Surface Charge Dissipation Characteristics of Al2O3/Silicone Rubber Composites

Silicone rubber composite insulators represent a crucial component in the outdoor insulation of high-voltage equipment. However, the influence of dc electric field might lead to the accumulation of surface charge on insulators, potentially resulting in insulation failure. To enhance the dissipation...

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Bibliographic Details
Published in:IEEE transactions on dielectrics and electrical insulation 2024-10, Vol.31 (5), p.2556-2563
Main Authors: Wang, Feng, Hu, Dexiong, Zhong, Lipeng, Chen, She, Wang, Lanbo
Format: Article
Language:English
Subjects:
Al₂O
Electric potential
Electrodes
Flashover
Needles
Probes
Rubber
shallow trap
silicone rubber
surface charge
surface flashover
Surface treatment
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Summary:Silicone rubber composite insulators represent a crucial component in the outdoor insulation of high-voltage equipment. However, the influence of dc electric field might lead to the accumulation of surface charge on insulators, potentially resulting in insulation failure. To enhance the dissipation rate of surface charge on silicone rubber composite insulators, this article employs a needle-plate electrode to inject surface charges into silicone rubber, and then, the surface potential decay properties of nanoscale and microscale Al2O3/silicone rubber composites at concentrations of 10, 20, and 30 wt% are measured by using an electrostatic capacitance probe. The results show that the addition of nanoscale and microscale Al2O3 introduces new shallow traps in silicone rubber, thereby enhancing the dissipation rate of surface charge. Al2O3/silicone rubber composites with different concentrations reduce the time required to achieve a 30% decline in the average surface charge density, falling within the range of 25.41%-30.53%. While the addition of Al2O3 enhances the dissipation rate of surface charge, it concurrently results in a reduction of the surface flashover voltage. The negative dc surface flashover voltage of charged samples with pure silicone rubber, nanoscale Al2O3/silicone rubber composite, and microscale Al2O3/silicone rubber composite can be recovered to 89.44%, 97.41%, and 95.78% of uncharged samples, respectively.
ISSN:1070-9878
DOI:10.1109/TDEI.2024.3399173