Please use this identifier to cite or link to this item: http://dspace.iitrpr.ac.in:8080/xmlui/handle/123456789/446
Title: Superior dielectric breakdown strength of graphene and carbon nanotube infused nano-oils
Authors: Dhar, P.
Katiyar, A.
Maganti, L.S.
Pattamatta, A.
Das, S.K.
Keywords: Dielectric breakdown
Dielectric liquids
Nanofluid
Graphene
Carbon nanotubes (CNT)
Transformer oil
Analytical formulation
Issue Date: 18-Nov-2016
Abstract: Nano–oils comprising stable and dilute di spersions of synthesized Graphene (Gr) nanoflakes and carbon nanotubes (CNT) h ave been experimentally observed for the first time to exhibit augmente d dielectric breakdown strengt hs compared to the base transformer oils. Variant nano–oils comp rising different Gr and CNT samples suspended in two different grades of transfo rmer oils have yielded consistent and high degrees of enhancement in the breakdown strength. The apparent counter–intuitive phenomenon of enhancing insulating caliber of fluids utilizing nanostructures of high electronic conductance has been shown to be physically consistent thorough theoretical analysis. The crux mechanism has been pin pointed as efficient charge scavenging leading to hampered streamer growth and development, thereby delaying probability of complete ionization. The mathematical an alysis presented provides a comprehensive picture of the mechanisms and physics of the electrohydrodynamics involved in the phenomena of enhanced breakdown strengths. Furthermore, the analysis is able to physically explain the various breakdown ch aracteristics observed as functions of system parameters, viz. nanostru cture type, size distribution, relative permittivity, base fluid dielectric properties, nanomaterial concentration and nano–oil temperature. The mathematical analyses have been extended to propose a physically and dimensionally consistent analytical model to predict the enhanced breakdown strengths of such nano– oils from involved constituent material pr operties and characteristics. The model has been observed to accurately predict th e augmented insulating property, thereby rendering it as an extremely useful tool for efficient design and prediction of breakdown characteristics of nanostructu re infused insulating fluids. The present study, involving experimental investigations ba cked by theoretical analyses and models for an important dielectric phenomenon such as electrical breakdown can find utility in design of safer and more efficient high opera ting voltage electrical drives, transformers and machines.
URI: http://localhost:8080/xmlui/handle/123456789/446
Appears in Collections:Year-2016

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