Correlation of Diffusion Limited Oxidation to Color Difference in Accelerated Aging of Electrical Cable Insulation

2021 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP) Pub Date : 2021-12-12 DOI:10.1109/CEIDP50766.2021.9705346

Witold K. Fuchs, Mychal P. Spencer, Donghui Li, Y. Ni, Andy Zwoster, L. Fifield

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Abstract

Diffusion limited oxidation (DLO) as a phenomenon has complicated material lifetime predictions from accelerated aging studies. Many methods to analyze DLO have been developed in recent years. However, an analytical tool for high throughput and low-cost analysis of DLO affected samples remains absent from the literature. Color differences in polymers exposed to oxidative conditions have recently been observed and correlated to increased concentrations of oxidation products. Herein, total color difference was utilized to rapidly quantify DLO in ethylene propylene rubber (EPR) polymeric cable insulation specimens. Insulation specimens were aged at 121 °C, 136 °C, 150 °C, and 165 °C and a 10% ΔE*ab difference between the specimen edge and specimen center was used as the threshold for DLO. Based on these specifications DLO was observed in EPR insulation specimen at temperatures of 136 °C and above, with an increasing degree of DLO observed as the time of exposure increased. The method presented in this work represents a quantitative and high-throughput method for the investigation of DLO with a low cost barrier for entry.

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电缆绝缘加速老化中扩散限制氧化与色差的关系

扩散限制氧化(DLO)作为一种现象，从加速老化研究中对材料寿命进行了复杂的预测。近年来发展了许多分析DLO的方法。然而，一种高通量和低成本分析DLO影响样品的分析工具仍然缺乏文献。聚合物暴露于氧化条件下的颜色差异最近被观察到，并与氧化产物浓度的增加有关。本文采用总色差法快速定量测定EPR聚合物电缆绝缘试样中的DLO。保温试样分别在121°C、136°C、150°C和165°C老化，以试样边缘和试样中心之间的10% ΔE*ab的差值作为DLO的阈值。根据这些规范，EPR绝缘试样在136℃及以上温度下观察到DLO，随着暴露时间的增加，观察到的DLO程度越来越大。本文提出的方法是一种定量、高通量、低成本进入壁垒的DLO研究方法。

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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2021 IEEE Conference on Electrical Insulation and Dielectric Phenomena (CEIDP)

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