Effect of transverse load‐resisting elements on inelastic earthquake response of eccentric‐plan buildings

Abstract

AbstractThe accurate evaluation of code torsional provisions for plan‐eccentric structures exhibiting inelastic response relies on the adoption of appropriate systems defining both the torsionally balanced (reference) and torsionally unbalanced cases. Whilst a considerable number of analytical studies of this problem have been presented in the literature, inconsistencies have arisen in their conclusions. It is evident from a review of previous studies that one factor contributing significantly to these discrepancies arises in the definition of the structural layout. An issue of particular importance is whether the transverse load‐resisting elements oriented perpendicular to the assumed (lateral) direction of earthquake loading should, for purposes of realism, be included in model definitions. Given the diverse approaches in the existing literature, clarification of this issue is required in order to advance the understanding of inelastic torsional response behaviour and to assist the interpretation and comparison of previous studies. This paper aims to provide such clarification, based on analyses of a series of models defined rigorously according to code design provisions. Such models have been subjected to both uni‐ and bi‐directional ground motion input. It is concluded that for the flexible‐edge element, accurate estimates of additional ductility demand arising from torsional effects may be obtained from uni‐directional models (in which both the transverse elements and the corresponding earthquake component are neglected) only for medium‐period to long‐period systems. Such estimates may be over‐conservative for short‐period systems, which constitute a large proportion of systems for which code static torsional provisions are utilized. It is further concluded that models incorporating the transverse elements but analysed under uni‐directional lateral loading may underestimate by up to 100% the torsional effects in such systems, but are reasonably accurate for medium‐ and long‐period structures.