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Effects of soil‐structure interaction and lateral design load pattern on performance‐based plastic design of steel moment resisting frames
Author(s) -
Ganjavi Behnoud,
Gholamrezatabar Abolfazl,
Hajirasouliha Iman
Publication year - 2019
Publication title -
the structural design of tall and special buildings
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.895
H-Index - 43
eISSN - 1541-7808
pISSN - 1541-7794
DOI - 10.1002/tal.1624
Subject(s) - structural engineering , ductility (earth science) , flexibility (engineering) , moment (physics) , strength reduction , seismic analysis , reduction (mathematics) , seismic loading , base (topology) , structural load , soil structure interaction , geotechnical engineering , engineering , materials science , mathematics , finite element method , composite material , statistics , geometry , creep , mathematical analysis , physics , classical mechanics
Summary The effects soil‐structure interaction (SSI) and lateral design load‐pattern are investigated on the seismic response of steel moment‐resisting frames (SMRFs) designed with a performance‐based plastic design (PBPD) method through a comprehensive analytical study on a series of 4‐, 8‐, 12‐, 14‐, and 16‐story models. The cone model is adopted to simulate SSI effects. A set of 20 strong earthquake records are used to examine the effects of different design parameters including fundamental period, design load‐pattern, target ductility, and base flexibility. It is shown that the lateral design load pattern can considerably affect the inelastic strength demands of SSI systems. The best design load patterns are then identified for the selected frames. Although SSI effects are usually ignored in the design of conventional structures, the results indicate that SSI can considerably influence the seismic performance of SMRFs. By increasing the base flexibility, the ductility demand in lower story levels decreases and the maximum demand shifts to the higher stories. The strength reduction factor of SMRFs also reduces by increasing the SSI effects, which implies the fixed‐base assumption may lead to underestimated designs for SSI systems. To address this issue, new ductility‐dependent strength reduction factors are proposed for multistory SMRFs with flexible base conditions.