Thomas Gkourmpis scite author profile

The insulation of state-of-the-art extruded highvoltage direct-current (HVDC) power cables is composed of cross-linked low-density polyethylene. Driven by the search for sustainable energy solutions, concepts that improve the ability to withstand high electrical fields and, ultimately, the power transmission efficiency are in high demand. The performance of a HVDC insulation material is limited by its residual electrical conductivity. Here, we demonstrate that the addition of small amounts of high-density polyethylene (HDPE) to a low-density polyethylene (LDPE) resin results in a drastic reduction in DC conductivity. An HDPE content as low as 1 wt % is found to introduce a small population of thicker crystalline lamellae, which are finely distributed throughout the material. The change in nanostructure correlates with a decrease in DC conductivity by approximately 1 order of magnitude to about 10 −15 S m −1 at high electric fields of 30 and 40 kV mm −1 and elevated temperature of 70 °C. This work opens up an alternative design concept for the insulation of HVDC power cables.

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Byproduct-free curing of a highly insulating polyethylene copolymer blend: an alternative to peroxide crosslinking

Mauri

Peterson

Senol

et al. 2018

J. Mater. Chem. C

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Thomas Gkourmpis

Molecular dynamics simulation of linear polyethylene blends: Effect of molar mass bimodality on topological characteristics and mechanical behavior

Modelling tie chains and trapped entanglements in polyethylene

Highly Insulating Polyethylene Blends for High-Voltage Direct-Current Power Cables

Byproduct-free curing of a highly insulating polyethylene copolymer blend: an alternative to peroxide crosslinking

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