Engineering, Technology & Applied Science Research Vol. 8, No. 6, 2018, 3502-3504 3502  
  

www.etasr.com Papadakis et al.: Surface Discharges and Flashover Voltages in Nanocomposite XLPE Samples 

 

Surface Discharges and Flashover Voltages in 

Nanocomposite XLPE Samples 
 

C. Papadakis 

Democritus University of Thrace 

Department of Electrical and Computer Engineering 

Power Systems Laboratory 

Xanthi, Greece 
 

 

M. G. Danikas 

Democritus University of Thrace 

Department of Electrical and Computer Engineering 

Power Systems Laboratory 

Xanthi, Greece 

Y. Yin 

Shanghai Jiao Tong University 

Department of Electrical Engineering 

School of Electronic, Information and Electrical 

Engineering, Shanghai, China 

 

C. Charalambous 

Democritus University of Thrace 

Department of Electrical and Computer Engineering 

Power Systems Laboratory 

Xanthi, Greece 

 

 

Abstract—DC cable insulation is a field of intensive research 

activity. Special attention is being given to polymer 

nanocomposites, as promising insulation for such cables. 

Relatively little is known regarding surface discharges and 

flashover voltages for the aforementioned materials.  In this 

paper, a comparison is made between samples of cross-linked 

polyethylene insulation with added MgO nanofillers and samples 

of pure polyethylene w.r.t. the behavior of surface discharges and 

flashover voltages in arrangements of water droplets of various 

conductivities on the said polymeric surfaces under the influence 

of uniform electric fields. Experimental evidence indicates that 

the flashover voltages of XLPE with MgO nanofillers are higher 

that the ones obtained with pure PE. 

Keywords-discharge; flashover; cable; XPLE; nanocomposite   

I. INTRODUCTION  

Power transmission through DC voltage becomes 
increasingly popular, especially in countries with extended 
areas, such as China or the USA. Recently, efforts are being 
undertaken in the direction of polymer nanocomposite 
insulation for DC applications [1-3]. A possible candidate for 
such applications is the cross linked polyethylene (XLPE) with 
added MgO nanofillers 0.5 wt%. Surface discharges and 
subsequent flashovers constitute, among others, a danger for 
such insulation [4]. In this paper, surface discharges and 
flashover voltages of the above mentioned polymer 
nanocomposite are compared with those of pure polyethylene 
(PE). Water droplets of various conductivities are put on the 
polymeric surfaces and the discharge phenomena are studied 
under the influence of uniform electric fields. 

II. EXPERIMENTAL SET-UP 

In the context of this work, a transformer with a rated 
voltage of 20 kV was used. The electrodes used were of brass 
and they are shown in Figure 1. The distance between the 
electrodes was set at 2.5 cm in all experiments. Uniform 
electric fields were applied in all experiments. The water 
droplets were positioned on the polymeric surface with the aid 
of a 10 ml syringe and a special arrangement consisting of a 
metallic frame and three rules, one of which had two laser 
indicators. The positioning of the droplets w.r.t. the electrodes 
can be seen in Figure 2. The insulation materials investigated 
were pure PE and XLPE with added MgO nanofillers (having 
0.5 wt% nanofillers). The water droplets were of the following 
conductivities: 0,8 μS/cm, 100 μS/cm, 200 μS/cm, 500 μS/cm, 
1000 μS/cm, 2000 μS/cm, 5000 μS/cm and 10000 μS/cm. Each 
single droplet has a 0.05 ml volume. 

 

 

Fig. 1.  The brass electrodes used for the experiments 



Engineering, Technology & Applied Science Research Vol. 8, No. 6, 2018, 3502-3504 3503  
  

www.etasr.com Papadakis et al.: Surface Discharges and Flashover Voltages in Nanocomposite XLPE Samples 

 

 

Fig. 2.  The various water droplet arrangements used 

The experimental procedure was the following: Once the 
water drops of specified volume and conductivity was placed 
on the insulating material in one of the aforementioned 
arrangements, the output voltage of the power supply was 
gradually increased until the flashover of the gap and the 
recording of the breakdown voltage. After cleaning the 
insulating surface with alcohol, we repeated the same 
procedure by increasing the voltage of the power supply until 
the last recorded value not to bring about the flashover of the 
gap was reduced by 1,2 kV. At this point we left the output 
voltage of the power supply steady for five minutes to provide 
the necessary time for the process of deformation of the drop to 
be developed, the occurrence of partial discharges and/or 
ultimately the flashover to occur. If there was no flashover, the 
voltage was increased at 0.4 kV steps until the occurrence of a 
flashover. This was the value of flashover voltage that was 
finally recorded. The parameters that were investigated were: 
1) the water droplet arrangements, 2) water conductivity, 3) 
water droplet volume, 4) the insulating material used and 5) the 
positioning of the droplets w.r.t. the electrodes. 

III. EXPERIMENTAL RESULTS AND DISCUSSION 

A water droplet on a polymeric surface is affected by the 
surface tension of the liquid, the surface tension of the solid, 
the interfacial tension between the droplet and the solid as well 
as by the applied electric field. The latter causes 
deformation/elongation of the droplet. Such deformation will 
affect the distribution of the electric field, which in turn will 
again act upon the droplet. There is a so to speak a feedback 
mechanism, which will eventually cause local field 
intensifications and microdischarges. Dry zones will ensue and 
finally the flashover will result [5]. In Figure 3, the flashover 
voltages of pure PE, for water droplet arrangements, such as 
those of Figure 2 (each water droplet of 0.05 ml volume), are 
shown with varying conductivity. It is evident that the two-
droplet horizontal arrangement gives the lower results, whereas 
the other three droplet arrangements seem to give more or less 
similar flashover voltages for the various conductivities, with 
the one droplet arrangement giving the best results and with the 

three droplet arrangement giving somehow lower flashover 
voltages in higher conductivities. Evidently the positioning of 
the droplets w.r.t. the electrodes plays a vital role in 
determining the flashover voltage. 

 

 
Fig. 3.  Flashover voltages for various droplet arrangements on PE 
surfaces 

In Figure 4, the flashover voltages for the XLPE with added 
MgO nanofillers are shown (each droplet having 0.05 ml 
volume). Again we observe that the two droplet horizontal 
arrangement gives the worst flashover voltages whereas the 
other three droplet arrangements give somehow similar 
flashover voltages. In this case again, the three droplet 
arrangement gives lower flashover voltages at higher 
conductivities.  

 

 
Fig. 4.   Flashover voltages for various droplet arrangements on XLPE 
surfaces with added MgO nanofillers 

If one compares Figures 3 and 4, it seems that XLPE with 
added nanofillers gives higher flashover voltages compared to 
pure PE, for all droplet arrangements and for all conductivities 
tested. Although the experiments performed in the context of 
the present work are not of long duration, one may see a 
difference between XLPE with nanofillers and pure PE. The 
reason as to why this should be so was given some years ago in 
[6-7], where it was proposed that with polymer 
nanocomposites, discharge activity tends to force the nanofilers 
(or agglomerations of them) to come onto the surface, 
hindering thus the propagation of surface discharges. Recent 
SAXS measurements of XLPE samples (with added 
nanofillers) as well as of pure PE samples showed that the 



Engineering, Technology & Applied Science Research Vol. 8, No. 6, 2018, 3502-3504 3504  
  

www.etasr.com Papadakis et al.: Surface Discharges and Flashover Voltages in Nanocomposite XLPE Samples 

 

surface of the former after discharging tends to be more 
compact [8]. This is in agreement with [6-7]. XLPE with MgO 
nanofillers after discharge shows increasing crystallinity, which 
again can be explained with increasing nanofillers 
agglomerates. The aforementioned interpretations seem to be in 
agreement with [9], where it was reported that there can be 
surface modifications of the nanocomposites and of the nature 
of the interface in the region around the nanofillers. These 
views are also shared in [10, 11]. It is true that the present 
research was carried out using AC voltages whereas it is 
intended that the tested materials will be used for DC 
transmission. Nevertheless, after the DC transmission the 
voltage has to be changed to AC, and this fact underlines the 
importance of studying the above materials also under AC 
conditions.  

Further steps towards a better clarification can be taken, 
such as more experiments with a larger variety of droplet 
arrangements, experiments with XLPE having various MgO 
nanofiller percentages and comparative contact angle studies 
between XLPE with MgO nanofillers and pure PE. Especially 
about the latter, there were reports that the addition of 
nanofillers in XLPE increases the contact angle [12]. The 
interpretation related to the hardening of the nanocomposite 
surface needs to be further explored, especially in view of 
recent research indicating that nanofillers may accelerate the 
dissipation of surface space charge, i.e. rapid charge dissipation 
may be due to high shallow trap density created by nanofillers. 
Shallow traps can capture electrons and fast electrons can be 
converted to slower electrons [13]. 

IV. CONCLUSIONS 

In this paper, indications that the XLPE with added 
nanofillers of MgO performs better than pure PE regarding the 
flashover voltage, were presented. This may be due to the 
gradual erosion of the base polymer and the coming onto the 
surface of the nanocomposite of the nanofillers (or 
agglomerations of them) which eventually hinder the further 
propagation of surface discharges. More experiments will 
further elucidate the phenomena of surface discharge and 
flashover in nanocomposites.  

ACKNOWLEDGMENTS 

The samples of the present work have been prepared at 
Shanghai Jiao Tong University by the group of Prof. Yi Yin. 

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