Electrical breakdown mechanism and life prediction of thermal-aged epoxy/glass fibre composites

IF 5 2区 材料科学 Q1 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Polymer Testing Pub Date : 2024-08-22 DOI:10.1016/j.polymertesting.2024.108552
Pengfei Wang, Ji Liu, Zhen Li, Chao Zhang, Longfei Zhang, Shouming Wang, Mingze Zhang
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Abstract

Epoxy/glass fibre composites possess excellent mechanical and electrical properties and are widely utilised in electrical and electronic power equipment. However, the composites exhibit relatively poor thermal conductivity, causing the temperature of the composites to increase during the operation of power equipment, resulting in a significant reduction in the electrical breakdown strength. Although the effects of thermal aging on polymeric materials have been widely studied, its influence on electrical strength mechanisms has not been investigated at the molecular level. In this study, epoxy/glass fibre composite specimens were subjected to accelerated thermal aging treatment for 360 h at 180 °C. Functional groups, molecular chain dynamics, and electrical breakdown are characterised using infrared spectroscopy, dielectric spectroscopy, and breakdown measurement. Subsequently, electrical breakdown mechanism and life prediction of the thermally aged composites are discussed. During thermal aging, the epoxy resin molecular chains undergo continuous oxidation and chain scission, which generate numerous polar functional groups and short chains and an increase in the free volume. This triggers an enhancement in the chain segmental dynamics, thereby significantly reducing the activation energy of the epoxy resin. After 360 h, activation energy decreased from 0.78 eV to 0.67 eV. The DC breakdown voltages of the specimens decreased from 168.28 kV/mm to 134.91 kV/mm. An insulation life prediction model for thermally aged epoxy/glass fibre composites is established based on the time-temperature equivalence theory. The prediction results indicate that the service life of the operational composites is approximately 11.2 years at 353 K, which is consistent with engineering experience.

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热老化环氧树脂/玻璃纤维复合材料的电击穿机理和寿命预测
环氧树脂/玻璃纤维复合材料具有优异的机械和电气性能,被广泛应用于电气和电子电力设备中。然而,这种复合材料的导热性能相对较差,在电力设备运行过程中会导致复合材料温度升高,从而显著降低电气击穿强度。虽然热老化对聚合物材料的影响已被广泛研究,但其对电气强度机理的影响尚未在分子水平上进行研究。在这项研究中,环氧树脂/玻璃纤维复合材料试样在 180 °C 下进行了 360 小时的加速热老化处理。使用红外光谱、介电常谱和击穿测量来表征官能团、分子链动力学和电击穿。随后,讨论了热老化复合材料的电击穿机理和寿命预测。在热老化过程中,环氧树脂分子链会发生持续氧化和链裂,产生大量极性官能团和短链,并增加自由体积。这引发了链段动力学的增强,从而显著降低了环氧树脂的活化能。360 小时后,活化能从 0.78 eV 降至 0.67 eV。试样的直流击穿电压从 168.28 kV/mm 降至 134.91 kV/mm。根据时间-温度等效理论,建立了热老化环氧树脂/玻璃纤维复合材料的绝缘寿命预测模型。预测结果表明,在 353 K 下,工作复合材料的使用寿命约为 11.2 年,这与工程经验相符。
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来源期刊
Polymer Testing
Polymer Testing 工程技术-材料科学:表征与测试
CiteScore
10.70
自引率
5.90%
发文量
328
审稿时长
44 days
期刊介绍: Polymer Testing focuses on the testing, analysis and characterization of polymer materials, including both synthetic and natural or biobased polymers. Novel testing methods and the testing of novel polymeric materials in bulk, solution and dispersion is covered. In addition, we welcome the submission of the testing of polymeric materials for a wide range of applications and industrial products as well as nanoscale characterization. The scope includes but is not limited to the following main topics: Novel testing methods and Chemical analysis • mechanical, thermal, electrical, chemical, imaging, spectroscopy, scattering and rheology Physical properties and behaviour of novel polymer systems • nanoscale properties, morphology, transport properties Degradation and recycling of polymeric materials when combined with novel testing or characterization methods • degradation, biodegradation, ageing and fire retardancy Modelling and Simulation work will be only considered when it is linked to new or previously published experimental results.
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