Thermal behavior and dielectric response of epoxy–boron nitride composites reinforced with short human hair fiber

Nanda, Bishnu Prasad; Satapathy, Alok

doi:10.1002/pc.26139

Cited by 8 publications

(9 citation statements)

References 41 publications

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“…[14] Besides high T g , high thermal conductivity and low coefficient of thermal expansion of EPs are always desired for their industrial applications, especially from an electronic packaging perspective. To date, considerable efforts have been made to improve the heat endurance and heat dissipation capabilities of EP-based dielectric materials by inorganic particle doping [15][16][17][18][19][20][21][22][23][24] and chemical modification. [25][26][27] Furthermore, EP is also an indispensable adhesive that is extensively used in power equipment.…”

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confidence: 99%

Space Charge Behavior in Epoxy‐Based Dielectrics: Progress and Perspective

Liu

Xie

et al. 2022

Adv Elect Materials

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temperature and complex electric field conditions. [1][2][3] Epoxy resin (EP) is a class of polymer oligomers containing two or more epoxide groups based on organic compounds (e.g., aliphatic, alicyclic, and aromatic). As a prepolymer, EP shows excellent performance after its reaction with a curing agent to form an insoluble polymer with a 3D network structure. EP has desirable insulating characteristics, [4][5][6][7] heat resistance, [8] high mechanical strength, [9] low shrinkage, [10] chemical stability, and adhesive properties, which originate from its compact structure and tunable functional groups. The above mentioned outstanding performances, along with characteristics of easy processing and formula design flexibility, enable the extensive use of EP-based materials in power equipment and electronic devices [11] (Figure 1), including bar insulation and impregnating varnish in transformers, main insulation in dry-type bushings and wall bushings, insulator in gas-insulated switchgear (GIS) and gas-insulated transmission line (GIL), epoxy molding compound for integrated circuit (IC) packaging. It is noteworthy that EPs typically possess lower glass transition temperature (T g ) compared to other high-T g dielectric polymer substitutes used in microelectronic systems such as benzocyclobutene, [12] polyimide (PI), [13] and maleimide. [14] Besides high T g , high thermal conductivity and low coefficient of thermal expansion of EPs are always desired for their industrial applications, especially from an electronic packaging perspective. To date, considerable efforts have been made to improve the heat endurance and heat dissipation capabilities of EP-based dielectric materials by inorganic particle doping [15][16][17][18][19][20][21][22][23][24] and chemical modification. [25][26][27] Furthermore, EP is also an indispensable adhesive that is extensively used in power equipment. [28][29][30][31][32] Yet, potential reliability hazards may exist during the operation of power equipment and electronic devices, especially at high temperatures and under high voltage direct current (HVDC) application, one of which is the space charge accumulation in EP-based dielectric materials. [29,30,33,34] The accumulated space charge may cause deterioration/aging and even partial discharge or dielectric breakdown of dielectric materials. [35][36][37][38][39][40] Specifically, the extensive application of EP-based dielectric materials in HVDC transmission projects eagerly calls for relevant studies on the space charge behavior Epoxy-based dielectrics are extensively used in grid-connected energy systems and modern microelectronics as electrical insulation, adhesive, and packaging components. However, space charge accumulation in epoxy-based dielectrics is a foremost factor threatening device stability and lifespan, especially under conditions of high voltage direct current and high temperatures during long-term operation, and thus are investigated systematically. This article reviews the state-of-the-art progress in understanding and r...

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confidence: 99%

Space Charge Behavior in Epoxy‐Based Dielectrics: Progress and Perspective

Liu

Xie

et al. 2022

Adv Elect Materials

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“…Under this circumstance, epoxies filled with high thermal conductive fillers are emerging as a cost‐effective way to cope with thermal management issues. Incorporating highly thermally conductive ceramic fillers in polymers have long been studied to improve the thermal conductivity of the composites 4–8 . In these composite systems, the filler size and content have been reported to be major factors affecting thermal conductivity, where efficient packing could increase the loading density of the fillers in the polymer matrix 9–14 .…”

Section: Introductionmentioning

confidence: 99%

“…Incorporating highly thermally conductive ceramic fillers in polymers have long been studied to improve the thermal conductivity of the composites. [4][5][6][7][8] In these composite systems, the filler size and content have been reported to be major factors affecting thermal conductivity, where efficient packing could increase the loading density of the fillers in the polymer matrix. [9][10][11][12][13][14] Research on their applications has shown that high filler loading (>70 wt%) is still the main method to obtain high thermal conductivity of epoxy insulation packaging materials for electrical equipment.…”

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The effects of multiple‐sized compound fillers on the thermal, electrical, and processing properties of epoxy composites

Yang,

Zhao,

Chen

et al. 2023

Polymer Composites

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The efficient filling of the multiple‐sized compound fillers can effectively increase the thermal conductivity of the polymer composite. However, determining the specific proportion of the compound fillers with different sizes is hard. This article proposes a random distribution model and the closest packing model to calculate the proportion of the compound fillers and prepare the epoxy composites with different compound fillers. By elaborately designing epoxy composites containing 75 wt% (48 vol%) ternary compound Al2O3 fillers, its thermal conductivity reached 1.640 W/(m·K). In addition, the volume resistivity for all prepared Al2O3/epoxy composites was higher than 1016 Ω cm. Besides, the electrical and dielectric properties of the epoxy composite with multiple‐sized compound fillers were comparable or superior to the composite with single‐sized fillers. Last but not least, the viscosity of the ternary compound Al2O3/epoxy mixture was significantly lower than the single‐sized Al2O3/epoxy mixture, which is beneficial for improving the processability of the epoxy composite. The results of this article will guide the development and utilization of epoxy composites with high thermal conductivities.Highlights A random distribution model and the closest packing model were proposed. The thermal conductivity of the designed epoxy composites reached 1.640 W/(m·K). The compound filler can effectively improve the processability of the composite.

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“…Hexagonal boron nitride (h-BN) nanosheets, as a promising 2D ceramic material, have several advantages over both carbon-based materials and metal nanoparticles, including high thermal stability, [13] excellent corrosion resistance, [6] outstanding oxidize resistance, [14] and excellent electrical insulation, [15] rendering it an exceptional thermal conductive filler for enhancing the heat transfer performance of polymers. [16,17] Nevertheless, the lack of active groups causes BN to clump together and distribute poorly in the polymer matrix, forming many interfacial thermal resistances (ITR) between the filler and the matrix, as well as the overlaps of fillers. [18,19] To solve these problems, surface functionalization can ameliorate the interfacial affinity of BN.…”

Section: Introductionmentioning

confidence: 99%

Anchoring modified polystyrene to boron nitride nanosheets as highly thermal conductive composites for heat dissipation

Han

Xiaohan

et al. 2022

Polymer Composites

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Enhancing the heat dissipation capacity of polymer-based composites requires effectively improving the compatibility of filler in a polymer matrix. Herein, hydroxylated boron nitride (BN-OH) and modified polystyrene (mPS) are combined to achieve a high thermal conductive BN-OH@mPS composite by using a facile in-situ polymerization. Due to the strong interface interaction between BN-OH and mPS, the proposed BN-OH@mPS composite can have high thermal conductivity (TC). Specifically, the TC of the composite containing 10 wt% BN-OH can reach 1.231 W/mK, which is 142% higher than that of BN/PS manufactured by a traditional method. Additionally, such a special structure brings a delayed decomposition process of the composite, making it possess high thermal stability. Overall, this serves as a universal route for developing thermal conductive non-polar polymer/inorganic filler composites.

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Thermal behavior and dielectric response of epoxy–boron nitride composites reinforced with short human hair fiber

Cited by 8 publications

References 41 publications

Space Charge Behavior in Epoxy‐Based Dielectrics: Progress and Perspective

Space Charge Behavior in Epoxy‐Based Dielectrics: Progress and Perspective

The effects of multiple‐sized compound fillers on the thermal, electrical, and processing properties of epoxy composites

Anchoring modified polystyrene to boron nitride nanosheets as highly thermal conductive composites for heat dissipation

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