Geocells have been widely applied to geotechnical engineering, but their reinforcement effects are still not fully understood. Such difficulties are primarily due to geocells not to be easily tested in the laboratory. Thus, selecting appropriate parameters for designing geocell-reinforced structures remains a difficult task. This study analyzed sand reinforced with geocells by the finite element software PLAXIS. In the beginning, verification of the numerical model was based on the triaxial compression test results of geocell-reinforced sand samples, with material parameters, boundary conditions, and strength parameters appropriately selected. After that, the numerical model was used to investigate the effects of size and shape of geocell as well as the effect of soil surrounding the geocells. Furthermore, the relationship of the compressive strength between multiple cells and single cell was found. From the verification of the numerical model, it has been found that the elastic modulus of the seam strengths of cell junction is very important. The analytical results show that the apparent cohesion of reinforced soil is closely related to the diameter of geocell; the cell with smaller diameter induces more apparent cohesion. Nevertheless, the friction angle of reinforced soil seems to be insignificantly affected. In addition, geocell under triaxial compression tends to become cylindrical shape, irrespective of its original shape. The deformation of geocell therefore has effect on the development of the tensile strength of the reinforcement, e.g., hexagonal packs showed the highest friction angle since their shape has many corners. Further, if there is soil surrounding cells, the compression strength of the sample can be obtained through the proposed modification equation. Finally, the relationship between the strengths of multiple cells and single cell was obtained, and it was found to be dependent on the aspect ratio of the geocell.