The present work aims to generate and analyze simulation results related to the behavior of linear and non-linear springs in the application of passive exoskeletons. The goal is to validate the feasibility of using non-linear springs for more efficient and comfortable designs for users. For such simulations, biomechanical behaviors during stair climbing were studied, as it is one of the movements that demands the most force in daily activities. The simulation was conducted by modeling the exoskeleton as a 2-degreeof-freedom robotic arm and coupling a spring in the simulation model. This allowed the analysis of energy variations in the system under various configurations and mechanical resistances of springs. To validate the simulation, a test was conducted with a humanoid robot. The test involved attaching a spring to its leg and analyzing the battery consumption during a repetitive movement. This led to the conclusion that the application of springs has an effect consistent with the simulation. In conclusion, comparing the results reveals a potential application for nonlinear springs in the system. These exhibited a more attractive behavior when compared to linear springs.