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Investigation of the Influence of the Synthesized Iron-

Carbide Mixture on the Adhesive and Mechanical 

Properties of Epoxy Composites for Parts of 

Transport Machines  

Andriy Buketov 

Department of Transport Technologies 

Kherson State Maritime Academy 
Kherson, Ukraine 

buketov.andrey@gmail.com 

Olha Syzonenko 

Department of Pulse Processing 

Dispersed Systems, Institute of Pulse 
Processes and Technologies of NAS of 

Ukraine, Mykolaiv, Ukraine 
sizonenko43@rambler.ru 

Dmytro Kruglyj 

Department of Innovative Technologies 

and Technical Means of Navigation 
Kherson State Maritime Academy 

Kherson, Ukraine 
krughlyidmytro@gmail.com 

Tetiana Cherniavska 

Department of Transport Technologies 

Kherson State Maritime Academy 

Kherson, Ukraine 

tanya2181@ukr.net 

Eduard Appazov 

Department of Innovative Technologies 

and Technical Means of Navigation 

Kherson State Maritime Academy 

Kherson, Ukraine 
eappazov1@gmail.com 

Kostiantyn Klevtsov 

Department of Transport Technologies 

Kherson State Maritime Academy 

Kherson, Ukraine 

klevtsovk@i.ua 

 

 

Abstract−Epoxy-diane oligomer ED-20, hardener polyethylene 

polyamine, and micro dispersed particles of iron-carbide mixture 

synthesized by high-voltage electric discharge have been used for 
the formation of Composite Materials (CMs) and protective 

coatings for the transport industry. The dependence of the 

adhesive, physical, and mechanical properties and residual 

stresses of epoxy composites on the content of micro dispersed 

powders has been studied in this paper. It has been proved that 

for the formation of a composite material or protective coating 
with improved adhesion and cohesion properties, the optimal 

content of particles is 0.5 wt.% per 100 wt.% of epoxy oligomer 

ED-20. Such materials are characterized by increased mechanical 

strength and the ability to resist static and shock loads, as their 

properties are significantly increased. The obtained results of the 

experimental studies of the physical and mechanical properties of 

composite materials correlate with the studied results of adhesive 
characteristics, which indicate their veracity. 

Keywords-epoxy composite; modulus of elasticity; impact 

strength; flexural stresses 

I. INTRODUCTION  

The development of various industries, including transport, 
involves the expansion of the scope of structural functional 
polymeric materials. The use of polymeric epoxy composite 
coatings is important for the corrosion protection of 
technological equipment, including parts of transport machines 
[1-5]. Ensuring the compliance between the properties of 
materials used in mechanisms and structures in the complex 
conditions of their operation is one of the most significant 

problems of technological progress nowadays. The current 
level of production development involves primarily taking into 
account the economic factor due to the need to develop new 
effective functional materials. Herewith, it is necessary to make 
allowance the latest approaches, which are based on the 
optimization of the components of materials of a specific 
functional purpose. At the same time, such optimization is 
carried out according to several criteria, such as adhesive 
strength, residual stresses, flexural stresses, and impact 
strength. Today, the potential capabilities of known polymeric 
materials are far from being fully realized, due to the 
insufficient analysis of the physicochemical processes during 
their operation and destruction. In our opinion, only an 
approach that involves the analysis of properties in a complex 
will ensure the formation of new gradient composites with 
specified improved both adhesive and cohesive characteristics. 

Authors in [6, 7] showed that the creation of new materials 
with high performance is impossible without understanding the 
mechanism of interaction at the interface of the phases 
“protective coating – metal base” and “polymer matrix – filler”, 
which is the basis for the formation of chemical and physical 
bonds that determine the durability of materials. To implement 
the above, dispersible filler particles are introduced into the 
polymer binder. The presence of the active groups on the 
surface of the additives, which during the polymerization of the 
matrix form a significant number of bonds per unit volume of 
polymer is important. In this regard, it is important to pre-
activate the filler. Authors in [8, 9] showed that the use of 

Corresponding author: A. Buketov



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synthesized (including high-voltage electric discharge) 
powders with particles of insignificant dispersion is 
perspective. Given this, it is important to conduct a study to 
determine the optimal content of iron-carbide mixture 
synthesized by high-voltage electric discharge in the formation 
of protective polymer coatings to improve the adhesive and 
mechanical properties of transport vehicle parts. 

The aim of the work is to investigate the influence of the 
content of synthesized iron-carbide mixture on the adhesive 
and mechanical properties of epoxy composites for the 
transport industry.  

II. MATERIALS AND METHODS 

Epoxy diane resin ED-20 (GOST 10587-84) was selected 
for the formation of the polymer matrix. Epoxy resin is a highly 
viscous transparent liquid that can be cross-linked at room or 
elevated temperature without external pressure. The ability to 
cure these resins without the release of by-products provides 
low shrinkage, high density, and low porosity of materials, 
which is important when working with composite products and 
protective coatings based on them in difficult conditions. 
Polyethylene polyamine – PEPA (TU 6-02-594-70) was 
selected for curing the epoxy compositions. Hardener PEPA is 
used for the cross-linking of epoxy resins at room and low 
temperatures in conditions of high humidity. The composites 
were crosslinked by introducing the hardener into the 
composition at a stoichiometric ratio of components at content 
(wt.%) – ED-20 : PEPA – 100 : 10. Synthesized Iron-Carbide 
Mixture (SICM) was used as a microdisperse filler in the 
experiment. The filler was formed by High-Voltage Electric 
Discharge (HVED) synthesis. For the HVED synthesis of the 
filler an experimental stand was used, described in detail in [8, 
9]. A mixture of powders of Fe (75%) and Ti (25%) was used 
as the starting material. During the synthesis, the accumulated 
energy of a single discharge (W1) was 1kJ, and the integrated 
specific energy of the processing (W) was 25MJ/kg. Variations 
can be performed in the process in the distribution of the 
electric field and plasma formations in the volume of the 
discharge chamber by using different types of electrode 
systems. In this work, a 15-point design of the electrode system 
is used [8]. The use of different electrode systems allowed 
controlling the distribution of the intensity of the main factors 
of HVED [9]. Thus, in the case of using a 1-point system, a 
larger share of the accumulated energy was transformed into 
shock waves, then the use of a 15-point system allowed 
increasing the intensity of thermal and current factors. The 
results of the research showed that as a result of HVED 
treatment all the treated particles were crushed and their phase 
composition was changed with the synthesis of high-modulus 
compounds TiC and Fe3C (Table I). 

The technology of forming epoxy composites is as follows. 
At the initial stage, the epoxy resin was heated to a temperature 
of T=353±2K, kept during for a time duration of τ=20±0.1min. 
At the next stage, the resin was hydrodynamically combined 
with the dispersed filler for 10±0.1min and then Ultrasonic 
Processing (USP) of the composition was performed for 
1.5±0.1min. After cooling the mixture to room temperature 
(τ=60±5min), a hardener was introduced and the composition 
was blending for 5±0.1min. The prepared compositions were 

formed and were polymerized according to the following 
procedure: 

• casting of specimens 

• keeping for 12.0±0.1 hours at room temperature (293±2K) 

• heating to 393±2K (at a rate of υ=3K/min) 

• keeping at a given temperature during 2.0±0.05 hours 

• slowly cooling to 293±2K. 

At the final stage, the specimens were kept for 24 hours in 
the air at a temperature of 293±2K to internal stress relaxation, 
which allowed stabilizing the developed materials properties. 
The following properties of СM were investigated in this work: 
adhesive strength, residual stresses, flexural stresses, and 
modulus of elasticity at bending and impact strength. 

TABLE I.  RESULTS OF THE HVED SYNTHESIS OF THE FILLER 

Composition 

Composition 

after 

treatment 

Electrode 

system 

Diameter after 

treatment d (µm) 
dmin dmax dav 

Fe (75 %) + 

Ti (25 %) 

Fe (70 %) + 

TiC (25 %) + 

Fe3C (5 %) 

15 ~1 147 17 

 

The influence of the content of additives of different nature 
on the adhesion properties of composites to the metal base was 
investigated. The destructive tension (“fungal method”) was 
measured with a uniform separation of a pair of glued samples 
in accordance with ASTM D897-08(2016). The adhesive 
strength was investigated on an automated tensile testing 
machine UM-5 at a loading speed of 10N/s. The diameter of 
the working part of the steel specimens was 25mm. Residual 
stresses in coatings were determined by the cantilever method 

according to [10]. Residual stresses σr were found by: 

3

3
3 ( )

r

HE

L

δ
σ

δ δ δ
∗ ∗

=
+

    (1) 

where Н is the substrate deflection from the initial position (m), 
Е is the elasticity modulus of the substrate (Е=2.1×10

8
Pa), L is 

the length of the substrate with the adhesive (m), δ is the 

substrate thickness (m), and δ*is the adhesive thickness (m). 

At the initial stage, a coating with thickness δ=0.1–0.2mm 
on a steel substrate was formed by the spray method. The 
parameters of the substrate were: total length l=100mm, 
working length l0=80mm, thickness δ=0.2mm. At the next step, 
during the polymerization process, the chemical bonds between 
the adhesive and the substrate are forming, which involves the 
occurrence of residual stresses in the coating. This leads to the 
deflection of the console up (in the form of a substrate with a 
coating), as the dominant in this case is the tensile stress. The 
value of this deflection (H) was determined after complete 
crosslinking of the material in the form of a protective coating 
(for a duration of 72 hours). Flexural stresses at bending and 
the modulus of elasticity at bending were determined in 
accordance with ASTM D 790 – 03. The dimensions of the 
testing specimens were: length l=120±2mm, width 
b=15±0.5mm, height h=10±0.5mm [11]. The impact strength 



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was determined by the Charpy method according to ASTM 
D6110 – 18. This method is based on a test in which a 
specimen placed on two supports is subjected to a pendulum 
impact, the line of impact being midway between the supports 
and directly opposite the notch (in the case of notched 
specimen). The dimensions of the testing specimens were: 
(63.5×12.7×12.7)±0.5mm. The distance between the supports 
was 40±0.5mm. The deviation of values of adhesive and 
physical and mechanical properties of CM was 4–6% from 
nominal during the study. 

III. RESULTS AND DISCUSSIONS 

It has been experimentally established that the adhesion 
strength at break of the epoxy matrix modified by USP is 

σа=24.8MPa (Figure 1). The introduction of SICM particles 
(d=15–18µm) into the epoxy binder leads to a monotonic 
increase in the adhesive strength of the composite. It is shown 
(Figure 1, curve 1) that the maximum in the “adhesive strength 
at break–filler amount” curve was observed at content of 
particles of q=0.5 wt.% by 100 wt.% of ED-20 (hereinafter 
wt.% are given per 100wt.% of epoxy resin ED-20). The 
adhesive strength of the material increases from σа=24.8MPa 

(epoxy matrix) to σа=44.7MPa at this introduction. Further 
increase in the particle content leads to a deterioration of the 
adhesive properties of epoxy composites. It has been proved 
(Figure 1) that the content increase of particles amount to q=2.0 
wt.% promotes the CM formation. The adhesive strength of 

such CM decreases from σа=44.7MPa (for CM with filler 

content of q=0.5 wt.%) to σа=33.2MPa. Based on the above 
experimental results, it was considered that the further increase 
of the SICM amount in the epoxy composite is not advisable, 
since the adhesive properties of the materials monotonically 
deteriorate. 

 

 
Fig. 1.  Dependence of adhesive strength and residual stresses in CM on 

the content of SICM particles: 1 – adhesive strength at break (σa); 2 – residual 
stresses (σr). substrate material – steel. 

The obtained experimental results allow stating the 
efficiency of using the SICM for the formation of CM on the 
basis of epoxy binder. Authors in [8, 9] showed that before the 
synthesis of filler particles at the initial stage they formed a 
mechanical mixture of powders at a predetermined content: 

Fe(75%)+Ti(25%). In the process of high-voltage electric 
discharge according to predetermined modes, a synthesized 
powder is formed, which contains components of the following 
composition: Fe(70%)+TiC(25%)+Fe3C(5%). It was proved, 
that the improvement of adhesion characteristics of materials as 
a result of the loading of active dispersed particles into the 
epoxy oligomer is presented. It was assumed that the active 
centers of Fe, TiC and Fe3C, which are contained both in the 
volume and on the surface of the dispersed phase during the 
polymerization process interact with the segments and pendent 
groups (OH-, CH-, C=O) of the epoxy oligomer. At the same 
time, the degree of crosslinking of the three-dimensional 
polymer net increases, which improves the adhesive properties 
of CM. In addition, authors in [8, 9] proved that, after the 
synthesis, on the surface of the particles areas, titanium and 
iron carbides are localized, which are mainly activators of 
physical and chemical interfacial bonds in the structure of 
materials. At the same time, it should be noted that the 
maximum number of chemical bonds per volume unit of the 
polymer was observed at a critical content of dispersed 
particles in the amount of q=0.5 wt.%. This explains the 
highest values of adhesive strength of composites with such a 
filler content among the entire range of investigated materials. 

It is known [12] that the occurrence of residual stresses in 
polymer composites is one of the determining criteria for the 
durability of protective coatings, including anti-corrosion 
coatings, especially in the transport industry. Therefore, in the 
context of adhesion tests, it was considered necessary to 
investigate the value of residual stresses in the formed coatings 
depending on the content of the SICM. It is established (Figure 
1, curve 2) that the initial epoxy matrix is characterized by 

residual stresses σr=1.4MPa. The introduction of SICM 
particles at low content (q=0.2–0.5 wt.%) provides a decrease 
in residual stresses from 1.4MPa (for epoxy matrix) to 0.7MPa. 
Further increase in the particle content (q=0.7–2.0 wt.%) leads 
to an increase in the value of residual stresses in the protective 

coatings to σr=0.8–1.0MPa. Comparing the values of adhesive 
strength and residual stresses depending on the content of 
particles, we can state the following: The highest values of 

adhesive strength (σа=44.7MPa) among the whole range of test 
materials is a composite containing filler in the amount of 
q=0.5 wt.%. At the same time, such a material is characterized 
by the lowest residual stresses, which are σr=0.7MPa. This 
indicates that the developed composite and the protective 
coating based on it can be used quite effectively to improve the 
performance of parts that work not only under static but also 
dynamic loads. Hence, the optimal content of the SICM for the 
formation of epoxy protective coating with maximum adhesion 
characteristics and low residual stresses was determined. It is 
proved that at the introduction of the powder in the amount of 
q=0.5 wt.% a material with the following properties is formed: 

adhesive strength at break σа=44.7MPa and residual stresses 

σr=0.7MPa. This provides an increase in the adhesion strength 
at break by 1.8 times and a decrease in residual stresses by 2.0 
times compared with the ultrasonically modified epoxy matrix. 

It should be noted that from a scientific and practical point 
of view it is interesting to study not only the adhesive 
properties of materials and residual stresses depending on the 



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content of SICM particles, but also the dynamics of mechanical 
characteristics at different amounts of active filler. Therefore, 
at the next stage, physical and mechanical properties of epoxy 
composites filled with SICM were studied. In particular, the 
modulus of elasticity and flexural stresses at bending and 
impact strength of the developed materials were analyzed. It 
has been experimentally established (Figure 2, curve 1) that the 
modulus of elasticity of the epoxy matrix modified by UPS is 
E=2.8GPa. The introduction of filler particles at low content 
(q=0.2–0.5 wt.%) does not change this characteristic of the 
CM, since the modulus of elasticity at bending is 2.6–2.8GPa 
(values within experimental errors). Further increase in the 
content of particles from 0.7 wt.% to 2.0 wt.% leads to a 
deterioration of the elastic properties of the CM. In particular, it 
was shown (Figure 2, curve 1) that at such loading the modulus 
of elasticity decreases from 2.8GPa (for epoxy matrix) to  
2.2–2.4GPa. Note that the modulus of elasticity characterizes 
not only the elastic characteristics of materials, but also their 
brittleness. From another point of view, high values of the 
modulus of elasticity indirectly indicate increased values of 
residual stresses in materials and a significant stress state in 
their structure. It can be a cause of premature failure of 
composites, especially under the action of shock loads. Taking 
into account the modulus of elasticity, it can be argued that the 
effective materials are composites filled with SICM particles in 
amounts of q=0.2–0.5 wt.%. 

 

 
Fig. 2.  Dependence of physical and mechanical properties of epoxy CM at 

the SICM content: 1 – elasticity modulus at bending (Е); 2 – flexural stresses 

at bending (σfl) 

According to the studied results of the dynamics of the 
values of flexural stresses at bending from the filler amount, 
the following can be stated: It was established (Figure 2, curve 
2) that the value of the flexural stresses of the epoxy matrix 

modified by USP was σfl=48.0MPa. It was proved that the 
introduction of SICM particles at low content (q=0.2–0.5 wt.%) 
leads to a monotonic increase in the value of flexural stresses 
from 48.0MPa (for the original matrix) to 67.2–84.9MPa. The 
maximum in the “flexural stresses at bending–filler content” 
curve was observed at 0.5 wt.% SICM content. The magnitude 

of the flexural stresses for such a material was σfl=84.9MPa. 
Further increase in the content of particles leads to a 
deterioration of the cohesive properties of composites. It has 
been shown (Figure 2, curve 2) that the loading of particles at a 
content of q=0.7–2.0 wt.% into the CM leads to a decrease in 

the flexural stresses from σfl=84.9MPa (for materials with a 

content of SICM 0.5 wt.%) to σfl=55.0–71.1MPa. The 
magnitude of the flexural stresses at bending indirectly 
indicates the plastic properties of the materials. As shown 
above, the modulus of elasticity, which characterizes the 
materials brittleness, for composites at a 0.5 wt.%. particle 
content is almost no different from the similar characteristic for 
the epoxy matrix. At the same time, the values of flexural 
stresses at bending of such CM are almost 2 times higher than 
the similar values of the matrix. Based on this, the effectiveness 
of the additives introduction at such content to improve the 
elastic-plastic properties of composites for different functional 
purposes can be argued. 

It should be noted that one of the problems of modern 
materials science is the creation of materials and protective 
coatings based on them, which can be operated under the 
influence of static and shock loads. Therefore, it was 
considered necessary to investigate the impact strength of 
materials with different filler content. It was experimentally 
found (Figure 3) that the impact strength of the epoxy matrix 
modified by UPS was W=7.4kJ/m

2
. Extreme dependence in the 

“W–q” values was observed when the SICM particles were 
loaded into the binder. Maximum values among the whole 
spectrum of the studied materials were observed for CM with a 
0.5 wt.% content of particles. The formation of such CM 
provides an increase in impact strength from 7.4kJ/m

2
 to 

13.0kJ/m
2
. Further increase in the particles content leads to a 

decrease in the impact strength of epoxy composites. In order 
to analyze the mechanism of destruction of materials under the 
influence of shock loads in detail, their fracture structure was 
additionally investigated by optical microscopy. It should be 
noted that the fracture surface of the specimens was analyzed 
with pre-selected content of dispersed particles in CM:  
q=0.2 wt.%, q=0.5wt.%, and q=1.0 wt.%. 

 

 
Fig. 3.  The dependence of the impact strength (W) on the SICM content 

(q) in CM: (a) matrix (control specimen), (b) 0.2 wt.%, (c) 0.5 wt.%, (d) 1.0 

wt.%, (e) 1.5 wt.% 

It is shown (Figure 4(a)) that the destruction of specimens 
filled with SICM particles at a content of 0.2 wt.%, occurs in 
an almost straight line. This is evidence that the material does 
not sufficiently resist external loads, and the crack propagation 
front is rectilinear. On the fracture surface of such samples, a 
grid of chipping lines is visible (Figure 4(b)-(c)), depressions 
and craters are observed, which is evidence of a sufficiently 



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tense state in such systems. It can be argued about the low 
reliability in the operation of such materials. 

 

 
(a) ×2 

  
(b) ×4 (c) ×4 

 
d) ×2 

  
(e) ×4 (f) ×4 

 
(g) ×2 

  
(h) ×4 (i) ×4 

Fig. 4.  Fractograms of CM fracture at different content of microdisperse 

filler SICM q per 100 wt.% of epoxy oligomer ED-20: (a)-(c) 0.2, (d)-(f) 0.5, 

(g)-(i) 1.0. 

On the contrary, for 0.5 wt.% content of particles the 
curvilinear nature of the fracture surface was observed (Figure 
4(d)). This allows to state about the increased cohesion 
characteristics of composites with filler at such content. The 
presence of particles in such CMs increases the resistance to 
the propagation of cracks during impact, as a result of which 
the trajectory of destruction of the specimens is wavy. 
Additional analysis of the images shown in Figure 4(d)-(e) 
allows to state the existence of a stress state in such systems, 
but the nature of the fracture is viscous, with noticeable petal-
shaped inclusions. This suggests the existence of areas with 
improved cohesive strength, which increases the durability of 
such materials during operation in critical conditions under the 
influence of shock loads. Analysis of the fracture surface of the 
specimens of the CM at 1.0 wt.% particle content allows assert 
about the rectilinear character of crack propagation during the 
destruction of materials (Figure 4(g)). At the same time, it 
should be noted that the fracture surface of such specimens is 
characterized by a tightly packed structure (Figure 4(h)-(i)), 
which indicates the improved cohesive properties of such 
materials. The use of such composites in the operation of 
equipment under the influence of shock loads can be argued. 

IV. CONCLUSION 

The optimal content of microdispersed filler of iron-carbide 
mixture synthesized by high-voltage electric discharge  
(d=15–18µm) for the formation of epoxy protective coating 
with improved adhesive and cohesive properties and 
insignificant residual stresses to increase the service life of 
transport parts was established. It has been found that when 
introducing particles of iron-carbide mixture in the amount of 
0.5 wt.% by 100 wt.% of ED-20 epoxy oligomer, a material 

was formed with adhesive strength at break σa=44.7MPa and 

residual stress σr=0.7MPa. This provides an increase, compared 
to the epoxy matrix modified by ultrasonic processing of the 
adhesion strength at break by 1.8 times and a decrease in 
residual stresses by 2.0 times. It is proven that the active 
centers of Fe, TiC and Fe3C, which are contained both in the 
volume and on the surface of the dispersed phase during the 
polymerization process, interact with the segments and pendent 
groups (OH-, CH-, C=O) of the epoxy oligomer. This increases 
the degree of crosslinking of the three-dimensional polymer 
net, which improves the adhesive properties of the composites. 
This is due to the fact that on the surface of the particles after 
synthesis areas of titanium and iron carbides, which are mainly 
activators of the formation of physical and chemical interfacial 
bonds in the structure of materials are localized. 

It has been established that the introduction of powder 
mixture particles in the amount of q=0.5 wt.% by 100 wt.% of 
epoxy oligomer ED-20 provides the formation of a material 
with the following properties: modulus of elasticity at bending 

E=2.7GPa, flexural stress at bending σfl=84.9MPa, and impact 
strength W=13.0kJ/m

2
. The formation of such a material 

provides a 1.8-times increase in the flexural stresses at bending 
and impact strength compared to the epoxy matrix modified by 
USP, while the modulus of elasticity was closely unchanged. 
For composites at a particle content in the amount of 
q=0.5 wt.% the curvilinear nature of the fracture surface was 
observed. This allows to state about the increased cohesion 
characteristics of materials at such filler content. The presence 
of particles in such a composite increases the resistance to the 
crack propagation during impact, as a result of which the 
trajectory of destruction of the specimen is wavy. This allows 
to assert the existence of areas with improved cohesive 
strength, which increases the durability of such materials 
during operation in critical conditions of impact loads. 

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