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Abstract

Recent research revealed potentials to develop polymer matrix composite foams filled with thermally conductive filler network as light-weight thermal management materials. Since polymeric foams are commonly used for thermal insulation, the concept of thermally conductive polymer matrix composite foams seems to be counter-intuitive, and the underlying factors that govern polymer matrix composite foam’s effective thermal conductivity (k_eff) were not clear. In this context, this paper develops new models to predict polymer matrix composite foams’ k_eff and to elucidate the dependence of k_eff on their cellular morphology. Linear low density polyethylene–hexagonal boron nitride composite foams were used as case examples to verify the model. The model demonstrated that the composite foam’s k_eff would be promoted when the volume expansion was over a threshold percentage. At low hexagonal boron nitride loadings (e.g. 10 vol.%) and fixed cell size, linear low density polyethylene–hexagonal boron nitride foams’ k_eff increased with volume expansion percent through an increase in cell population density. Constrained foaming with preferential expansion in the heat flow direction also enhanced their k_eff.

Keywords

Effective thermal conductivity filler alignment modelling polymer matrix composite foams thermal resistor network

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Modelling of effective thermal conductivity of polymer matrix composite foams with biaxially aligned filler networks

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