Graphite, as one of the main forms

Graphite, as one of the main forms of the sixth element in the Peri- odic Table of Elements, is abundantly available in nature. The π orbital distributed over the entire graphene sheet makes it thermally and elec- trically conductive. The thermal conductivity of graphite is about 209.34 W·m− 1·K− 1, which is three orders of magnitude of that of pure rubber. Therefore, if graphite filler is used in natural rubber with good dispersion, it surely can greatly enhance the thermal conductivity of the rubber. Wang [15] concluded that for tread rubber of radial tires, graphite could be used instead of silica, and it was possible to maintain a certain level of main properties of the compounds and vulcanizate. However, there are no detailed reports about graphite filled tire rubber for thermal conductivity improvement up to now.
In addition to the high thermal conductivity of graphite, the graphene sheets can easily slide with each other due to the weak van der Waals forces between the graphite layers. Therefore, the graphite has a soft and lubricating nature, which attributes to the relatively poor reinforcing properties of graphite for polymer. Li et al. [16], Zhao [17] and Tang et al. [18] pointed out that the graph- ite as a filler in conjunction with carbon black incorporated in rubber could improve the mechanical properties. The thermal conductivity of the composites would be better than that of the composites using graphite as a filler alone. Thus, graphite in conjunction with kinds of carbon black can improve the thermal conductivity of natural rubber on the basis of maintaining a certain level of mechanical properties.
Graphite exists as a layered material in its bulk state. Because of the high surface energy, graphite particles are easy to come together to form aggregates. As a filler, in order to utilize graphite efficiently, it is neces- sary to separate and disperse its layers in a polymeric matrix. Broadly, two methods are adopted. One is to form graphite intercalation com- pounds (GIC) [19] by intercalating various atoms, molecules, metal complexes and salts between the expanded graphene sheets. Another is surface treatment of the graphite [16,20–22].
Propylene ester copolymer emulsion is an emulsion polymeriza- tion product of acrylate or methyl propylene esters with other vinyl monomers. At present, methacrylic acid ester copolymer emul- sion, vinyl acetate/methyl acrylate copolymer emulsion, and sty- rene/methyl acrylate copolymer emulsion are widely used. Because the acrylic ester contains functional groups of ester, carboxyl and hydroxyl, it has strong polarity, and thus has good adhesive proper- ties with various substances. In addition, the acrylic emulsion bears good weather resistance, heat resistance and oil resistance, and it is non-toxic, easily synthetic, of non-environmental pollution and so on, and thus it is widely used [23–25]. If graphite particles are coated with polyacrylate in natural rubber, aggregation among the particles will be hindered for the reduction in potential energy of the surface. Therefore, the filler can achieve good dispersion in a rubber matrix, and then enhance the thermal conductivity of rubber.
The present study reported graphite filled natural rubber com- posites with good thermal conductivity. The graphite was coated with polyacrylate by the method of emulsion polymerization to achieve good dispersion in the rubber matrix and eight schemes of graphite coating were investigated. In order to obtain certain mechanical properties, carbon black N660 and acetylene black were incorporated as fillers together with graphite and the acety- lene black was also good for thermal conductivity enhancement. The curing characteristics, thermal conductivity and mechanical properties of the rubber composites were discussed in detail.