In this study, SUS304 stainless steel tubes with local sharp-notched depths of 0.2, 0.4, 0.6, 0.8 and 1 mm were subjected to cyclic bending for investigating relative mechanical behavior and buckling failure. From observing the experimental moment-curvature relationship, when the number of cycles increased, the bending moment also increased. The relationship became a steady loop after several bending cycles. In addition, the notch depth had no influence on the moment-curvature relationship. Regarding the ovalization-curvature relationship, when the number of cycles increased, it exhibited an increased and ratcheted manner. The greater the depth of the notch, the more unsymmetrical the ovalization-curvature relationship became, and the greater the increase of the ovalization. Furthermore, although five local sharp-notched depths were tested, only five nearly parallel lines were observed for the controlled curvature-number of cycles that produced a buckling relationship in the log-log scale. The finite element ANSYS software package was used to simulate the moment-curvature and ovalization-curvature relationships. In addition, this study proposes a theoretical model for simulating the controlled curvature-number of cycles to produce the buckling relationship. Through comparison of the experimental data, the theoretical model could appropriately simulate the experimental findings.