高导热MXene改性PI的多温度直流闪络特性

张博; 郭建华; 王晓敏; 王琎; 乌江

doi:10.13336/j.1003-6520.hve.20241774

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高导热MXene改性PI的多温度直流闪络特性

更新时间：2026-02-02

- 高导热MXene改性PI的多温度直流闪络特性
- Vol. 51, Issue 12, Pages: 5859-5868(2025)
- 作者机构：
  
  1. 西安工程大学电子信息学院,西安,710048
  2. 西安市电气设备互联感知与智能诊断重点实验室,西安,710048
  3. 西安建筑科技大学环境与市政工程学院,西安,710055
- 作者简介：
- 基金信息：
- DOI：10.13336/j.1003-6520.hve.20241774
  CLC：
- Published：2025
- 稿件说明：
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张博, 郭建华, 王晓敏, et al. 高导热MXene改性PI的多温度直流闪络特性[J]. 2025, 51(12): 5859-5868.
DOI：

张博, 郭建华, 王晓敏, et al. 高导热MXene改性PI的多温度直流闪络特性[J]. 2025, 51(12): 5859-5868. DOI： 10.13336/j.1003-6520.hve.20241774.

摘要

聚酰亚胺因其优异的绝缘性能与耐高低温性能，广泛应用于电缆绕包、变压器等匝间绝缘材料领域。长期处于高温高电压状态下的聚酰亚胺容易引发沿面闪络导致绝缘性能的破坏，其表面电荷的积累与消散特性对其绝缘破坏具有重要影响。MXene是一种由二维过渡金属碳化物(氮化物)组成的纳米材料，具有较大比表面积和丰富可调控的表面官能团(—OH、—F和—O)，氧化后对电子有较强的吸引力，可以限制泄漏电流并提高电气强度与电阻率。通过添加二维MXene纳米片制备不同质量分数MXene/PI复合薄膜，研究不同温度下聚酰亚胺复合薄膜表面电荷的运输行为对闪络的影响，以及不同质量分数下MXene/PI纳米复合材料在25、50、80 ℃下复合薄膜陷阱分布及闪络变化规律。结果发现，随着MXene质量分数的增大其闪络电压先增大后减小，其中质量分数0.5% MXene/PI复合薄膜的闪络电压最大。随着温度升高闪络电压先增大后减小，50 ℃时不同质量分数MXene/PI复合薄膜的闪络电压整体最大。当质量分数为0.5%时其深陷阱能级与密度最大，其规律与闪络电压相似。添加一定量的二维纳米片，可以有效地改变界面区的能级分布，导致复合材料的深陷阱能级与密度的增大，会使电子的迁移受到限制，导致其电阻率的增大与闪络电压的升高。

Abstract

Polyimide is widely used in the field of turn-to-turn insulating materials such as cable wrapping and transformers due to its excellent insulating properties and high and low temperature resistance. Polyimide in the high-temperature and high-voltage state for a long time is prone to trigger flashover along the surface leading to the destruction of insulation performance

and its surface charge accumulation and dissipation characteristics have an important impact on its insulation damage. MXene is a nano-material consisting of two-dimensional transition metal carbides (nitrides)

with a large specific surface area and a wealth of tunable surface functional groups (—OH

—F and —O)

which have a strong attraction to electrons after oxidation

and can limit the leakage current and improve the electrical strength and resistivity. MXene/PI composite films with different mass fractions were prepared by adding two-dimensional MXene nanosheets to study the effect of the transport behavior of surface charge on the flashover of polyimide composite films at different temperatures. In this paper

we study the trap distribution and flashover law of composite films with different mass fractions of MXene/PI nanocomposites at 25 ℃

50 ℃

and 80 ℃. It is found that the flashover voltage increases and then decreases with the increase of MXene content

in which the flashover voltage of 0.5 wt% MXene/PI composite film is the largest. The flashover voltage increases and then decreases as the temperature rises

and the flashover voltage of MXene/PI composite films with different mass fractions is the overall maximum at 50 ℃. The flashover voltage of MXene/PI composite films with different mass fractions is the overall maximum at 0.5%. Its deep trap energy level and density are maximum when the concentration is 0.5%

and the pattern is similar to the flashover voltage. The addition of a certain amount of 2D nanosheets can effectively change the energy level distribution in the interfacial region

leading to the increase of the deep trap energy level

and the density of the composite material will limit the electron migration

resulting in the increase of its resistivity and the increase of the flashover voltage.

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