Investigation of 22 kV silane cure TR-EPR cable

International Journal of Applied Power Engineering Pub Date : 2020-03-01 DOI:10.11591/IJAPE.V10.I1.PP41-47

Fernando Agustin, Akhtar Kalam, A. Zayegh

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Abstract

EPR-insulated cables for distribution power network are not commonly used in Australia. This is due to the higher DDF of common EPR cables when compared with XLPE that contributes to the power loss and economics in transmitting electricity. This led to the development of EPR called TR-EPR with significantly lower DDF and uses silane curing process to address concerns about cost-effectiveness. The thermal behavior of low DDF silane cure TR-EPR is investigated for 30 months of exposure to the maximum operating temperature of material. The physical changes in the samples throughout the long-term aging are examined to create an opportunity to model the expected life cycle of TR-EPR cable under thermal stress. The cross-linking characteristics of TR-EPR cable are also examined by ambient curing that simulates the storage condition for unused cable and by cable heating process that simulates the condition when the cable is energized. The results are tabulated for a better understanding of the time for the material to cross-link at various conditions. The improved partial discharge values after cross-linking are also presented.

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22kv硅烷固化TR-EPR电缆的研制

配电网用epr绝缘电缆在澳大利亚并不常用。这是由于与XLPE相比，普通EPR电缆的DDF更高，这会导致功率损失和传输电力的经济性。这导致了称为TR-EPR的EPR的发展，其DDF显着降低，并使用硅烷固化工艺来解决成本效益问题。研究了低DDF硅烷固化TR-EPR在材料最高工作温度下暴露30个月的热行为。研究了样品在长期老化过程中的物理变化，为热应力下TR-EPR电缆的预期寿命周期建模创造了机会。TR-EPR电缆的交联特性还通过模拟未使用电缆的储存条件的环境固化和模拟电缆通电时的条件的电缆加热过程来检查。为了更好地理解材料在不同条件下交联所需的时间，将结果制成表格。交联后的局部放电值也有所提高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Journal of Applied Power Engineering

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