Engineering, Technology & Applied Science Research Vol. 7, No. 4, 2017, 1737-1740 1737  
  

www.etasr.com Sykaras et al.: A Study of SiR/EPDM Mixtures for Outdoor Insulators 
 

A Study of SiR/EPDM Mixtures for Outdoor 
Insulators  

 

A. Sykaras 
Democritus University of 

Thrace, Department of 
Electrical and Computer 

Engineering, Xanthi, 
Greece 

 V. Rajini 
SSN College of 

Engineering, Department 
of Electrical and 

Electronics Engineering, 
Chennai, India 

 M. G. Danikas 
Democritus University of 

Thrace, Department of 
Electrical and Computer 

Engineering, Xanthi, 
Greece 

 R. Sarathi 
Indian Institute of 

Technology Madras, 
Department of Electrical 
Engineering, Chennai, 

Tamil Nadu, India 
  

 
Abstract—This paper deals with the flashover voltages on 
samples of silicone rubber/ethylene propylene diene monomer 
(SiR/EPDM) mixtures under the influence of a uniform electric 
field. Five different mixtures of SiR/EPDM were investigated. 
Various SiR/EPDM mixtures (100% EPDM, 10% SiR + 90% 
EPDM, 30% SiR + 70% EPDM, 50% SiR + 50% EPDM, 70% 
SiR + 30% EPDM, 90% SiR + 10% EPDM, 100% SiR) were 
tested for different water droplet arrangements, different water 
conductivities, different droplet volumes as well as different 
droplet positioning w.r.t. the electrodes. The 50% SiR + 50% 
EPDM mixture proved to be the best mixture regarding the 
flashover voltage. 

Keywords-SIR; EPDM; insulators; high voltage; polymeric   

I. INTRODUCTION  
Polymeric outdoor insulators are in use in the past few 

decades [1]. One of the most popular insulating materials for 
this application is silicone rubber [2]. Lately, efforts have been 
undertaken in order to combine mixtures of silicone rubber 
(SiR) with ethylene propylene diene monomer (EPDM), which 
is also a good insulating material. SiR has excellent 
hydrophobicity [2] and it performs very well in polluted areas, 
whereas it lacks in mechanical strength. EPDM has high 
mechanical strength but its resistance to UV radiation is not 
that good and it seems to loose, as time passes by, its 
hydrophobicity [3]. An admixture of the two aforementioned 
materials may be a good way of having a new polymer with 
improved properties, both electrical and mechanical. Mixtures 
of the two materials in various proportions have been studied in 
[4].  Hydrophobic surfaces are characterized by a low surface 
energy. On hydrophobic surfaces, water forms discrete droplets 
and, consequently, leakage currents are minimized and the 
formation of dry zones becomes more difficult [3]. As a result, 
the probability of flashover is reduced. The main characteristic 
of hydrophobicity is the contact angle. The lower the surface 
energy of the insulating surface, the larger the contact angle θ 
[5]. Needless to say that, a hydrophobic surface presents a 
contact angle of more than 900 whereas a hydrophilic surface 
has a contact angle of less than 900. 

 On polymeric surfaces, the shape of water droplets 
depends on the surface material, the surface pollution, the 

surface deterioration, the droplet conductivity, the surface 
roughness, the charging of the droplet as well as the angle of 
the insulator sheds [6]. It has been reported elsewhere that the 
larger the droplet volume, the smaller the contact angle 
becomes, and consequently, the probability of a flashover 
increases [6]. The electric field distribution is greatly affected 
by the presence of a droplet on an insulating surface. It is 
already noted that the field lines inside the droplet are less 
dense because of the high dielectric constant of water. An 
intensification of electric field is observed at the triple junctions 
(where the three materials, air/droplet/silicone rubber, meet) [6, 
7]. 

 When a uniform electric field is applied, a water droplet 
(not charged) begins to oscillate at a certain field value. The 
oscillation frequency may be twice as much of that of the 
applied voltage. As the voltage increases, the oscillation 
becomes even more pronounced until a flashover ensues. With 
a charged droplet, the shape of the droplet –as the voltage 
increase– becomes asymmetrical and the oscillation frequency 
is the same with that of the applied voltage [6].  In the context 
of the present paper, various mixtures of SiR/EPDM (100% 
EPDM, 10% SiR + 90% EPDM, 30% SiR + 70% EPDM, 50% 
SiR + 50% EPDM, 70% SiR + 30% EPDM, 90% SiR + 10% 
EPDM, 100% SiR) were investigated, with the purpose to see 
which of them presented the highest flashover voltage. In order 
to observe this, a uniform electrode arrangement was used. 
Since the flashover voltage is affected by the presence of 
humidity (water droplets) on the surface of an insulator, water 
droplets of various conductivities and volumes were placed on 
the surface of the samples. 

II. SIR/EPDM MIXTURES 
Silicone rubber is widely used for outdoor insulation 

because of its excellent hydrophobicity, good resistance to 
oxidation and ozone as well its perseverance in higher 
temperatures. Moreover, it is thermally stable and it functions 
well under polluted conditions. It is, however, more expensive 
than other insulating materials and it has a smaller mechanical 
strength. EPDM performs well under high temperatures and 
humidity, it presents small dielectric losses and very good 
dielectric strength, it is resistant to corona discharges and it is 



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www.etasr.com Sykaras et al.: A Study of SiR/EPDM Mixtures for Outdoor Insulators 
 

less expensive compared to silicone rubber. It is, however, 
sensitive to UV radiation and to pollution and it is less 
thermally stable in comparison to SiR. It is intended that a 
combination of the two aforementioned materials may give 
improvements regarding the mechanical strength, the resistance 
to UV radiation and to oxidation and ozone, the thermal 
stability, the hydrophobicity and the cost [6, 8, 9]. It has been 
observed that, generally speaking, the electrical properties 
improve with the increase of SiR in the mixture. Regarding the 
mechanical properties, the tensile strength decreases with the 
percentage increase of SiR, in other words, a percentage 
increase of SiR implies a reduction of mechanical strength. 

Data published elsewhere, regarding the relation between 
the various percentages of SiR/EPDM mixtures with important 
quantities, such as tracking resistance, tensile strength, 
dielectric strength, surface resistivity, volume resistivity, arc 
resistance and dielectric constant, indicated that there is an 
interplay between the percentages of the two materials w.r.t. 
the above properties [4].  Referring to the experimental data of 
[4], it is understandable that the mechanical strength of SiR can 
be considerably increased with the addition of EPDM. A 
SiR/EPDM mixture renders somehow worse electrical 
properties – in comparison to a 100% SiR – but such a decrease 
is not that big when the addition of EPDM is not more than 
50%. Mixtures having equal quantities of SiR and of EPDM 
present good electrical and mechanical properties. An addition 
of more than 50% EPDM is not to be recommended because of 
a significant degradation of the electrical properties. Mixtures 
with more than 70% SiR present excellent electrical properties 
but their mechanical strength is not that satisfying. 
Furthermore, mixtures of 50% SiR + 50% EPDM are less 
expensive than “pure” SiR. 

III. EXPERIMENTAL EQUIPMENT 
For the experiments, a dry transformer was used giving 

voltages up to 24 kV. A horizontal wooden surface was used 
for putting the samples. Two copper electrodes were used. In 
the photographs shown in Figure 1 the power supply, the 
electrodes and the horizontal wooden surface, on which the 
experiments were performed, can be seen. The insulating 
materials used in the context of the present paper are given in 
Table I. 

 

 
Fig. 1.  Experimental set-up 

TABLE I.  MIXTURE COMPOSITION 

Blend Percentage in SiR Percentage in EPDM 
A 90% 10% 
B 70% 30% 
C 50% 50% 
D 30% 70% 
E 10% 90% 

IV. CONDUCTIVITIES, DROPLET ARRANGEMENTS AND 
EXPERIMENTAL PROCEDURE 

Water droplets of various conductivities were used, from 
almost distilled water (1.4 μS/cm) up to 10000 μS/cm 
(conductivities used were: 1.4 μS/cm, 100 μS/cm, 200 μS/cm, 
500 μS/cm, 1000 μS/cm, 2000 μS/cm, 5000 μS/cm and 10000 
μS/cm). The droplets arrangements are shown in Figure 2. In 
the top arrangement (with one droplet) has a volume of 0.1 ml, 
at a distance of 1.25 cm from the electrodes. In the bottom 
arrangement, the two droplets have each volume of 0.05 ml, 
and their distance from the respective electrodes is 0.8 cm. The 
electrodes in all experiments were at a distance of 2.5 cm from 
each other.  

 

Fig. 2.  Water droplet arrangements 

After positioning the droplets on the polymer surface, the 
voltage was slowly raised until flashover occurred. After that 
and after cleaning the surface and positioning new droplets on 
it, the voltage was raised up to the previous flashover value 
minus 1.2 kV, so that no new flashover would occur. At this 
voltage value, the arrangements could stay for 5 min. If no 
flashover occurred, the voltage was raised by 0.4 kV and the 
procedure was repeated until flashover occurred. The new 
flashover value was recorded. The reason for allowing the 
voltage for 5 min at each voltage level was because a ceratin 
time was required for the droplets to deform and for the PD to 
start. The deformation of a single droplet can be seen in Figure 
3. In Figure 4, the successive phases of formation of an arc are 
given for a single droplet of 1000 μS/cm on sample C. 

The oscillations of droplets on samples rich in SiR 
(mixtures A and B) are more intense because of their better 
hydrophobicity, i.e. for a constant droplet volume, in 
hydrophobic materials, the contact angle is large and the 



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www.etasr.com Sykaras et al.: A Study of SiR/EPDM Mixtures for Outdoor Insulators 
 

contact surface small and, consequently, the droplet oscillates 
more.  The flashovers on samples rich in SiR are more intense, 
thus forming bigger arcs. An increase in droplet volume, in 
droplet number as well as in water conductivity, leads to a 
flashover in lower voltages. Increase of conductivity, and 
especially at values of 5000 μS/cm and 10000 μS/cm, causes 
deterioration of the sample surface. Samples rich in EPDM 
show more intensive deterioration (especially in the higher 
water conductivities), as is shown in Figure 5. Rich in EPDM 
samples showed a reduction of flashover voltage because of the 
deterioration of their surface. 

 

 
Fig. 3.  Deformation of a single droplet on sample A (droplet conductivity 

1.4 μS/cm) 

 
Fig. 4.  Arcing of a single droplet on sample C 

 

 
Fig. 5.  The state of the samples after the experiments.  

V. EXPERIMENTAL RESULTS AND DISCUSSION 
  Figure 6 refers to flashover voltages for samples A, B, C, 

D, and E (Table I) and for a droplet volume of 0.1 ml at a 
distance of 1.25 cm from the electrodes. Figure 7 shows 
flashover voltages for samples A, B, C, D, and E for an 
arrangement of two droplets, each of 0.05 ml at a distance of 
0.8 cm from the electrodes and also between them. From the 
above mentioned figures, it is evident that the influence of 
water conductivity on flashover voltage is prominent. No 

matter the droplet arrangement, the droplet volume or the 
droplet number, or even the sample composition, an increase in 
water conductivity leads to a decrease of flashover voltage. 
Droplet volume as well as droplet number effect was noted 
previously [10-13]. Larger droplet volume and/or droplet 
number leads to a lower flashover voltage [14-15. The 
beneficial effect of silicone rubber on EPDM was also noted 
recently [16]. 

 

 
Fig. 6.  Flashover voltage in terms of droplet conductivity with a 0.1 ml 

water droplet for the various mixtures 

 
Fig. 7.  Flashover voltage in terms of droplet conductivity with two 

droplets each of 0.05 ml for the various mixtures 

   It seems that mixture C (50% SiR - 50% EPDM) presents 
a satisfying flashover behavior. This is in accordance with [4], 
where it was shown that this mixture presented the best 
combination of electrical and mechanical properties. Mixtures 
D and B (Table 1) follow regarding the flashover behavior. 
Mixtures A (90% SiR – 10% EPDM) and E (10% SiR – 90% 
EPDM) present the worst behavior regarding the flashover 



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voltage. From the measurements performed in the context of 
this work, mixture C seems to electrically behave the best in 
comparison with the rest of the mixtures. This is perhaps due to 
the fact that the percentage 50% SiR – 50% EPDM preserves 
somehow in the best way the electric and mechanical properties 
of the constituent materials.  

   For future work, it is recommended a further series of 
experiments regarding surface discharges and flashover 
voltages, taking into account the surface roughness of the 
samples, the more detailed study of the contact angle for the 
various blends as well as the use of other electrode 
arrangements and larger samples. The latter will allow the 
probable use of larger water droplets, which in turn will give a 
more ample variety of results. 

VI. CONCLUSION 
  In the context of this paper, an investigation was 

performed for various mixtures of SiR and EPDM, regarding 
the flashover voltage. Experiments with water droplets of 
various conductivities under the influence of a uniform electric 
field indicated that the mixture having 50% SiR – 50% EPDM 
gives the most satisfactory data. This renders the 
aforementioned mixture a reliable candidate for industrial 
outdoor high voltage applications. 

ACKNOWLEDGMENTS 
The samples were prepared at SSN College of Engineering, 

Department of Electrical and Electronics Engineering, 
Chennai, Tamil Nadu, India. 

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