Nowadays, in the face of slopes or deep excavation projects where the water level is not easy to describe, the shear strength of the undrained state is used for design. The result tends to be conservative and convenient. Therefore, it has become the most important strength indicator for the geotechnical engineering community. However, compared with the effective stress parameters, the mechanical behavior can be expressed in terms of friction. The undrained shear strength can only represent the carrying capacity of the soil under undrained conditions, and has no physical meaning. Therefore, this study was first conducted by the triaxial test. The effective stress parameters of sand were obtained and the soil undrained test was simulated by the finite element software PLAXIS 2D. It is hoped that the relationship between the undrained strength and the effective stress parameters can be found and the physical phenomena can be defined. High fines content sand is the soil most commonly responsible for liquefaction, and it is important for the study of the properties and strength of sand containing fine-grained . Therefore, in this study, coarse-grained mixed sand with particle size was used as the test soil sample, and the fines content and drainage conditions were used as test variables, and the multistage triaxial test and unloading-reloading test were added. To investigate the effect of fines content on drainage and undrained behavior of sand and the applicability of the multistage triaxial test to the soil sample. In numerical simulation, the effective stress parameters required for the simulation are obtained through the triaxial test, and the effective stress parameters are optimized with the drainage test curve. Based on the optimized effective stress parameters, the undrained behavior of the sand was simulated. Finally, the simulation results were compared with the actual test to explore the relationship between the effective stress parameters and the undrained strength. The test results show that the fines content of sand is an important experimental factor affecting the triaxial test results, and the peak strength, pore water pressure excitation amount, elastic modulus and friction angle are all affected. Multistage triaxial test in this study, the test intensity was lower than the traditional test, which was supposed to be affected by the relative density and the dilatancy behavior of the soil, resulting in less than expected results. The numerical simulation results show that in the simulation of drainage test, the hardening soil model is more reflective of the true soil behavior than the Mohr-Coulomb model. When predicting the undrained behavior of the easily dilatable soil by the hardening soil model, it is recommended to set the m and Rf parameters to 0, which is more likely to reflect the phenomenon of different loading slopes due to pore water pressure changes. It has also been confirmed through this study that it is impossible to predict the undrained behavior of sand in the absence of an undrained test curve.