Abstract
An insufficient separation distance between adjacent buildings is the main reason for structural pounding during severe earthquakes. The lateral load resistance system, fundamental natural period, mass, and stiffness are important factors having the influence on collisions between two adjacent structures. In this study, 3-, 5- and 9-story adjacent reinforced concrete and steel moment resisting frames (MRFs) were considered to investigate the collision effects and to determine modification factors for new and already existing buildings. For this purpose, incremental dynamic analysis was used to assess the seismic limit state capacity of the structures using a developed algorithm in OpenSees software including two near-field record subsets suggested by FEMA-P695. The results of this paper can help engineers to approximately estimate the performance levels of MRFs due to pounding phenomenon. The results confirm that collisions can lead to the changes in performance levels, which are difficult to be considered during the design process. In addition, the results of the analyses illustrate that providing a fluid viscous damper between adjacent reinforced concrete and steel structures can be effective to eliminate the sudden changes in the lateral force during collision. This approach can be successfully used for retrofitting adjacent structures with insufficient in-between separation distances.
Highlights
The seismic design of structures is usually performed for a single structure, neglecting the existence of any adjacent one
One record of Pulse-Like (PL) record subsets (Kocaeli Turkey, 8/17/1999, Izmit) suggested by FEMA-P695 (2009) was selected to perform nonlinear time history analysis given that Sa (T1) = 1.34 g
The results concern only one of the beams and column hinges of the 3-story steel moment resisting frames (MRFs), similar results have been obtained for all moment-rotation curves of the considered structural models
Summary
The seismic design of structures is usually performed for a single structure, neglecting the existence of any adjacent one. Many studies show that pounding between adjacent structures during earthquakes can impose unexpected additional impact force (Sołtysik and Jankowski 2013; Elwardany et al 2019; Rezaei et al 2020; Miari et al 2020). Bulletin of Earthquake Engineering (2021) 19:317–343 load may result in extensive damages or even lead to complete structural destruction (Cole et al 2012). The structural pounding hazard is taken into account in the latest versions of seismic codes by introducing the minimum separation distance between adjacent buildings. Several structures were constructed in the past without sufficient in-between separation (see Fig. 1 for example). Eccentric contact forces due to pounding may lead to torsional movements, which can cause crucial damage in structures (Karayannis and Naoum 2018)
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