Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography
Abstract Of late, cross‐linked polyethylene insulated aerial bundled cables have replaced conventional copper conductors being resistant to electricity pilferage, offer lower maintenance costs and reduced power losses. However, in coastal areas, aerial bundled cables experience frequent insulation b...
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Wiley
2021-04-01
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| Series: | IET Generation, Transmission & Distribution |
| Online Access: | https://doi.org/10.1049/gtd2.12106 |
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doaj-058f94d8b29742d5a814955bc45a82f52021-07-14T13:25:16ZengWileyIET Generation, Transmission & Distribution1751-86871751-86952021-04-011581348135610.1049/gtd2.12106Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermographyMoez ul Hassan0Tariq Mairaj Khan1Sumayya Abbas2Muhammad Atayyab Shahid3Syed Talha Tariq4Faisal Amir5Department of Electronics & Power Engineering National University of Sciences & Technology Karachi Sindh PakistanDepartment of Electronics & Power Engineering National University of Sciences & Technology Karachi Sindh PakistanDepartment of Electronics & Power Engineering National University of Sciences & Technology Karachi Sindh PakistanDepartment of Electronics & Power Engineering National University of Sciences & Technology Karachi Sindh PakistanDepartment of Electronics & Power Engineering National University of Sciences & Technology Karachi Sindh PakistanDepartment of Electronics & Power Engineering National University of Sciences & Technology Karachi Sindh PakistanAbstract Of late, cross‐linked polyethylene insulated aerial bundled cables have replaced conventional copper conductors being resistant to electricity pilferage, offer lower maintenance costs and reduced power losses. However, in coastal areas, aerial bundled cables experience frequent insulation breakdown causing sudden cable failures leading to unexpected power shutdowns. Condition monitoring, employing sophisticated diagnostic techniques, has thus become a major requirement of the energy sector. The reported research work utilizes infrared thermography as one such candidate NDT technique. A novel framework is proposed to investigate the progressive shift in the statistical parameters of the temperature distribution in aerial bundled cables’ insulation, as it degrades over time. The cumulative distribution function of pixel intensity data from a healthy/ operational aerial bundled cable is first compared with a reported failed aerial bundled cable. A prominent difference in 0.9 cumulative distribution function values is observed in the temperature distributions. Therefore, 0.9 cumulative distribution function values are used for degradation quantification with respect to ageing. Degradation rates are then computed using periodically acquired thermographic data from operational aerial bundled cables, installed at two different locations in a coastal region, each subjected to different marine climate. The proposed technique proved effective in degradation rate assessment of insulation of operational aerial bundled cables. Consequently, the results achieved can also be utilized for remaining useful life prediction of these cables.https://doi.org/10.1049/gtd2.12106 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Moez ul Hassan Tariq Mairaj Khan Sumayya Abbas Muhammad Atayyab Shahid Syed Talha Tariq Faisal Amir |
| spellingShingle |
Moez ul Hassan Tariq Mairaj Khan Sumayya Abbas Muhammad Atayyab Shahid Syed Talha Tariq Faisal Amir Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography IET Generation, Transmission & Distribution |
| author_facet |
Moez ul Hassan Tariq Mairaj Khan Sumayya Abbas Muhammad Atayyab Shahid Syed Talha Tariq Faisal Amir |
| author_sort |
Moez ul Hassan |
| title |
Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography |
| title_short |
Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography |
| title_full |
Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography |
| title_fullStr |
Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography |
| title_full_unstemmed |
Degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography |
| title_sort |
degradation assessment of in‐service aerial bundled cables in coastal areas leading to prognosis using infrared thermography |
| publisher |
Wiley |
| series |
IET Generation, Transmission & Distribution |
| issn |
1751-8687 1751-8695 |
| publishDate |
2021-04-01 |
| description |
Abstract Of late, cross‐linked polyethylene insulated aerial bundled cables have replaced conventional copper conductors being resistant to electricity pilferage, offer lower maintenance costs and reduced power losses. However, in coastal areas, aerial bundled cables experience frequent insulation breakdown causing sudden cable failures leading to unexpected power shutdowns. Condition monitoring, employing sophisticated diagnostic techniques, has thus become a major requirement of the energy sector. The reported research work utilizes infrared thermography as one such candidate NDT technique. A novel framework is proposed to investigate the progressive shift in the statistical parameters of the temperature distribution in aerial bundled cables’ insulation, as it degrades over time. The cumulative distribution function of pixel intensity data from a healthy/ operational aerial bundled cable is first compared with a reported failed aerial bundled cable. A prominent difference in 0.9 cumulative distribution function values is observed in the temperature distributions. Therefore, 0.9 cumulative distribution function values are used for degradation quantification with respect to ageing. Degradation rates are then computed using periodically acquired thermographic data from operational aerial bundled cables, installed at two different locations in a coastal region, each subjected to different marine climate. The proposed technique proved effective in degradation rate assessment of insulation of operational aerial bundled cables. Consequently, the results achieved can also be utilized for remaining useful life prediction of these cables. |
| url |
https://doi.org/10.1049/gtd2.12106 |
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