Article


 

  AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 132–135 
 

   

       Contents lists available at http://qu.edu.iq 

 

Al-Qadisiyah Journal for Engineering Sciences 

  
Journal homepage: http://qu.edu.iq/journaleng/index.php/JQES  

  

 

* Corresponding author.  

E-mail address: hadeelalobaidi90@gmail.com ( Hadeel A. Alobaidi) 

 

https://doi.org/10.30772/qjes.v15i2.824  

2411-7773/© 2022 University of Al-Qadisiyah. All rights reserved.                                This work is licensed under a Creative Commons Attribution 4.0 International License. 

 

 Influence of heat aging on tensile test in rubber-epoxy composites 

Hadeel A. Alobaidi* and Nabeel Almuramady 

Department of Mechanical Engineering, College of Engineering,  University of Al-Qadisiyah, Iraq 

 

A R T I C L E I N F O 

Article history:  

Received 13 May 2022 

Received in revised form 10 June 2022 

Accepted 5 July 2022 

 

Keywords: 

Heat Aging  

Natural Rubber  

Epoxy Resin 

Tensile test 

 

A B S T R A C T 

Composite materials using natural rubber as the main matrix are popular these days because of the wide 

applications of rubber materials in modern industries. Rubber materials also have damping properties, 

energy absorption, and exposure to continuous loads and different environmental conditions. In this 

research, the effect of temperatures on the rubber-epoxy composite with different ratios (0%, 10%, 20%, 

30%, 40%, and 50%) of epoxy has been studied. Where comparison was made between heat-aged and un-

aged samples using the tensile test. To know the effect of high temperatures on the rubber-epoxy composite, 

it was done in a heated oven at a temperature of 70◦C. The results obtained from the tensile test observed a 

decrease in tensile strength and elongation when exposed to thermal aging. 

 

 

 

© 2022 University of Al-Qadisiyah. All rights reserved.    

1. Introduction 

        Natural rubber has been widely used in the twentieth century and that 

has led to a huge increase in its sophisticated applications. Thus, the 

industrial rubber sector was resorted to in World War II, because of its ideal 

characteristics such as flexibility, lightweight, resistance, deformation 

capacity, or vibration isolation. It was also used as a basic material in 

composite materials, in which natural rubber is blended with various 

additives to make it more suited for the applications for which it was 

designed [1-5]. 

Rubber composites' mechanical characteristics are affected by temperature 

and time. Where the crosslinking and chain disintegration are both caused 

by thermal aging. The expandability decreases and the modulus of the 

material increase due to the crosslinking. The unsaturated carbon-carbon 

double bonds in the backbone of rubbers make them sensitive to oxidative 

aging. This type of oxidative aging is generally aided by high temperatures 

[6, 7]. 

Toughened epoxy has a popular addition in research because of its ability 

to boost composite strength. Epoxy resins have a hard form, an anti-slip 

coating, minimal cure shrinkage and good electrical properties. Also, its 

compatibility with a wide range of materials, dependability, and the ability 

to cure under adverse conditions. It is also employed as an adhesive in 

composites Almuramady, et al. [8]. Potting, building construction, 

chemical-resistant equipment, weathering, boats, and other applications, 

thus it has acquired widespread popularity in the industrial field over the 

last 20 years [9, 10]. 

 The effect of temperature on rubber compounds was one of the important 

topics that many scientists touched upon, as the increase in the temperature 

of rubber leads to a loss of its ductility and ability to dampen and increase 

its hardness as a result of repeated use for a long time, which affects the life 

of the sample. Among the characteristics that were affected by aging was 

the ability of the material to stretch and elongate and that will be addressed 

in this research [11-13]. 

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https://doi.org/10.30772/qjes.v15i2.824
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HADEEL ALOBAIDI AND NABEEL ALMURAMADY. /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 132–135                                                    133 

 

2. Experimental work 

2.1. Materials 

The practical side was implemented in several stages where natural rubber 

was used as a matrix material in this work, and (epoxy resin) and (carbon 

black) were used as reinforcing materials. 

First step: The natural rubber paste was prepared by adding (carbon black) 

only as a hardener with what is mentioned in Table 1 below, where the work 

was done in the General Company for Tire and Rubber Industry in 

Diwaniyah - Iraq. 

Table 1. Materials used in the preparation of rubber dough without 

epoxy. 

material Occupation 

Rubber RSS1 basic material 

zinc oxide tonic 

stearic acid tonic 

sulfur vulcanization agent 

DCBS Accelerator  accelerated 

TBBS Accelerator accelerated 

N₃₂₆ reinforcement filling 

N₁₁ₒ reinforcement filling 

Renacit digestive substance 

Struktol 40 ms homogenizing substance 

Wax Oxidation protection 

IPPD Oxidation protection 

Escorez 1102 Adhesive 

Resorcinol melt Adhesive 

PVI  cathodic substance 

HMT Adhesive 

 

Second step: is to mix natural rubber with epoxy, where the epoxy is first 

prepared. 

The epoxy that was used in this work is sikadur-52 produced by sika Egypt 

for construction chemicals and consists of two components of high grade, 

low viscosity (1000-250) MPa.s, yellow in color, density at 20°C is about 

1.1 kg/l and has a mixing ratio of 2R:1H based on weight. 

At room temperature (25°C), the epoxy resin and the hardener were mixed 

manually in a ratio of 2R:1H. Mixture has been mixed and moved 

continuously until it becomes homogeneous and air bubbles have been 

disappear, then it was added to the natural rubber in different proportions 

(0%, 10%, 20%, 30%, 40%, and 50%) of epoxy. 

2.2. Samples Preparation  

After the dough preparation, it was placed in the rolling machine Fig. 1a to 

make it a more homogeneous dough. Equipment’s have been used to 

control the distance between the two rollers so that the distance ranges from 

the lowest distance of 2 mm to the highest distance of 8 mm, and the final 

thickness of the dough that got from the rolling machine was 3mm. then 

The dough has placed in the heat press Fig. 1b by using special molds for 

testing, under ideal conditions (pressure of 3.5 MPa and temperature of 146 

°C for a period ranging from 15 to 20 minutes) to obtain vulcanized 

composite rubber. 

 

a                                                    b 

 

Figure 1.  (a) The rolling machine;  (b) Heated press machine 

 

2.3. Tensile testing 

In order to prepare tensile specimens, a special mold has been used to obtain 

a composite material specimen with the required dimensions to fit with the 

tensile test device. The template which was used to obtain the tensile 

samples are shown in Fig. 2 Tensile test has been studied according to 

ASTM D638 − 14 Type IV [14, 19]. 

 

 

 

 

Figure 2. Tensile test specimen according to ASTM D638 − 14  

Type IV. 

 



134                     HADEEL  ALOBAIDI AND  NABEEL ALMURAMADY. /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 132–135 

 

The tensile test was performed at room temperature in the laboratories of 

the University of Babylon / College of Materials, using a microcomputer-

controlled electronic universal testing machine) of Chinese origin, model 

(WDW-5E) that was controlled by a computer, shown in Fig. 3. The force 

was applied (load control) at a speed of 100 mm / min until a failure of the 

sample was occurs and then the stress-strain curve was plotted. 

 

 

Figure 3. Tensile test device. 

2.4. Aging test 

Some samples of dumbbells were taken and placed in an aging oven (O7E 

Multi-cell Aging Oven) produced by Wallace Test Equipment Company 

according to ASTM D573-99 specification [15]. Where the oven consists 

of 7 cells isolated from each other to prevent contamination of the knees 

with volatile materials [16-18]. The samples have been placed for 7 days at 

a temperature of 70 degrees Celsius by means of an automatic timer and as 

in Fig. 4. Where the work was done in the General Company for Tire and 

Rubber Industry in Diwaniyah - Iraq. To find out the effects of thermal 

aging on the rubber compound and the extent of its resistance to wear over 

time, a tensile test was conducted for the aged samples and compared with 

the tensile test for the original unaged samples. 

Figure 4. The oven aging. 

3. Results and discussions 

The 24 tests of the successful tests have been conducted to calculate the 

tensile resistance of natural rubber composite mixed with epoxy resin with 

different ratios (0%, 10%, 20%, 30%, 40%, and 50%) of epoxy. where the 

results test for all the percentages were compared with the purely natural 

rubber sample. as shown in Fig. 5, represents a graph of the true stress-

strain curve of the rubber-epoxy compound. Where a discrepancy was 

observed in the results between the different percentages of the rubber-

epoxy composite that was not aged by heat. Where an increase in stress was 

observed as the percent of epoxy increased, and decrease in elongation 

when the epoxy ratio increased and this was due to the hardness property 

of epoxy, which increases the hardness of the composite, which makes it 

resistant to stress and elongation. 

 

 

 

Figure 5. Stress-strain curve. 

Fig 6. Represents the difference in tensile strength between the composites 

that have different percentages of epoxy (0%, 10%, 20%, 30%, 40%, and 

50 %) of the samples that were tested in the tensile testing device without 

aging and the samples that were tested in the tensile device and were aged 

in an air oven. Where we notice a discrepancy in the results, where the 

results are divided into two parts, the first part, in which the tensile strength 

and elongation are in a descending state, i.e. decreasing with the increase in 

the percentage of epoxy. As for the second part, there is an increase in 

tensile strength with a decrease in elongation when the ratio of epoxy in the 

composite increases for the first test (without aging).  

As for the second test (samples that were previously aging), noticed a 

discrepancy in the results, as the effect of the rubber-epoxy composite, was 

observed in temperature as in Figs 6 and 7, where a decrease in the values 

of stress resistance and elongation when the ratios of epoxy resin increase 

more than the test the first. But when the epoxy ratios were increased to 

40% and 50%, there was an increase in the stress resistance for the samples 

that were aging, however less than in the first test. This change was 

attributed to the effect of increasing the amount of epoxy in the composite 

and also to the effect of the high temperatures on the composite, which 

affected it was viscous properties and decreased and hardness slightly. 

  

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HADEEL ALOBAIDI AND NABEEL ALMURAMADY. /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 132–135                                                    135 

 

 

 

Figure 6. Effect the heat aging on the max tensile strength. 

 

 

Figure 6. Effect the heat aging on the elongation. 

4. Conclusion 

In this research, the effect of temperatures on the rubber-epoxy compound 

with different epoxy resin ratios (0%, 10%, 20%, 30%, 40%, and 50%) were 

studied. The original samples were compared with the heat-aged samples 

by conducting a tensile test for them. A decrease in the tensile strength and 

elongation of the samples was indicated in the beginning by an increase in 

the percentage of epoxy, then it will be increased with an increase in the 

epoxy ratio. Also, a discrepancy was observed in the results with the heat-

aged samples due to the added quantities of epoxy rubber and it was the 

effect of high temperature. And due to the rubber being also affected by 

heat for periods and loss of flexibility, Ali [8]. 

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[14] Standard Test Method for Tensile Properties of Plastics, Designation: D638 − 14. 

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[19] https://www.alibaba.com/product-detail/ASTM-D412-Rubber-Plastic-

Dumbbell-Tensile_60827990137.html 

 

 

 

 

 

 

 

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https://www.alibaba.com/product-detail/ASTM-D412-Rubber-Plastic-Dumbbell-Tensile_60827990137.html
https://www.alibaba.com/product-detail/ASTM-D412-Rubber-Plastic-Dumbbell-Tensile_60827990137.html