Effects of Mechanical Stress on Cohesive Energy and Energy Level Distribution of Bisphenol-A Epoxy Resin

2021 International Conference on Advanced Electrical Equipment and Reliable Operation (AEERO) Pub Date : 2021-10-15 DOI:10.1109/AEERO52475.2021.9708284

Pengxiang Guo, Jin Li, Chi Zhang, Ying Zhang, Jin He, Q. Tang, R. Zhao, X. Kong, Boxue Du

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Abstract

Epoxy resin is widely used in the field of electrical equipment insulation. In this paper, the effects of mechanical stress on cohesive energy and energy level distribution of epoxy resin were investigated. Tensile stress reduces the cohesive energy density of epoxy resin and accelerates the insulation deterioration. On the contrary, the compressive stress can restrain the insulation deterioration. The van der Waals interaction plays a more important role in changing the cohesive energy. The band gap of epoxy resin decreases and the polarizability increases under tensile stress. Under compression stress, the band gap increases and the polarizability decreases. The changes of molecular local state and polarization can affect the charge transport characteristics, which reveals the relationship between the insulation deterioration and the mechanical stress. The conclusion is helpful to understand the insulation failure mechanism of epoxy resin under mechanical stress.

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机械应力对双酚a环氧树脂黏结能和能级分布的影响

环氧树脂广泛应用于电气设备绝缘领域。研究了机械应力对环氧树脂黏结能和能级分布的影响。拉应力降低了环氧树脂的内聚能密度，加速了绝缘劣化。相反，压应力可以抑制绝缘劣化。范德华相互作用在改变内聚能方面起着更重要的作用。在拉伸应力作用下，环氧树脂的带隙减小，极化率提高。在压缩应力作用下，带隙增大，极化率减小。分子局域态和极化的变化会影响电荷输运特性，揭示了绝缘劣化与机械应力之间的关系。该结论有助于理解环氧树脂在机械应力作用下的绝缘破坏机理。

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2021 International Conference on Advanced Electrical Equipment and Reliable Operation (AEERO)

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