This research aims to investigate the effect of particle size, volume fraction and dispersion on the tensile strength of particulate nanocomposites with an initial crack. The finite element micromechanical model in conjunction with linear elastic fracture mechanics was used to study the particle effect on the fracture behavior. Calculating the strain energy release rates of the crack could be applied to estimate the tensile strength of particulate nanocomposites. It was shown that the crack in the matrix is more likely to extend at the pole region of the particle in the direction of the applied tension, and there is a stress shielding zone at the equator which can reduce the possibility of crack growth. The tensile strength of particulate composites can be improved with decreasing of particle size, and the local aggregation of particles results in a decrease of tensile strength. These analytical results demonstrate a good agreement with the experimental literature. The result also showed that the tensile strength decreased with increasing of volume fraction. However, various trends of the volume fraction effect on the composite strength had been demonstrated. It seems that there is no consistent conclusion in literature to determine the relation between volume fraction and strength. Hence, to verify the above result, further experimental research is needed. In this study, for the sake of investigating the particle/matrix interface crack problem, we summarized the fracture mechanics of the bimaterial interface crack and its calculating method by finite element analysis. Although there was less use of the calculating method in this research, we still expect that the summary can be helpful for the further investigation of the particle/matrix debonding.