Effects of electric partial discharges on the rheological and chemical properties of polymers used in HV composite insulators after railway service

Habas, Jean‐Pierre; Arrouy, J.-M.; Perrot, F.

doi:10.1109/tdei.2009.5293959

Cited by 17 publications

(10 citation statements)

References 48 publications

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“…In other words, porcelain has a weak bonding force between its molecules, unlike heat tempered glass and silicone (silicone has a strong bonding force between its molecules made from oxygen and silicon). Thus, this chemical structure plays a main role in the electrical and dielectric properties of these materials [25].…”

Section: Experimental Results Analysismentioning

confidence: 99%

An Experimental Study Followed by a Development and a Comparison of Regression Models for Predicting TJ Electric Discharge in Insulators

Saim

Bitam-Megherbi

2021

mjee

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Section: Experimental Results Analysismentioning

confidence: 99%

An Experimental Study Followed by a Development and a Comparison of Regression Models for Predicting TJ Electric Discharge in Insulators

Saim

Bitam-Megherbi

2021

mjee

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“…In fact, during surface electrical discharge due to a significant increase in temperature, both degradation of the matrix polymer and dehydration of the ATH-like filler present in the compound can happen. 44,89−92 Therefore, it may be concluded that the second stage decomposition temperature measured through TGA for a housing material is related to its service life.…”

Section: Resultsmentioning

confidence: 99%

“…However, the housing material may be exposed to a much higher temperature well beyond 170 °C, the highest aging temperature for a very short duration during electrical discharges. 44,89−92…”

Section: Resultsmentioning

confidence: 99%

Degradation and Stability of Polymeric High-Voltage Insulators and Prediction of Their Service Life through Environmental and Accelerated Aging Processes

Ghosh

Khastgir

2018

ACS Omega

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Polymeric composite insulators consisting of core fiber reinforced polymer insulators covered with polydimethylsiloxane (PDMS) housing are now replacing conventional ceramic insulators especially for high-outdoor power transmission lines due to some specific advantages. Unlike ceramics, polymers have relatively shorter life. Outdoor insulators experience different electrical, mechanical, chemical, and thermal stresses during service. The long-term service performance of these insulators and their service life estimation is an important issue, but it is complicated and time-consuming. The objective of the present investigation is to check the rate of property deterioration during service and to find the approximate lifetime. Working insulators with different ages were collected from service, and the changes in mechanical and electrical properties and hydrophobicity of the PDMS cover against aging time were measured. The service life estimated from the change in mechanical properties and surface hydrophobicity (using MATLAB software) was compared with the service life of a new compound subjected to accelerated aging tests. Prediction of service life is helpful for replacement of aged insulators from service to avoid interruption in power transmission.

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“…This could be the main reason that leads to tracking due to its lowest activation energy. Furthermore, a reduction in the percentage of C‐H and pyrolysis of sulphuric components (‐S) are likely to facilitate the ignition of a conducting path and gas by‐products such as SO 2 and H 2 S [26]. As concerns HDPE, its resistance to tracking in salt fog is better than that in clean fog probably due to a higher leakage current magnitude that dries quickly the moisturised surface and inhibits FOV arcs.…”

Section: Discussionmentioning

confidence: 99%

Assessment of the resistance to tracking of polymers in clean and salt fogs due to flashover arcs and partial discharges degrading conditions on one insulator model

Douar

Béroual

Souche³

2016

IET Generation, Transmission & Distribution

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International audienceThis paper describes the assessment of the resistance to tracking of various polymers after (i) flashover voltage (FOV) and flashover gradient (FOG); and (ii) partial discharges (PDs) measurements in dry, clean and salt fogs on one insulator model using standardised electrodes; the aim being the development of optimised methods based on flashover and PDs to the conception of new generation of piercing connectors. The investigated materials belong to two distinct classes widely used in the electrical industry: thermoplastics (namely polyphenylene sulfide and high density polyethylene) and thermosetting cycloaliphatic epoxy resins namely one unfilled material (UnCEP) and another unfilled and hydrophobic resin (UnHCEP). FOV measurements are based on the electro-geometrical parameters of each specimen and the resistance to tracking, both may be assessed through the slope of FOV curves against the leakage distance as an indicator of surface damages. Regarding PDs, the suggested technique is devoted to clean and salt fogs and provides quicker and more accurate information about PDs effects on materials deteriorations rather than IEC60109 where the exposition time to discharges is much longer at lower voltage levels by using only liquid contaminants such as sulfuric or nitric acids or ammonium chloride as described in IEC60587 or ASTM D2303

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Effects of electric partial discharges on the rheological and chemical properties of polymers used in HV composite insulators after railway service

Cited by 17 publications

References 48 publications

An Experimental Study Followed by a Development and a Comparison of Regression Models for Predicting TJ Electric Discharge in Insulators

An Experimental Study Followed by a Development and a Comparison of Regression Models for Predicting TJ Electric Discharge in Insulators

Degradation and Stability of Polymeric High-Voltage Insulators and Prediction of Their Service Life through Environmental and Accelerated Aging Processes

Assessment of the resistance to tracking of polymers in clean and salt fogs due to flashover arcs and partial discharges degrading conditions on one insulator model

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