In this study, a series of component tests and seismic performance tests on the pre-bent steel strip has been conducted to explore its mechanical properties and the feasibility of using it for earthquake resistance of building structures. Component tests show that the hysteresis loops of the pre-bent steel strips are pretty stable, and richness of the hysteresis increases with the thickness of the strips as well as the disturbing amplitude. Stress analysis by ANSYS agrees well with the experimental results, which helps in getting insight of the mechanical behavior of the pre-bent steel strips. In order to further predict the seismic structural responses, the Generic Wen's Model is adopted in this study to simulate the mechanical behavior of the pre-bent steel strips. In form of a nonlinear differential equation, the Generic Wen's Model is resolved by using the fourth-order Runge-Kutta method, with parameters of the shape function calibrated to comply with the hysteresis obtained by the component tests. The nonlinear dynamic analysis of the structure is then carried out via an iterative process using the state-space approach. Seismic performance tests show that the ductile braces, consisting of the pre-bent steel strips and wide-flange steel beams (H-beams), significantly enhance the equivalent damping ratios in the lower modes of the structure, and therefore reduce the overall dynamic responses. While the higher mode responses are somewhat amplified due to stiffness strengthening by the ductile braces. The seismic performance of the ductile braces becomes more pronounced with the quake intensity increased, due to increase in the extent of yielding of the pre-bent steel strips. Simulation results of the seismic performance tests are fairly correlated with the experimental data, although the discrepancies are not negligible. The source of errors is believed to come from neglecting the H-beams in the modeling which results in over-estimation of the stiffness. It is suggested that the H-beam should be taken into account in modeling the structural system in the future.