The flexural modulus of rigid PVC/r

The flexural modulus of rigid PVC/rice hull composite was 2.71 GPa with associated flexural strength of 54.1 MPa. The effects of the concentrations and the particle sizes of the mAC on PVC/rice hull foams are evident in the plot of flexural modulus and strength presented graphically in Fig. 8. Overall, the flexural modulus and the ultimate flexural strength decreased as the level of the mAC was increased from 0 to 2.0 wt.%, but there was an upturn when the mAC reached 3.0 wt.%. The foamed composite was most flexible at 2.0 wt.% of mAC. This trend was observed over all the particle sizes of the mAC studied. The identical flexural behavior of the foamed composites was also reported by Paterson and Bledzki
and Faruk. The large mAC particle size of 22 lm gave a PVC/rice hull foamed composite with the highest flexural modulus while the 5 lm mAC provided the lowest one. For the case of 5 lm mAC, the flexural modulus of the foamed composites with 0.5, 1.0, 1.5, 2.0 and 3.0 wt.% of mAC were 1.80, 1.47, 1.02, 0.89 and 1.43 GPa respectively. For the 22 lm mAC, the flexural moduli of the foamed composites were 2.45, 2.15, 2.02, 1.95 and 2.24 GPa. The ultimate flexural strength at various mAC particle sizes and content, shown in Fig. 8b, depicted a similar trend as the flexural modulus. The larger mAC particle sizes gave rise to yielding PVC/rice hull foamed composites with greater ultimate flexural strength while the 5 lm mAC led to foams with the lowest strength. As is evident in Fig. 8, the incorporation of mAC led to a significant reduction of both the flexural modulus and the ultimate flexural strength due to the formulation of numerous porous cells in the PVC/rice hull composite structure. The increment of the modulus and the strength at 3.0 wt.% of mAC resulted from the large amount of evolved gas densely distributed at the skin and subskin regions of the PVC/rice hull foams.