Abstract:
In Kenya, the cost of ceramic floor tiles has been increasing due to rapid population growth and urbanization. As
a result, there has been significant research into developing affordable composite tiles made from plastics and
sand to address this issue. Plastics, particularly PET, causes environmental pollution because they are non-
biodegradable and versatile. This study created a stain-resistant and flame-retardant floor tile composite using
sand and PET plastic bottle waste as a binder to address this issue. The sand was collected from Ndondo, Isiolo
County, while the PET plastic bottle waste was collected from the Nyeri County dump site in Kenya. The composite
tile was formulated by varying the amount of sand and keeping the weight of PET plastic bottle waste constant.
ZnO was added to the mixture, then coated using a pigment containing TiO2. The physiochemical properties of
the composite tile were assessed according to ASTM standards. The sand used in the study was composed of
93.90% SiO2, and the composite tile produced with 55.56% sand content had the optimum values for compression
strength and tensile strength, and water absorption (104.17 N/mm2
, 12.22 N/mm2
, and 0.21%, respectively).
Flame retardation ability improved with adding ZnO, while chemical resistivity depended on the amount of sand
added. The composite tile was mainly made of SiO2 (81.39%) and showed good resistance to acids, bases,
swimming pool salts, and household chemicals. The floor tile had varying levels of viscoelasticity (flexible to
brittle), depending on the storage modulus. Characterization of the composite revealed that PET and sand had
good crosslinking, as evidenced by FTIR analysis. XRF characterization showed that the composite tile was
mainly composed of SiO2 (81.39%). In summary, PET waste bottles can be used as a sand binder to create floor
tile composites that are stain-resistant, flame-retardant, and suitable for residential and commercial use.