Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

54, 2, pp. 551-560, Warsaw 2016
DOI: 10.15632/jtam-pl.54.2.551

IMPROVING MECHANICAL PROPERTIES OF EPOXY BY ADDING

MULTI-WALL CARBON NANOTUBE

Basim M. Fadhil, Payman Sahbah Ahmed

Manufacturing Engineering Department, Koya University, Koysinjaq, Irak

e-mail: basim.fadhil@koyauniversity.org

Ava Ali Kamal

Engineering and Projects Directorate, Salahadin University, Erbil, Irak

e-mail: avaali@yahoo.com

In this research, multi-walled carbon nanotubes (MWCNTs) are used as the reinforcement
in an epoxy resin with weight percentages (0,0.2,0.4,0.6,0.8,1)wt%, respectively, by using
both direct (nonhomogeneous) and homogeneous dispersion mixing processes to prepare
(epoxy/MWCNTs) nanocomposites.Tensile and dropweight impact tests are used to evalu-
atemechanical properties of the composites. Results show that homogeneous dispersion has
a great effect on enhancingmechanical properties of multi-wall carbon nanotube reinforced
composites. Adding 0.2wt% of MWCNTs enhances and increases tensile properties, and
adding 0.6wt% ofMWCNTs enhances impact properties.

Keywords: multi-wall carbon nanotubes, mechanical properties and nanocomposites

1. Introduction

CNT/polymer composites are increasingly used for engineering applications under hardworking
conditions due to unique mechanical properties of CNTs, such as high elastic modulus, tensile
strength and strain to fracture, ability to withstand cross-sectional and twisting distortions
and compression without fracture combined with a low specific weight and high resistance to
degradation in order to ensure safety and economic efficiency (Du et al., 2007; Walter et al.,
1997).

Epoxy based Multi-Walled Carbon Nanotubes (MWCNTs) reinforced composites are syn-
thesized by Samal (2009) by themethod of sonication. The variation of nature of the reinforce-
ment (aligned and randomly orientedMWNTS) has resulted in the improvement of mechanical
properties like flexural modulus, tensile strength and hardness. A small change in chemical tre-
atment of the nanotubes has a great effect in the mechanical and morphological properties of
the nanocomposites due to the effective load transfer mechanism and state of dispersion. The
change in properties has been verified by optical microscopy and scanning electron microscopy.
Apart from that the prepared composites have been treated under different temperatures (like
hot water, room temperature and liquid nitrogen temperature) and the change inmechanical as
well as morphological nature has been verified by SEMof fractographic surface, this proved the
elasticity and ductility of the composites.

Multi-walled carbon nanotubes (MWCNTs) were used by Nemaa et al. (2014) to enforce
the blend of epoxy/polysulfide and then tensile and wear behavior of this reinforcement were
evaluated. For achieving this goal, different weight percentages of MWCNT (0.2-0.6wt%) we-
re dispersed in the epoxy resin, then polysulfide resin was added and mixed with two curing



552 B.M. Fadhil et al.

agents. Experimental results have shown significant difference between epoxy/polysulfide and
CNT/epoxy/polysulfide inmechanical properties.With 0.2-0.6% MWCNTs we observed an in-
crease in Young’s modulus from 245 to 273MPa, tensile strength from 30.5 to 38.9MPa and
fracture strain from 12.4% to 14.2%. For understanding the structure and morphology of na-
nocomposite, the dispersion states were studied using scanning electron microscopy (SEM) and
field emission electron microscopy (FESEM).

Different types of Multi-Walled Carbon Nanotubes (MWCNTs) long and short were used
by Al-Rawi et al. (2014) as the reinforcement in an epoxy resin with weight percentages
(0.1,0.2,0.5,1.0,1.5,2.0,2.5,3.0,3.5,4.0,4.5,5)wt%, respectively, by using directmixing proces-
ses to prepar (epoxy/MWCNTs) nanocomposites. The ultrasonic mixing process was used to
disperse the nanotubes into the epoxy resin system.The results show improvement of themecha-
nical properties with an increase in the percentage weight less than 2% and then a decreament
with a further increase in theMWCNTs content. The results show that long carbon nanotubes
have mechanical properties better than short carbon nanotubes.

A systemic evaluation was done by Ci and Bai (2006), for different reinforcement roles of
carbon nanotubes in those nanocomposites with different matrix stiffnesses while the curing
process were controlled. Bothmechanical tests andmicroscope observations indicated that such
a reinforcement would gradually reduce while increasing the stiffness of matrix. However, in
soft and ductile composites, carbon nanotubes show a significant reinforcementwithout fracture
strain growth. The interface interaction is poor between carbon nanotubes and matrix in the
stiff composite, and therefore, they have little contribution to the mechanical properties of the
composite.

In this research,Multi-Walled CarbonNanotubes (MWCNTs) are used as the reinforcement
inanepoxy resinwithweightpercentages (0,0.2,0.4,0.6,0.8,1)wt%, respectively, byusingdirect
and homogeneous dispersion mixing processes to prepare (epoxy/MWCNTs) nanocomposites.
Tensile and drop weight impact tests are used to evaluate the mechanical properties of the
composites.

2. Experimental part

Epoxy resin of a trade mark (Quickmast 105 base) is used as the matrix which is a liquid of
low viscosity as compared with other thermosets, and it is converted to solid state by adding a
hardener (Quickmast 105 hardener) at ratio of 3:1, the technical properties of Quickmast 105
according to the data sheet of DCP company are listed in Table 1; while the nanoparticle
reinforcements are MWCNTs manufactured by Henan Huier Nano Technology Co. Ltd. Their
technical properties are listed in Table 2.

Table 1.Technical properties of Quickmast 105 (provided by the supplier)

Compressive Flexural Tensile
Pot life

Specific
gravity

strength strength strength Viscosity
BS6319 BS6319 BS6319

> 72MPa > 50MPa > 20MPa 60min 1.1 3-5 poise
7 days 25◦C 25◦C 25◦C

1-2 poise
35◦C

To prepare a carbon nanotubes/epoxy composite, the nanotube powder (with a content of
0, 0.2, 0.4, 0.6, 0.8, and 1wt%) was added into the liquid epoxy in two ways:



Improving mechanical properties of epoxy by adding... 553

Table 2.Technical properties of multi-wall carbon nanotube (provided by the supplier)

Length of the Outer diameter Tube wall Number
carbon tube of tubes thickness of layer

3-12nm 12.9nm 4.1nm 8-15

Tube thickness distribution TEM image

1. Nonhomogeneous dispersion: the resin and carbon nanotube solutionwasmanually stirred
for 5min to form a homogeneous suspension.And then an epoxy hardener wasmixed into
the carbon nanotubes/epoxy suspension, and softly stirred for about 2min. Finally, the
composite suspension was poured into the impact and dog-bone-like steel tensile mould
and left to be cured at room temperature for 7 days.

2. Homogeneous dispersion: the resin and carbon nanotube solution wasmanually stirred for
10min to form a homogeneous suspension. And then an epoxy hardener was mixed into
the carbon nanotubes/epoxy suspension, softly stirred for about 10min, and the mixture
was left for 2hrs to get homogeneous dispersion. Finally, the composite suspension was
poured one corner into the impact and dog-bone-like steel tensile mould (to avoid bubble
formationwhich causes cast damage) and left to be cured at room temperature for 7 days.

Samples without carbon nanotube addition (matrix samples) were also fabricated for compari-
son.

Mechanical tests were done according toASTMD638 [3] for a tensile test and ISO 6603 [10]
for an impact test. Instron 5982 tensile test machine was used to measure tensile behavior of
the samples at strain rate of 2mm/s. The specimenwas fixed straightly by using two jaws with
100kN maximum load. The machine started to elongate the specimen at a constant rate, and
to continuously and simultaneously measure the instantaneous applied load and the resulting
extension. InstronCeast 9350 instrumentedwith theDropweight impact tester was used tome-
asure the resistance to failure of amaterial subjected to a suddenly falling object (weight=5.8kg)
from a level of 700mm. The machine started to continuously and simultaneously measure the
instantaneous impact load and the resulting deformation and impact energy (absorbed energy).

3. Results and discussion

During the study, multi-walled carbon nanotubes (MWCNTs) were used as the reinforcement
in the epoxy resin with weight percentages (0,0.2,0.4,0.6,0.8,1)wt%, respectively, by using
direct and homogeneous dispersion mixing processes to prepare (epoxy/MWCNTs) nanocom-
posites. Tensile and drop weight impact test were carried out used to evaluate the mechanical
properties of the composites. The relationships of stress-strain, impact force-time, impact force-
deformation, impact energy-time and impact energy-deformation were obtained from experi-
mental data as follows.



554 B.M. Fadhil et al.

3.1. Tensile test results

Figure 1 shows the stress-strain results of the composites used in this studywith differentmulti-
-walled carbonnanotubes (MWCNTs) reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and1wt%
for two mixing techniques, i.e. nonhomogeneous and homogeneous dispersion.

Fig. 1. Stress-strain curves of the composites with different percentages of multi-wall carbon nanotube:
0, 0.2, 0.4, 0.6, 0.8, and 1wt%

Fig. 2. Tensile stress, extension and energy at maximum load in the composites with different
percentages ofMWCNTs reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt%

It can be seen that the dispersion has a great effect on the stress and strain values for all
composites. Such low reinforcing ability of the nanotubes in epoxy nanocomposites, which is so-
metimes observed, can be explained by a number of reasons: one is lack of interfacial adhesion,



Improving mechanical properties of epoxy by adding... 555

which is critical for load transfer in composites. Indeed, carbon nanotube surfaces are atomi-
cally smooth, which may limit the transfer of load from thematrix to nanotubes reinforcement
(Cooper et al., 2000; Bokobza, 2007). Another reason is poor dispersion of nanotubes in the
polymer matrix, which is also significant for fabrication of reinforced nanocomposites (Gojny
et al., 2004). Due to their high aspect ratio and huge surface area, CNTs have strong tendency
to agglomerate, which leads to inhomogeneous dispersion in the polymer matrix (Smutisikha,
2010).

Figure 2 shows tensile properties and results of the composites usedwithdifferentpercentages
ofMulti-Walled CarbonNanotubes (MWCNTs) reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8,
and 1wt%.

It can be seen that the content of MWCNTs (0.2-1wt%) enhances and increases the tensile
properties and reaches the maximum values for 0.2% NT composite: tensile stress at maximum
load from 28.6MPa for epoxy resin to 41.4MPa, maximum load from 2.1kN for epoxy resin to
2.9kN, tensile extension at maximum load from 5.04mm for epoxy resin to 4.2mm and tensile
energy at maximum load from 5.9J for epoxy resin to 10.6J. Creating attractive polar forces,
andVan der-Waals bondingbetween chains and nanotubes leads to an increase in the constraint
between tubes/epoxy chains and epoxy chains, complicates epoxy chains which approach one
another, reduces free volume space. This effect of MWCNTs make the epoxy chains bear extra
loading (Park et al., 2004). A 0.4%wt ofMWCNTs is better than that of epoxy, but lower than
other percentages due to formation of agglomerates of nanotubes in the polymer matrix that
reduce the reinforcing effects of the CNTs.

3.2. Impact test results

3.2.1. Impact force – time behavior

Figure 3 shows time histories of the impact force in the composites used with different
percentages of MWCNTs reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt% for two
mixing techniques, i.e. nonhomogeneous and homogeneous dispersion.

It can be seen that dispersion has a great effect on the force values for all composites which
is attributed to good dispersions of the nanotubes in thematrix and good reactions between the
epoxy and grafted nanotubes. The investigation of the fracture surface in nanocomposites reve-
aled that narrower crack-tips underneath the advancing cracks were more efficiently bridged by
thenanotubes in epoxy/MWCNTs resulting in an increased resistance against crack propagation
(Ajayan et al., 2006).

3.2.2. Impact force – deformation behavior

Figure 4 shows the impact force vs. deformation results of composites with different percen-
tages of MWCNTs reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt% for two mixing
techniques. It can be seen that dispersion has a great effect on the force values for all composites
which is attributed to the formation of a network structure which can take more mechanical
loading from the matrix when the matrix is under stress. This means that when the applied
loading is over the elastic deformation stress, the carbon nanotubes transfer the stress (Qi etal,
2006), which enhances the strength of the resin matrix.

3.2.3. Impact energy – time behavior

Figure 5 shows the impact energy vs. time of composites with different percentages of
MWCNTs reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt% for twomixing techniques.
It can be seen that dispersion has a great effect on the force values for all composites which is
attributed to theweak van derWaals bonding between the reinforcement and thematrix, which



556 B.M. Fadhil et al.

Fig. 3. Impact force vs. time in composites used with different percentages of MWCNTs reinforcement
in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt%

Fig. 4. Impact force vs. deformation of composites with different percentages of MWCNTs
reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt%



Improving mechanical properties of epoxy by adding... 557

is themain load transfermechanism forCNT/polymer composites where the interfacial energies
normally amount to∼ 50-350mJ/m (Nardin and Schultz, 1993).

Fig. 5. Impact energy vs. time of composites with different percentages of MWCNTs reinforcement in
the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt% fot twomixing techniques

3.2.4. Impact energy – deformation behavior

Figure 6 shows the impact energy vs. deformation of compositeswith different percentages of
MWCNTs reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt% for twomixing techniques.
It can be seen that dispersion has a great effect on the force values for all composites which is
attributed to the micromechanical interlocking, which can be marginal in CNT/polymer com-
posites if CNTs have atomically smooth surface. The van der Waals bonding is increased by
using small size reinforcement and close contact at the interface. CNTs are strong enough and
inter-connected or long enough to block the movement of polymer chains (Du et al., 2007; Lu,
1997; Meguid and Sun, 2004).

3.2.5. Effect of multi-wall carbon nanotube percentages on impact properties of the composites

Figure 7 shows a summary of the effect of addingmulti-wall carbon nanotubepercentages on
impact properties: energy, force and deformation of the composites in this study. It can be seen
thatboth energy and force values are increasedup to 0.6%multi-wall carbonnanotube then they
decrease, which is due to critical CNT content in thematrix. This can be foundwhen the CNT
strengthening effect on randomly orientedCNT/polymer composites are investigated. Below this
content, the strengthening effect for randomly orientedCNT/polymer composites increases with



558 B.M. Fadhil et al.

Fig. 6. Impact energy vs. deformation of composites with different percentages ofMWCNTs
reinforcement in the epoxy: 0, 0.2, 0.4, 0.6, 0.8, and 1wt% for twomixing techniques

Fig. 7. Effect of adding multi-wall carbon nanotube percentages on impact properties: energy, force and
deformation of the studied composites

growing CNT content. Above this content, the strength of CNT/polymer composites decreases.
The work of Bai (2003) shows that the critical CNT loading percentage is about 0.5wt% for
CNT/epoxy composites. The same tendency was reported by Meguid and Sun (2004) in their
work on the tensile and shear strength of nano-reinforced composite interfaces. The excess of
CNTs increases the viscosity of polymers and can also cause some surface of the CNTs not be
completely covered by the polymer matrix due to the large specific surface area of the CNTs.
This makes uniform dispersion and load transfer more difficult. Moreover, it is very difficult



Improving mechanical properties of epoxy by adding... 559

for high quantity of polymers to intercalate among CNTs when the CNT content becomes high
(Du et al., 2007). Impact energy and force increases from 2.9J and 0.92kN for the epoxy to
its maximum value 25.5J and 4.16kN in 0.6% NT composites, and the impact deformation
decreases from 18.4mm for the epoxy to its minimum value 13.6mm in 0.6% NT composites.

4. Conclusions

• Homogeneous dispersion has a great effect on enhancing mechanical properties of multi-
-wall carbon nanotube reinforced composites.

• Adding 0.2wt% of MWCNTs enhances and increases tensile properties to reach their
maximumvalues as follows: tensile stress atmaximum load from 28.6MPa for epoxy resin
to 41.4MPa, maximum load from 2.1kN for epoxy resin to 2.9kN, tensile extension at
maximum load from 5.04mm for epoxy resin to 4.2mm and tensile energy at maximum
load from 5.9J for epoxy resin to 10.6J.

• The impact energy and force increase from 2.9J and 0.92kN for the epoxy to their ma-
ximum values of 25.5J and 4.16kN, respectively, in 0.6% NT composites. The impact
deformation decreases from 18.4mm for the epoxy to its minimum value 13.6mm in 0.6%
NT composites.

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Manuscript received July 20, 2015; accepted for print September 22, 2015