Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable
Polymeric-insulated power cables are often subjected to multiple sources of degradation. Generally, the main cause for electrical breakdown in this type of cable insulation is usually due to the microscopic impurities and defects located in the bulk, or even at the interfaces of the material. When t...
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my.uniten.dspace-302412024-04-17T10:42:24Z Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable Ariffin A.M. Kuan T.M. Sulaiman S. Illias H.A. 16400722400 49561583600 36562570400 26633053900 aging measurement techniques Aging Cables Dielectric Constant Electric Fields Impurities Insulation Interfaces Measurement Signals Techniques Aging of materials Cables Condition monitoring Electric fields Forestry Impurities Insulating materials Interfaces (materials) Permittivity measurement Polymers Signal detection Underground cables Cable insulation Characteristic impedance Degradation process Detection mechanism Electrical breakdown Electrical stress Insulation system Localized discharges Measurement techniques Micro voids Multiple source Power cables Presence of water TDR signals Time domain reflectometry Time-domain reflectometry techniques Time-domain signal Water trees Water-tree degradation Time domain analysis Polymeric-insulated power cables are often subjected to multiple sources of degradation. Generally, the main cause for electrical breakdown in this type of cable insulation is usually due to the microscopic impurities and defects located in the bulk, or even at the interfaces of the material. When the dielectric is subjected to a high electrical stress, imperfections such as protrusions, contaminants and microvoids, will all act as points where the electric field is enhanced; increasing the likelihood that degradation processes will be initiated. The intensification of electric field within the insulating material can cause localized discharge to occur continuously, and thus tree-like channels can be developed in the long-run. This paper attempts to investigate whether the existence of water tree region can be detected within polymeric-insulated cables, and the proposed method for the detection mechanism is the time domain reflectometry (TDR). When water trees are present within an insulation system, the characteristic impedance of the material also changes so this can cause reflection of signal propagating along the cable. It was found that there is a difference in TDR signals between un-degraded cable and water tree degraded cable. It is hoped that the difference in these time domain signals can actually assist in determining the location where the presence of water trees can be considered as significant. � 2012 IEEE. Final 2023-12-29T07:45:49Z 2023-12-29T07:45:49Z 2012 Conference Paper 10.1109/CMD.2012.6416367 2-s2.0-84874239657 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84874239657&doi=10.1109%2fCMD.2012.6416367&partnerID=40&md5=cb79bd423452014ad299d79fb8d12bf9 https://irepository.uniten.edu.my/handle/123456789/30241 6416367 1163 1166 Scopus |
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aging measurement techniques Aging Cables Dielectric Constant Electric Fields Impurities Insulation Interfaces Measurement Signals Techniques Aging of materials Cables Condition monitoring Electric fields Forestry Impurities Insulating materials Interfaces (materials) Permittivity measurement Polymers Signal detection Underground cables Cable insulation Characteristic impedance Degradation process Detection mechanism Electrical breakdown Electrical stress Insulation system Localized discharges Measurement techniques Micro voids Multiple source Power cables Presence of water TDR signals Time domain reflectometry Time-domain reflectometry techniques Time-domain signal Water trees Water-tree degradation Time domain analysis |
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aging measurement techniques Aging Cables Dielectric Constant Electric Fields Impurities Insulation Interfaces Measurement Signals Techniques Aging of materials Cables Condition monitoring Electric fields Forestry Impurities Insulating materials Interfaces (materials) Permittivity measurement Polymers Signal detection Underground cables Cable insulation Characteristic impedance Degradation process Detection mechanism Electrical breakdown Electrical stress Insulation system Localized discharges Measurement techniques Micro voids Multiple source Power cables Presence of water TDR signals Time domain reflectometry Time-domain reflectometry techniques Time-domain signal Water trees Water-tree degradation Time domain analysis Ariffin A.M. Kuan T.M. Sulaiman S. Illias H.A. Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| description |
Polymeric-insulated power cables are often subjected to multiple sources of degradation. Generally, the main cause for electrical breakdown in this type of cable insulation is usually due to the microscopic impurities and defects located in the bulk, or even at the interfaces of the material. When the dielectric is subjected to a high electrical stress, imperfections such as protrusions, contaminants and microvoids, will all act as points where the electric field is enhanced; increasing the likelihood that degradation processes will be initiated. The intensification of electric field within the insulating material can cause localized discharge to occur continuously, and thus tree-like channels can be developed in the long-run. This paper attempts to investigate whether the existence of water tree region can be detected within polymeric-insulated cables, and the proposed method for the detection mechanism is the time domain reflectometry (TDR). When water trees are present within an insulation system, the characteristic impedance of the material also changes so this can cause reflection of signal propagating along the cable. It was found that there is a difference in TDR signals between un-degraded cable and water tree degraded cable. It is hoped that the difference in these time domain signals can actually assist in determining the location where the presence of water trees can be considered as significant. � 2012 IEEE. |
| author2 |
16400722400 |
| author_facet |
16400722400 Ariffin A.M. Kuan T.M. Sulaiman S. Illias H.A. |
| format |
Conference Paper |
| author |
Ariffin A.M. Kuan T.M. Sulaiman S. Illias H.A. |
| author_sort |
Ariffin A.M. |
| title |
Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| title_short |
Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| title_full |
Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| title_fullStr |
Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| title_full_unstemmed |
Application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| title_sort |
application of time domain reflectometry technique in detecting water tree degradation within polymeric-insulated cable |
| publishDate |
2023 |
| _version_ |
1806423526631014400 |
| score |
13.214268 |