Investigating optimal region for thermal and electrical properties of epoxy nanocomposites under high frequencies and temperatures

Awais, Muhammad; Chen, Xiangrong; Dai, Chao; Wang, Qilong; Meng, Fanbo; Hong, Zelin; Paramane, Ashish; Tanaka, Yasuhiro

doi:10.1088/1361-6528/ac45c3

Cited by 15 publications

(12 citation statements)

References 37 publications

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“…Furthermore, as shown in the XRD pattern in Figure 3c, the results before and after grafting both contain (002), (100), (101), (102), and (004) crystal plane (2 θ = 26.78°, 41.65°, 43.93°, and 50.19°, respectively) corresponding to hBN. In the case of surface‐modified nano hBN, the same suppressed XRD peaks than raw hBN are observed, which may be attributed to the exfoliation of pristine hBN by successful grafting [42]. Obviously, the (002) crystal plane is absolutely dominant here, so the computational chemistry model in the following paper mainly studied this crystal plane of hBN.…”

Section: Resultsmentioning

confidence: 99%

Large‐scale plasma grafts voltage stabilizer on hexagonal boron nitride for improving electrical insulation and thermal conductivity of epoxy composite

Zhang

Yao

et al. 2022

High Voltage

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Better electrical insulation and thermal management are both urgently required in integrated power semiconductors. Electrical insulation epoxy encapsulation suffers from poor heat conduction, which has increasingly become a bottleneck of power semiconductors integration. Although incorporating high thermal conductivity ceramics, such as hexagonal boron nitride (hBN), aluminium nitride etc. into epoxy promotes the thermal conductivity, the eco‐friendly scalable fabrication of these composites with sufficient electrical breakdown strength remains a formidable challenge. Suitable voltage stabilizers are known to provide additional benefits to breakdown strength. Herein, a high‐throughput approach combining plasma with roll‐to‐roll was developed. The voltage stabilizer (acetophenone) was grafted on interfaces between hBN and epoxy matrix through plasma. The high‐energy electrons are consumed by the grafted interface, which leads to the significant suppression of partial discharge in Epoxy/hBN. Meanwhile, interfacial phonon scattering is repaired by grafting. Therefore, the epoxy composite concurrently exhibits improved breakdown strength (by 27.4%) and thermal conductivity (by 142.9%) at about 11.9 wt.% filler content, outperforming the pure epoxy. Consequently, a promising modification strategy for mass production is provided for the encapsulation materials in various high‐power‐density semiconductor devices.

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Section: Resultsmentioning

confidence: 99%

Large‐scale plasma grafts voltage stabilizer on hexagonal boron nitride for improving electrical insulation and thermal conductivity of epoxy composite

Zhang

Yao

et al. 2022

High Voltage

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“…Figure 6 describes the variation of dielectric loss (tan δ ) at different frequencies and temperatures. For the reliable operation of dielectric insulation, it should have minimum dielectric loss 37 . Figure 6a explains that all the EPR micro‐nano composites initially exhibit higher tan δ values than EPR at 25°C and at frequency < 1 kHz.…”

Section: Resultsmentioning

confidence: 99%

“…For the reliable operation of dielectric insulation, it should have minimum dielectric loss. 37 Figure 6a explains that all the EPR micro-nano composites initially exhibit higher tan δ values than EPR at 25 C and at frequency < 1 kHz. However, above 1 kHz, the EPR suffers from the highest tan δ among all the samples (except M5N0 ≈ EPR).…”

Section: Dielectric Performancementioning

confidence: 95%

Influence of dielectric barrier effect and thermally‐conductive network on thermal and electrical properties of epoxy under different frequencies and temperatures

Awais

Chen

Shi

et al. 2022

J of Applied Polymer Sci

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Epoxy resin (EPR) insulations play a vital role in the insulation of modern power electronic equipment owing to their excellent dielectric properties.However, due to the high-power density and miniaturization of power equipment which causes high heat fluxes under high voltage and high-frequency stresses, EPR with good thermal and insulation properties is urgently needed.In this study, the polydopamine functionalized micro-BN and core-shell nano TiO 2 -SiO 2 particles are dispersed in EPR to simultaneously improve thermal and dielectric insulation properties. It is revealed that the addition of micronano particles significantly improves the thermal and dielectric performance. Particularly, the high thermal conductivity of micro-BN and the dielectric barrier effect due to the core-shell structure of nano TiO 2 -SiO 2 are the main reasons for improved thermal and dielectric insulation performance, respectively.The EPR composite containing 3 wt% of micro-BN and 1 wt% of nano TiO 2 -SiO 2 exhibits the optimal performance with 0.49 W/mK thermal conductivity and the highest dielectric strength among all the samples, that is, 60.61 kV/ mm even at 10 kHz and 90 C. This study found that the crucial factors are the surface encapsulation, weight percent, and homogeneous dispersion of particles in EPR, the dielectric barrier effect, thermal conductivity, and the mismatch between the dielectric constant of EPR and particles. This study proposes the optimal weight percent of suitable micro-nano particles for EPR to produce suitable composites for high-frequency and high-temperature applications.

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“…It is commonly accepted that renewable energy sources prefer direct current (DC) over alternating current due to its large volume and elongated transmission, small footmarks, storage abilities and smart use of electricity. In recent decades, epoxy has emerged as an important insulation candidate and has been used in various applications of DC systems, such as Gas-insulated switchgear, electronic packaging, power inverters and in high-frequency power transformers [2,3]. However, there are several challenges and drawbacks in using epoxy in such systems that need to be resolved for the reliability and safety of the power system.…”

Section: Introductionmentioning

confidence: 99%

Multi‐modified epoxy insulation with improved flashover threshold for HVDC applications

Haq

Wang

2023

IET Nanodielectrics

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The flashover threshold (Vflsh) of polymer insulations such as epoxy (EP) in HVDC systems can be augmented by modifying their surface with an appropriate treatment technology. For such purpose, several surface treatment methods such as ion beam, sandpaper and a combination of the two is introduced. Firstly, insulation samples with pure epoxy (EPpure), different ion beam treatment periods (EPion;10, 15, 20 min) and different roughness (EPsand; R1 = 4.23 μm, R2 = 6.34 μm, R3 = 9.21 μm) are prepared on the laboratory scale. Afterward, based on several characterisations, such as surface conductivity, mean surface roughness and potential distribution of these insulations, multi‐modified insulation (EPmulti = EPion‐20 + EPsand‐R3) is prepared. In the end, the Vflsh of each insulation group is measured and compared to examine the effectiveness of the proposed modifications. It is obtained that the Vflsh of the modified insulations augmented dramatically irrespective of the treatment method. The Vflsh of the insulation group EPmulti augmented by 52.66 % which is the highest improvement among all insulation groups. In short, the proposed surface modifications are effective and could be used as references to enhance the insulation strength of polymer dielectrics in HVDC systems.

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Investigating optimal region for thermal and electrical properties of epoxy nanocomposites under high frequencies and temperatures

Cited by 15 publications

References 37 publications

Large‐scale plasma grafts voltage stabilizer on hexagonal boron nitride for improving electrical insulation and thermal conductivity of epoxy composite

Large‐scale plasma grafts voltage stabilizer on hexagonal boron nitride for improving electrical insulation and thermal conductivity of epoxy composite

Influence of dielectric barrier effect and thermally‐conductive network on thermal and electrical properties of epoxy under different frequencies and temperatures

Multi‐modified epoxy insulation with improved flashover threshold for HVDC applications

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