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In the era of highly thin, multi-functional and integrated electronic devices, it will inevitably lead to the heat accumulation inside the composite material, thereby seriously affecting the operation stability and service life of the equipment. How to realize the rapid and efficient heat conduction and heat dissipation of dielectric materials has become a bottleneck problem restricting the further development of electronic devices. The intrinsic thermal conductivity of traditional polyimide is low, which limits its application in electrical equipment, smart grid and other fields. The development of new high thermal conductivity polyimide dielectric film materials has become the focus of research. This paper introduces the thermal conduction mechanism of composite materials, summarizes the research progress and development status of thermally conductive polyimide films in recent years, and focuses on the effects of thermally conductive fillers, interface compatibility, and molding process of the thermal conductivity of materials. Finally, some key scientific and technical issues in the research are summarized and prospected in combination with the future development needs of thermally conductive polyimide composite dielectric materials.
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Keywords:
- polyimide /
- thermal conductivity /
- thermal conductive filler /
- composite materials
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表 1 常见聚合物的热导率
Table 1. Thermal conductivity of the common polymers.
材料名称 热导率/(W·m–1·K–1) 环氧树脂 (EP) 0.20—0.88 聚氨酯 (PU) 0.25 聚偏氯乙烯 (PVDF) 0.19 聚二甲基硅氧烷 (PDMS) 0.19 聚苯乙烯 (PS) 0.18 低密度聚乙烯 (LDPE) 0.32—0.40 高密度聚乙烯 (HDPE) 0.38—0.51 聚丙烯 (PP) 0.17—0.22 聚醚醚酮 (PEEK) 0.25 聚氯乙烯 (PVC) 0.14—0.17 聚酰亚胺 (PI) 0.10—0.35 聚乙烯醇 (PVA) 0.20 聚四氟乙烯(PTFE) 0.25 聚甲醛 (POM) 0.40 -
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[24] 徐京城, 戴思畅, 李昊亮, 杨俊和 2018 新型炭材料 33 213Google Scholar
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