Surface charge and flashover voltage of EVA/CB nanocomposite under mechanical stresses

Ethylene-vinyl acetate (EVA) composite is widely used in cable accessories to uniform electric field and prevent partial discharge. However, local electric field distortion will cause charges accumulation and flashover, which is susceptible to the tensile strain upon the materials. Carbon Black (CB)...

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Bibliographic Details
Published in:IEEE transactions on dielectrics and electrical insulation 2016-12, Vol.23 (6), p.3734-3741
Main Authors: Du, B. X., Li, Jin, Du, Qiang, Fu, M. L.
Format: Article
Language:English
Subjects:
accessories
Carbon black
Carrier mobility
Current carriers
Decision support systems
Deformation effects
Electric charge
Electric fields
Electric potential
Electrical distortion
Electrical properties
Ethylene vinyl acetates
ethylene-vinyl acetate
Flashover
flashover voltage
HVDC cable
Nanocomposites
Nanoparticles
Permittivity
Polymer matrix composites
Power cables
Strain analysis
Stress
stretching deformation
Surface charge
Surface flashover
Tensile strain
trap distribution
Voltage
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Summary:Ethylene-vinyl acetate (EVA) composite is widely used in cable accessories to uniform electric field and prevent partial discharge. However, local electric field distortion will cause charges accumulation and flashover, which is susceptible to the tensile strain upon the materials. Carbon Black (CB) nanoparticles can be applied to adjust the electrical properties of polymer composite. The effects of the CB contents on the surface charge and flashover characteristics of EVA/CB nanocomposite under various tensile strains need further investigation. In this paper, samples were prepared by incorporating CB nanoparticles into EVA matrix with fraction of 0, 1, and 5 wt% respectively. Tensile strains of 5, 10 and 15 % were applied to provide three deformations, which were compared with the unstretched sample. The dependence of the relative permittivity, surface charge decay and flashover characteristics on the CB contents under various tensile strains were measured. The trap distribution and carrier mobility were calculated to analyze the tensile strain dependent surface flashover. Obtained results show that the surface flashover voltage decreases with the increasing tensile strains for all the samples. Moreover, the flashover voltage of the samples doping with 1 wt% CB nanoparticles is higher than the other samples. The combination effects of trap distribution and carrier mobility are responsible for the above results. The surface flashover is more prone to occurrence under higher tensile strain, which should draw enough concern for the security of power cable operation.
ISSN:1070-9878
1558-4135
DOI:10.1109/TDEI.2016.005846