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Zhiyun HAN, Qingmin LI, Junke LI, Mengxi WANG, Hanwen REN, Liang ZOU. Phase field model for electric-thermal coupled discharge breakdown of polyimide nanocomposites under high frequency electrical stress[J]. Plasma Science and Technology, 2024, 26(2): 025505. DOI: 10.1088/2058-6272/ad0d49
Citation: Zhiyun HAN, Qingmin LI, Junke LI, Mengxi WANG, Hanwen REN, Liang ZOU. Phase field model for electric-thermal coupled discharge breakdown of polyimide nanocomposites under high frequency electrical stress[J]. Plasma Science and Technology, 2024, 26(2): 025505. DOI: 10.1088/2058-6272/ad0d49

Phase field model for electric-thermal coupled discharge breakdown of polyimide nanocomposites under high frequency electrical stress

  • In contrast to conventional transformers, power electronic transformers, as an integral component of new energy power system, are often subjected to high-frequency and transient electrical stresses, leading to heightened concerns regarding insulation failures. Meanwhile, the underlying mechanism behind discharge breakdown failure and nanofiller enhancement under high-frequency electrical stress remains unclear. An electric-thermal coupled discharge breakdown phase field model was constructed to study the evolution of the breakdown path in polyimide nanocomposite insulation subjected to high-frequency stress. The investigation focused on analyzing the effect of various factors, including frequency, temperature, and nanofiller shape, on the breakdown path of Polyimide (PI) composites. Additionally, it elucidated the enhancement mechanism of nano-modified composite insulation at the mesoscopic scale. The results indicated that with increasing frequency and temperature, the discharge breakdown path demonstrates accelerated development, accompanied by a gradual dominance of Joule heat energy. This enhancement is attributed to the dispersed electric field distribution and the hindering effect of the nanosheets. The research findings offer a theoretical foundation and methodological framework to inform the optimal design and performance management of new insulating materials utilized in high-frequency power equipment.
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