Study of Thermal Conductivity and Hardness Test of Carbon Black / Polymer Micro Composite

Zweid, Muntadher Nasir; Ubaid, Ahmed Qasim; Kamas, Abbas S.

doi:10.1088/1742-6596/1892/1/012003

Cited by 4 publications

(2 citation statements)

References 7 publications

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“…In contrast, conventional fillers (carbon black, metal nanoparticles, etc.) need to be filled at a rather higher percentage (e.g., >2 or even >10 wt%) to achieve results similar to those of 3DGF [ 32 , 33 , 34 ]. This advantage of 3DGF is due not only to the high thermal conductivity of CVD graphene itself, but also to the uniformly connected 3D graphene network that is very favorable for phonon and thermal transport.…”

Section: Resultsmentioning

confidence: 99%

A Fast-Responding Electro-Activated Shape Memory Polymer Composite with Embedded 3D Interconnected Graphene Foam

Zhou

Rong

et al. 2022

Micromachines

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Shape memory polymers (SMPs) have gained increasing attention as intelligent morphing materials. However, due to the inherent electrical insulation and poor thermal conductivity of polymers, deformation and temperature control of SMPs usually require external heating devices, bringing about design inconveniences and fragility of interfaces. Herein, we report a shape memory composite that integrates reliable temperature and shape control functions into the interior. The composite is comprised of resin-based SMP and three-dimensional interconnected graphene foam (3DGF), exhibiting a high recovery rate and thermal/electrical conductivity. With only 0.26 wt% of graphene foam, the composite can improve electrical conductivity by 15 orders of magnitude, thermal conductivity by 180%, tensile strength by 64.8%, and shape recovery speed by 154%. Using a very simple Joule heating scheme, decimeter-sized samples of the composite deformed to their preset shapes in less than 10 s.

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Section: Resultsmentioning

confidence: 99%

A Fast-Responding Electro-Activated Shape Memory Polymer Composite with Embedded 3D Interconnected Graphene Foam

Zhou

Rong

et al. 2022

Micromachines

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“…From the literature review, it has been concluded that epoxy as a matrix and carbon black as reinforcement is a less explored combination for thermal conductivity enhancement application. Carbon black has considerably higher thermal conductivity as compared to epoxy (Shahamatifard et al, 2021;Zweid et al, 2021). So it is expected to produce a better thermal conductive composite with epoxy resin.…”

Section: Pfrc As Thermal Conductormentioning

confidence: 99%

Carbon Black: A Thermally Conductive Reinforcement for Epoxy Based Composite

SAHOO,

Patel,

Nanda

2023

Preprint

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Heat conduction plays a vital role in the performance and durability of any component. A wide range of applications is available which demand a good heat conduction ability. The property used to understand the heat conduction behavior in a solid is called effective thermal conductivity (Keff). It is recommended to reinforce an adequate amount of filler material in the matrix to increase the Keff of the composite. The current study used carbon black (CB) particulates, a by-product of waste tyre pyrolysis, as the reinforcing agent in the epoxy resin. The composites are prepared by solution casting method with different volume % of filler. To study the thermal behavior of samples, effective thermal conductivity, glass transition temperature (Tg), and co-efficient thermal expansion (CTE) are measured as a function of vol. % of filler. After plotting the experimental result, it is noticed that the Keff and Tg are increased, and CTE is decreased with an increase in vol. % of CB. The percolation threshold is also calculated from Keff vs. vol. % curve. Various mathematical models are incorporated to verify the experimental results of effective thermal conductivity. A finite element method (FEM) based numerical model is also developed to study the thermal conductivity behavior of composites. ANSYS MECHANICIAL APDL is used for the FEM analysis. The FEM results showed a marginal variation from experimental data at 0.9928 vol. % of CB. The reason behind this is the formation of voids during sample making, the effect of which is not taken in FEM.

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