82.53 % in the average tensile modulus
of the composites when compared to the RLDPE. As
the IC particulate loading increased, the elasticity
of RLDPE has been suppressed by the presence of
the derived cellulose. The increment in the modulus
is attributed to the decreased deformability of the
interface between the IC particulate and the matrix
material, which caused a reduced strain as the par-
ticulate loading increased, due to the rigidity of the
material [3]. Then et al. [8] suggested that the en-
hancement in the tensile modulus is probably due to
the fibres itself, which have a higher stiffness than
those of the polymer.

3.1.3. Percentage elongation at break
Figure 9 illustrates the average percentage elongation
at break of the composite produced at different cellu-
lose loadings as compared to the RLDPE. It showed
that the RLDPE has a percentage elongation at break

 
 

Figure 9: Elongation at break at varying IC particulate loading 

 
 

0

10

20

30

40

50

60

0 5 10 15 20 25 30

E
lo

n
g

a
ti

o
n

 a
t 

B
r
e
a

k
 (

%
)

IC Particulate Loading (wt%)

Figure 9. Elongation at break at varying IC particu-
late loading.

of 54.93 %. It was observed that there was a decrease
of 64.73 % to 73.84 % in the average percentage elon-
gation at break of the composite as the IC particulate
loading increased from 5 wt% to 30 wt% compared
to the RLDPE. However, there was an increment of
57.31 % in the average percentage elongation at break
of the composite for particulate loading from 5 wt%
to 15 wt%. The maximum average percentage elon-
gation at break of the composite is nonetheless still
lower compared to that of the RLDPE. The incre-
ment noticed between 5 wt% and 15 wt% particulate
loadings may be attributed to a better dispersion of
the particles within the matrix. There was less ag-
glomeration of the particles and so a slightly more
strain at this range of particulate loading. However,
as the IC particulate loading increased, the elastic-
ity of the composite is suppressed by the presence
of the increased derived cellulose. The reduction is
attributed to the decreased deformability of a rigid
interface between the IC particulate and the matrix
material [3]. Liu et al. [9] reported that the decrease
in elongation at break is due to the destruction of the
structural integrity of the polymer by the fibres and
the rigid structure of the fibres.

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vol. 58 no. 3/2018 Characterization of Recycled Particulate Composites

IC Particulate Impact Hardness
Loading (wt%) Strength (HV)

(J)
0 5.03 52.63
5 2.68 50.57

10 2.88 64.73
15 2.98 70.63
20 3.45 91.53
25 3.8 103.77
30 4.4 111.33

Table 1. Impact strength and hardness property in
relation to IC particulate loading.

3.1.4. Impact strength
Table 1 illustrates the average impact strength of the
composite produced at different particulate loadings as
compared to the RLDPE. It showed that the RLDPE
has an average impact strength of 5.03 J. Higher im-
pact strength demonstrated by the neat RLDPE is due
to the flexibility, plasticity, and less brittleness of the
RLDPE, which allows it to absorb and distribute the
impact energy efficiently [3]. There was an increase of
7.46 % to 64.18 % in the average impact strength of
the composite as the IC particulate loading increased
from 5 wt% to 30 wt%. Nevertheless, the maximum
average impact strength of the composite at 30 wt%
particulate loading was still 12.52 % lower when com-
pared to that of the RLDPE. Considering the steady
increment that was observed, up to 30 wt% loading of
the IC particulate, it is possible that if the particulate
loading increases beyond 30 wt%, the impact strength
of the composite may eventually reach or even exceed
that of the RLDPE at some point. The increment
in the average impact strength may be attributed to
the rigid interface between the IC particulate and the
matrix material as the particulate loading increased.

3.1.5. Hardness property
Table 1 illustrates the average hardness values of the
composite produced at different IC particulate load-
ings as compared to the RLDPE. It showed that the
RLDPE has an average hardness value of 52.63. It
was observed that as the particulate loading increased
from 5 wt% to 30 wt%, there was an increase of 22.99 %
to 111.53 % in the average hardness values of the
composites when compared to the RLDPE. The in-
crease in the hardness property observed with the
RLDPE/IC particulate composite is a result of the
hardness property of the IC particulate itself, which
has been transmitted to the composite. The reduction
in the hardness value at 5 wt% particulate loading may
be as a result of a void in the composite [10].

3.2. Physical properties
3.2.1. Water absorption
Table 2 illustrates the average percentage water ab-
sorption of the composite produced at different IC

IC Particulate Water Mass Density
Loading (wt%) Absorp- (g) (g/cm3)

tion (%)
0 4.64 10.69 0.855
5 6.81 10.66 0.853
10 7.11 10.34 0.827
15 7.19 10.01 0.801
20 7.86 9.88 0.791
25 13.66 9.86 0.789
30 15.47 9.77 0.782

Table 2. Water absorption and density in relation to
IC particulate loading.

particulate loadings as compared to the RLDPE. It
showed that the RLDPE has a percentage water ab-
sorption of 4.64 %. It was observed that as the IC par-
ticulate loading was increased from 5 wt% to 30 wt%,
there was an increase of 46.77 % to 233.41 % in the
average percentage water absorption of the composites
when compared to the RLDPE. This result is accord-
ing to expectations, as composites with natural fibre
reinforcement exhibit higher water absorption due to
the inherent hydrophilic nature of the fillers [11, 12].

3.2.2. Density
Table 2 illustrates the average density of the composite
produced at different IC particulate loadings when
compared to RLDPE. It showed that the RLDPE has
a density of 0.855 g/cm3. It was observed that as the
IC particulate loading was increased from 5 wt% to
30 wt%, there was a decrease of 0.23 % to 8.53 % in the
average density of the composites when compared to
the RLDPE. The decrease in the density observed with
the RLDPE/IC particulate composite is as a result of
the low density of the IC particulate itself, which has
been transmitted to the composite. When a larger
fraction of the RLDPE, which is of a higher density,
is replaced by lighter particulates, the overall density
of the subsequent composite is reduced, which is one
advantage that natural fibre composites have over
synthetic fibre composites [3] and other engineering
materials.

4. Conclusion
In this study, RLDPE/IC particulate composites have
been produced through a form of hand lay-up tech-
niques and the mechanical and physical properties at
5 wt% to 30 wt% particulate loadings have been exam-
ined. The results from the tests carried out showed
that the tensile modulus, hardness, impact strength
and water absorption of the composite increased as
the IC particulate loading increased from 5 wt% to
30 wt% respectively. Although, an increasing trend
was observed for the impact strength as particulate
loading increased up to 30 wt%, the value was still
lower compared to that of the RLDPE. By increasing
the IC particulate loading beyond 30 wt%, the impact

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O. F. Olusunmade, S. Zechariah, T. A. Yusuf Acta Polytechnica

strength of the composite may eventually reach or
even exceed that of the RLDPE at some point. How-
ever, tensile strength, percentage elongation at break
and density of the composite decreased as particulate
loading increased 5 wt% to 30 wt% respectively. Al-
though an increase in tensile strength and elongation
was observed up to 15 wt% loading of the particulate,
the maximum tensile strength and elongation of the
composite at that loading was still lower than that
of the RLDPE. The results obtained from the tests
conducted showed that the composite can actually be
adapted in some engineering applications particularly
because of the positive indications observed regard-
ing tensile modulus, hardness, impact strength and
density. The combination of the recycled waste water-
sachets and the IC particulate is really promising for
a composite development. This creates opportunities
to reduce LDPE wastes and add economic importance
to an otherwise agricultural menace. It will mean
creating an economic value from “wastes”.

References
[1] LUCINTEL: “Global Natural Fiber Composite Market
2015-2020: Trends, Forecast, and Opportunity
Analysis,” Market Research Reports, 2015.

[2] CELLUWOOD: “Technologies and Products of
Natural Fibre Composites,” CIP-EIP-Eco-Innovation-
2008: ID: ECO/10/277331, 2008.

[3] Olusunmade, O. F, Adetan D. A and Ogunnigbo C. O:
“A Study on the Mechanical Properties of Oil Palm
Mesocarp Fibre Reinforced Thermoplastic (OPMFRT)”,
Journal of Composites, vol. 2016, Article ID 3137243, 7
pages, 2016. doi:10.1155/2016/3137243

[4] Ogunsile, B. O and Oladeji, T. G: “Utilization of
banana stalk fiber as reinforcement in low density
polyethylene composite,” RevistaMateria, artigo11757,
21(4), pp.953-963, 2016.
doi:10.1590/s1517-707620160004.0088

[5] Angzzas, S. M. K, Aripin, A. M, Ishak, N, Hairom, N.
H. H, Fauzi, N. A, Razali, N. F and Zainulabidin, M. H:

“Potential of Cogon Grass (Imperata cylindrica) as an
alternative fibre in paper-based Industry,” ARPN
Journal of Engineering and Applied Sciences, vol. 11,
No. 4, 2016.

[6] Soromessa, T: “Heteropogon contortus (L.) Beauv. Ex
Roem. & Schult.,” PROTA (Plant Resources of Tropical
Africa), Wageningen, Netherlands, 2011.

[7] Cook, B. G, Pengelly, B. C, Brown, S. D, Donnelly, J.
L, Eagles, D. A, Franco, M. A, Hanson, J, Mullen, B. F,
Partridge, I. J, Peters, M and Schultze-Kraft, R:
“Tropical Forages: an interactive selection tool,” CSIRO,
DPI&F (Qld), CIAT and ILRI, Brisbane, Australia,
2005.

[8] Then, Y. Y, Ibrahim, N. A, Zainuddin, N, Ariffin, H
and Wan Yunus, W. M. Z: “Oil palm mesocarp fiber as
new lignocellulosic material for fabrication of
polymer/fiber biocomposites,” International Journal of
Polymer Science, vol. 2013, Article ID797452, 7 pages,
2013. doi:10.1155/2013/797452

[9] Liu, L, Yu, J, Cheng, L and Qu, W: “Mechanical
properties of poly (butylene succinate) (PBS)
biocomposites reinforced with surface modified jute
fibre,” Composites Part A: Applied Science and
Manufacturing, vol. 40, no. 5, pp. 669–674, 2009.
doi:10.1016/j.compositesa.2009.03.002

[10] Kling, V, Rana, S and Fangueiro, R: “Fibre
reinforced thermoplastic composite rods,” Materials
Science Forum, vol. 730-732, pp. 331–336, 2013.
doi:10.4028/www.scientific.net/MSF.730-732.331

[11] Naghmouchi, I, Mutje, P and Boufi, S: “Olive Stones
Flour as Reinforcement in Polypropylene Composites:
A Step Forward in the Valorization of the Solid Waste
from the Olive Oil Industry,” Industrial Crops and
Products, 72, 183-191, 2015.

[12] Deo, C and Acharya, S. K: “Effect of Moisture
Absorption on Mechanical Properties of Chopped
Natural Fiber Reinforced Epoxy Composite,” Journal of
Reinforced Plastics and Composites, vol. 1 pp. 5-15,
2010. doi:10.1177/0731684409353352

200

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http://dx.doi.org/10.1590/s1517-707620160004.0088
http://dx.doi.org/10.1155/2013/797452
http://dx.doi.org/10.1016/j.compositesa.2009.03.002
http://dx.doi.org/10.4028/www.scientific.net/MSF.730-732.331
http://dx.doi.org/10.1177/0731684409353352

	Acta Polytechnica 58(3):195–200, 2018
	1 Introduction
	2 Materials and method
	2.1 Polymer and fibre processing
	2.2 Composite preparation
	2.3 Composite characterization
	2.3.1 Mechanical properties
	2.3.2 Physical properties


	3 Results and discussion
	3.1 Mechanical properties
	3.1.1 Tensile strength
	3.1.2 Tensile modulus
	3.1.3 Percentage elongation at break
	3.1.4 Impact strength
	3.1.5 Hardness property

	3.2 Physical properties
	3.2.1 Water absorption
	3.2.2 Density


	4 Conclusion
	References