Abstract
This study aims to produce novel composite artificial marble materials by bulk molding compound processes, and improve their thermal and mechanical properties. We employed stearic acid as an efficient surface modifying agent for CaCO(3) particles, and for the first time, a pretreated, recycled, polyethylene terephthalate (PET) fibers mat is used to reinforce the artificial marble materials. The innovative aspects of the study are the surface treatment of CaCO(3) particles by stearic acid. Stearic acid forms a monolayer shell, coating the CaCO(3) particles, which enhances the compatibility between the CaCO(3) particles and the matrix of the composite. The morphology of the composites, observed by scanning electron microscopy, revealed that the CaCO(3) phase was homogeneously dispersed in the epoxy matrix under the support of stearic acid. A single layer of a recycled PET fibers mat was pretreated and designed in the core of the composite. As expected, these results indicated that the fibers could enhance flexural properties, and impact strength along with thermal stability for the composites. This combination of a pretreated, recycled, PET fibers mat and epoxy/CaCO(3)-stearic acid could produce novel artificial marble materials for construction applications able to meet environmental requirements.