Analytical and numerical investigations of base isolation system with negative stiffness devices

This study presents an innovative base isolation system with negative stiffness devices (NSDs) for seismic pro-tection of structures. It is implemented by the vertical pre-stressed helical springs to generate variable stiffness in the lateral direction. The design concept of the NSDs is first introduced, and the induced lateral restoring force was given accordingly. The equation of motion with strong nonlinearity is established and simplified using the Taylor series expansion. The theoretical dynamic solution is obtained using the harmonic balance method, which is further compared with the numerical approach using the direct integration method. Results show that the theoretical solution could match well with numerical simulation when the system nonlinearity is insignificant. For this reason, a corresponding parameter with its recommended critical value is provided to determine the applicability of the analytical approach. Performance evaluation of the isolation system with NSDs is conducted through the incremental dynamic analysis using two single-degree-of-freedom models. As expected, the auxiliary NSDs promote the isolation effect under minor and moderate earthquakes, while the large isolation deformation could be reduced under major earthquakes. Moreover, the NSDs are especially effective under near-field earthquakes with pulse-like components. Some potential drawbacks of this isolation system are also discussed, including the potential amplified acceleration response induced by the restraining of excessive displacement and considerable residual deformation after earthquake shaking.

Automated summary

This study presents an innovative base isolation system using negative stiffness devices (NSDs) for seismic protection of structures. The theoretical dynamic solution is matched well with numerical simulation when the system nonlinearity is insignificant. Performance evaluation shows that the NSDs promote the isolation effect under minor and moderate earthquakes, reducing the large isolation deformation under major earthquakes, especially effective under near-field earthquakes.