Abstract:Traditional Chinese pavilion-type timber structure consists of a column base layer, column frame layer, paving layer and roof truss layer, of which the response of each layer under seismic waves indicates that the pavilion-type timber frame is a highly non-linear structural system, which contains a wealth of seismic mitigation and isolation mechanism. The seismic mechanism of the overall pavilion-type timber frame is sophisticated and the coordinated working mechanism, dynamic and energy dissipation performance have not been fully revealed. To investigate the dynamic and energy dissipation performance of the pavilion-type timber frame, a shaking table test of a 1/16 scaled simplified Guanyin Pavilion timber frame was carried out based on the previous study. Three seismic waves were scaled down and adjusted for peak ground acceleration (PGA) to analyze the dynamic response of the timber frame under unidirectional seismic excitation. The test results show that the response of the timber frame is little with little input acceleration, and the structural response, such as column rocking, column base sliding and column base uplifting occur with large input acceleration. The inter-story drift is mainly provided by the column frame layer, the inter-story displacement of the column frame layer decreases and the inter-story displacement of the paving layer increases as the PGA increases. Based on the displacement and acceleration responses of the specimen, the hysteresis characteristics of the timber frame are analyzed. Hysteretic curves of the timber frame present large initial stiffness before column rocking, as well as small positive second-stiffness after column rocking and negative stiffness when column base uplifting occurs. At the same time, the cumulative energy dissipation and energy dissipation proportion of each part of the specimen under different seismic excitations are analyzed. With an increasing PGA, the column base sliding becomes the main energy dissipation mode, and the greater the PGA, the more energy dissipation proportion of the column rocking of the column frame layer and the less energy dissipation proportion of the paving layer are.