Title :
Aging of silicone rubber under ac or dc voltages in a coastal environment
Author :
Gustavsson, T.G. ; Gubanski, S.M. ; Hillborg, H. ; Karlsson, S. ; Gedde, U.W.
Author_Institution :
Dept. of Electr. Power Eng., Chalmers Univ. of Technol., Goteborg, Sweden
fDate :
12/1/2001 12:00:00 AM
Abstract :
Material samples of silicone rubber with known differences in their composition, i.e. different filler content and extra silicone oil added, have been aged at the Anneberg field station on the west coast of Sweden. ac or dc voltage supplied to cylindrical samples at stress levels of 50 or 100 V/mm. The work includes laboratory examination of material changes together with on-site, visual observations and leakage current measurements. Material samplings for the laboratory tests were made after 18 months of electrical aging, which went on for one more year in order to gather further information on the long-term electrical performance of the material. The dominant aging factor was the level of the applied stress, independent of ac or dc voltage. The dc stressed samples showed a higher leakage current and exhibited larger surface degradation compared with samples exposed to ac voltage. The material parameter, an addition of extra silicone oil, initially led to an increase in adhesion of pollutants, whereas the overall performance was improved by the higher suppression of the leakage current related to oligomer diffusion. Samples with lower levels of alumina trihydrate (ATH) exhibited a delayed onset of degradation, but once damaged they degraded more rapidly than the specimens with a higher ATH content. Infrared spectroscopy showed that the ATH was completely consumed at the eroded surface regions. The aging of the surfaces was further assessed by X-ray photoelectron spectroscopy (XPS) and scanning electron microscopy (SEM). The low molar mass siloxanes present in the pollution layer were extracted and analyzed by size exclusion chromatography and gas chromatography-mass spectroscopy. The results indicated that the main degradation factor was thermal depolymerization activated by electrical discharges. Oxidative crosslinking of the silicone rubber, usually attributed to surface close corona discharges, appeared to have played a minor role
Keywords :
X-ray photoelectron spectra; chromatography; environmental degradation; environmental testing; insulation testing; insulator contamination; insulator testing; mass spectroscopic chemical analysis; scanning electron microscopy; silicone rubber; silicone rubber insulators; spectrochemical analysis; surface discharges; Anneberg field station; X-ray photoelectron spectroscopy; ac voltage; added silicone oil; aging; alumina trihydrate; applied stress level; coastal environment; cylindrical samples; dc voltage; degradation onset; electrical aging; eroded surface regions; filler content; gas chromatography-mass spectroscopy; infrared spectroscopy; laboratory tests; leakage current measurements; long-term electrical performance; low molar mass siloxanes; oligomer diffusion; oxidative crosslinking; pollutant adhesion; pollution layer; scanning electron microscopy; silicone rubber; size exclusion chromatography; surface corona discharges; surface degradation; thermal depolymerization; visual observations; Aging; Degradation; Laboratories; Leakage current; Petroleum; Rubber; Sea measurements; Stress; Surface contamination; Voltage;
Journal_Title :
Dielectrics and Electrical Insulation, IEEE Transactions on
