Abstract:
A seismic assessment study of two historical masonry arch bridges, with different geometries and spans, is
presented. The seismicity of the two locations was analyzed in order to define the seismic action to be applied.
Artificial ground motion records were generated accordingly, and real ground motions were also used. The two
numerical models were created with a 3D discrete element code. The accuracy of the deformability of the block
models was verified by comparison with a finite element model. In situ measurements of the natural frequencies
were available for one of the bridges, providing further means for model calibration. Time domain dynamic
analyses were performed with each set of ground motions, allowing an evaluation of damage and failure modes
under seismic action. The shorter span bridge was found to withstand the regulatory records with minimum
damage. In contrast, the longer span bridge displayed a significant vulnerability to earthquake action. The study
shows that rigid block models have the ability to represent effectively the dynamic elastic response of the bridges
and can be calibrated by ambient vibration measurements. Furthermore, the discrete element models provide a
powerful tool to investigate the nonlinear dynamic response and failure of these structures, which has to be based
on a comprehensive set of dynamic records.