sPP含量对iPP/sPP共混电缆绝缘电树生长特性的影响

S. Zhou, Zhonglei Li, Fan Yu, Wei Yang, Z. Xing, M. Fan, Ying Zhang, B. Du
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引用次数: 0

摘要

聚丙烯(PP)由于其更高的熔点和更高的电阻率,被认为是一种可回收的交联聚乙烯(XLPE)的电缆绝缘替代品。研究了共规PP (iPP)/sPP共混绝缘中共规PP (sPP)含量对交流电树生长特性的影响。在PP共混物中,随着sPP含量从0 wt%增加到15 wt%,电树生长速率下降。当sPP含量继续增加时,共混物的结晶度和深阱密度下降,导致电树的初始概率和生长速率增加。含15% sPP的PP共混物由于结晶度较高,表现出优异的抗电树性。较高的结晶度导致sPP/iPP共混物中较高的深阱密度。深阱密度的增加有利于降低电荷的平均自由程,限制冲击电离,导致电树生长速度降低。
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Effect of sPP Content on Electrical Tree Growth Characteristics in iPP/sPP Blend Cable Insulation
Polypropylene (PP) is considered to be a recyclable alternative to XLPE for cable insulation by virtue of its higher melting point and higher electrical resistivity. This work focuses on the effect of syndiotactic PP (sPP) content on the AC electrical tree growth characteristics in isotactic PP (iPP)/sPP blend insulation. The growth rate of electrical tree in PP blends decreased with the increase of sPP content from 0 to 15 wt%. When sPP content continues to increase, the crystallinity and deep trap density of the blend decline, resulting in the increasing initial probability and growth rate of electrical tree. The PP blend with 15 wt% sPP shows an excellent resistance to electrical tree, which is attributed to the higher crystallinity. The higher crystallinity results in a higher deep trap density in sPP/iPP blends. The increased deep trap density is conducive to reduce the mean free path of charges and confine impact ionization, resulting in the lower growth speed of electrical tree.
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