Epoxy-based composites with enhanced thermal properties through collective effect of different particle size fillers

Zeng, Xiaogang; Zhang, Zhengguo; Pan, Yaoqi; Zhang, Yongle; Hou, Linxi

doi:10.1177/09673911221106686

Cited by 4 publications

(1 citation statement)

References 56 publications

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“…Previously, it was demonstrated that thermal interface barriers play a major role in setting the performance limits in conventional cooling systems made of aluminum or copper being attached with thermal paste. [11][12][13] The key to dramatically reducing thermal interface barriers is developing new applicable materials which can be printed directly on the substrate.…”

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confidence: 99%

Novel Additive Manufacturing Materials for Waste Heat Deduction

et al. 2022

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Additive manufacturing (AM) technologies of polymers have experienced tremendous growth within the last decade. [1,2] Various application methods such as material extrusion (MEX), vat photo-polymerization (VPP), material jetting, binder jetting, or powder bed fusion techniques have been elaborated and refined as well as the corresponding feedstocks such as filaments, resins, powders, and compounds with metallic or ceramic powders. [3] Being used mainly for rapid prototyping approaches, in the beginning, AM technologies have grown to be a considerable alternative in production, especially when parameters such as freedom of design, resource efficiency, or mass customization are an issue. [4,5] One major research topic is additive manufacturing for medical applications, where personalized products can be produced via AM. [6][7][8][9] The limitation here are not the technologies but the materials, which have to fulfil all the medical requirements. Other topics are the use of the technologies in production lines, especially in aeronautic, space, and automobile industries. However, AM still has to overcome certain obstacles including inline assembly capability to make a step toward a fully accepted production alternative to well-established production processes. [10] Printing parts and components and subsequently mounting them on the final product do not make use of the full AM potential while printing these parts directly onto the substrate might generate additional benefits due to cutting manual assembly costs. Pushing AM toward inline assembly capability will even enhance the overall system performance of a product, for example, when electrical or thermal conductivity due to interface issues can be improved. [11] The EcoPrint project consortium has set its focus on developing AM inline applicable, electrically insulating, thermally

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Novel Additive Manufacturing Materials for Waste Heat Deduction

et al. 2022

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Simultaneously Enhanced Thermal Conductivity and Dielectric Breakdown Strength in Micro/Nano-BN/Epoxy/PC Multilayer Composites

Yang,

Chen,

Yue

et al. 2024

ACS Appl. Nano Mater.

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Because of their significant application potential in both power electronic devices and power equipment, the development of polymer-based composites with high thermal conductivity and breakdown strength has gained increasing attention. In this study, multilayer structural composites were successfully prepared. Micro/Nano-BN was prepared by electrospinning technology, showing positive gradient (PGD) and inverse gradient (IGD) distribution in an epoxy and polycarbonate (PC) blended matrix. The gradient distribution of nanofillers fully filled in each layer greatly enhances the breakdown strength of the composite dielectric. In comparison to traditional composites, the bottleneck of increasing thermal conductivity and breakdown strength at the same time was successfully overcome. The breakdown strength of the 2−6−2 structure multilayer positive gradient composite dielectric reaches 107.1 kV/mm, 76.7% higher than the single-layer uniform composite dielectric and thermal conductivity of 0.38 W/(m•K) (2.11 times that of epoxy). The 6−2− 6 structure obtains the highest breakdown strength of 110 kV/mm and a thermal conductivity of 0.33 W/(m•K). The thermal conductivity of the multilayer composite dielectric of both gradient structures changed; this phenomenon provides an idea for polymers to improve thermal conductivity.

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