Abstract
This paper evaluates the potential usage of graphene/crosslinked polyethylene (graphene/XLPE) as the insulating material for high voltage direct current (HVDC) cables. Thermal, mechanical and electrical properties of blends with/without graphene were evaluated by differential scanning calorimetry (DSC), tensile strength, DC conductivity, space charge measurements and water tree aging test. The results indicate that 0.007–0.008% weight amount of graphene can improve the mechanical and electrical insulation properties of XLPE blends, namely higher tensile/yield strength, improved space charge distribution, and shorter/fewer water tree branches. The improvements mainly attribute to the high stiffness of graphene, deep traps introduced by the interaction zones of graphene and XLPE, and the blockage effect of graphene within XLPE. For thermal performance of XLPE blends, graphene nano-fillers have but limited improvement. The crystallinity of the blends barely changes with the addition of graphene. However, the crosslinking degree increases as the additive-like amounts of graphene doped. The above findings provide a guide for tailoring lightweight XLPE materials with excellent mechanical and electrical performances by doping them with a small amount of graphene.
Highlights
This paper evaluates the potential usage of graphene/crosslinked polyethylene as the insulating material for high voltage direct current (HVDC) cables
It is concluded that the addition of graphene has but limited improvement for the thermal performance of XLPE blends, mainly on crosslinking degree
Results indicate that XLPE filled with graphene nanoparticles exhibited excellent mechanical and electrical insulation properties, namely higher tensile/yield strength, improved space charge distribution, and shorter water tree branches
Summary
This paper evaluates the potential usage of graphene/crosslinked polyethylene (graphene/XLPE) as the insulating material for high voltage direct current (HVDC) cables. For cables in alternating current (AC) transmission system, crosslinked polyethylene (XLPE) has been widely used as their insulating material due to its high breakdown strength, low dielectric loss, good mechanical properties and improved thermal resistance[4,5,6]. Wang studied the effect of nano-TiO2 on DC XLPE cables, and found that adding a small amount of nano-TiO2 to XLPE can improve the dielectric properties of polymers, including the crystallinity, conductivity activation energy and DC breakdown strength[16]. Recent studies on graphene indicated it being a promising nanoparticle filler to improve the electrical and thermal properties of dielectrics, though its effect on the mechanical properties has not been investigated y et[25,26]
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