Cold plasma modification of boron nitride fillers and its effect on the thermal conductivity of silicone rubber/boron nitride composites

Ji, Tuo; Zhang, Liqun; Wang, Wencai; Liu, Yu; Zhang, Xiaofeng; Lu, Yonglai

doi:10.1002/pc.22277

Cited by 35 publications

(10 citation statements)

References 41 publications

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“…For instance, the temperature in lip seals working in hostile environments may be as high as 185°C. Therefore, elastomer nanocomposites with high ageing resistance and high thermal conductivity are required for these applications [254,255]. The high heat build-up generated during the use of a tire is dangerous in that it will degrade the mechanical performance of the tire.…”

Section: High-speed Dynamic Elastomeric Productsmentioning

confidence: 99%

Transport performance in novel elastomer nanocomposites: Mechanism, design and control

Guo

Tang

Zhang

2016

Progress in Polymer Science

138

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Section: High-speed Dynamic Elastomeric Productsmentioning

confidence: 99%

Transport performance in novel elastomer nanocomposites: Mechanism, design and control

Guo

Tang

Zhang

2016

Progress in Polymer Science

138

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“…Most straightforwardly, increasing the filler content in the composite can improve the thermal conductivity; for example, a thermal conductivity of 32.5 W/mK was reported when BN reached a loading fraction of 78.5 vol% in polybenzoxazine matrix . Surface modification of BN assists with homogenous dispersion of filler in resin matrix . Mixing multiple sized particles leads to high packing density and easy formation of conductive pathways .…”

Section: Introductionmentioning

confidence: 99%

Densely packed polymer/boron nitride composite for superior anisotropic thermal conductivity

Zhu

Wang

et al. 2017

Polymer Composites

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High heat conduction performance of electrical insulating composite is highly desired in thermal management of electronics. In this study, densely packed boron nitride (BN) composites with resin matrices of epoxy, polymethyl methacrylate, and an acrylic copolymer based binder were prepared through a solvent mediated mixing and compression molding method. The solvent mediated mixing assisted homogeneous dispersion; the compression molding removed excessive resin and led to alignment of BN flakes with high filler content. The resulted composites exhibited superior in‐plane thermal conductivity k// up to 21.3 W/mK and pronounced anisotropic heat conduction properties. The thermal conductivity was positively correlated with density bold-italicρ of a specimen in experimental. A presentation of thermal conductivity bold-italick=bold-italick|bold-italicρ was proposed, and the dependence of thermal conductivity on specimen density bolddbold-italicktrue(bold-italicρtrue)/bolddbold-italicρ > 0 was proven mathematically. The application of BN composite in LED thermal management was demonstrated. An epoxy/BN heat spreader was used to efficiently cool down a 0.3‐W LED. The cooling effect was close to that with Al board heat spreader. POLYM. COMPOS., 39:E1653–E1658, 2018. © 2017 Society of Plastics Engineers

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“…One of the most practical ways to improve heat transfer in rubber materials is to add into the rubber matrix with thermally conductive fillers , such as aluminum oxide, magnesium oxide, zinc oxide, aluminum nitride, boron nitride, and silicon nitride. Carbon‐based fillers including carbon fiber, carbon nanotube, and graphene are also promising fillers for thermally conductive composites due to their high thermal conductivity .…”

Section: Introductionmentioning

confidence: 99%

Improvement in thermal conductivity and mechanical properties of ethylene‐propylene–diene monomer rubber by expanded graphite

Lin

Chen

et al. 2015

Polymer Composites

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Thermally conductive fillers are usually employed in the preparation of rubber composites to enhance thermal conductivity. In this work, ethylene‐propylene‐diene monomer rubber (EPDM)/expanded graphite (EG) and EPDM/graphite composites with up to 100 phr filler loading were prepared. Compared to EPDM/graphite compounds with the same filler loading, stronger filler network was demonstrated for EPDM/EG compounds. Thermal conductivity and mechanical properties of EPDM/graphite and EPDM/EG composites were compared and systematically investigated as a function of the filler loading. The thermal conductivity of both EPDM/graphite and EPDM/EG composites increased with increasing volume fraction of fillers, and could be well fitted by Geometric Mean Model. The thermal conductivity as high as 0.910 W · m−1 · K−1 was achieved for the EPDM/EG composite with 25.8 vol% EG, which was ∼4.5 times that of unfilled EPDM. Compared to EPDM/graphite composites, EPDM/EG composites exhibited much more significant improvement in thermal conductivity and mechanical properties, which could be well correlated with the better filler‐matrix interfacial compatibility and denser structure in EPDM/EG composites, as revealed in the SEM images of tensile fracture surfaces. POLYM. COMPOS., 38:870–876, 2017. © 2015 Society of Plastics Engineers

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Cold plasma modification of boron nitride fillers and its effect on the thermal conductivity of silicone rubber/boron nitride composites

Cited by 35 publications

References 41 publications

Transport performance in novel elastomer nanocomposites: Mechanism, design and control

Transport performance in novel elastomer nanocomposites: Mechanism, design and control

Densely packed polymer/boron nitride composite for superior anisotropic thermal conductivity

Improvement in thermal conductivity and mechanical properties of ethylene‐propylene–diene monomer rubber by expanded graphite

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