Abstract
This paper presents a mechanical model developed for the simulation of the monotonic behaviour of Steel frames with Reinforced Concrete infill Walls (SRCW). In particular, it deals with a specific typology of SRCW, obtained from the classical one through the interposition of dissipative elements in the columns and by stiffening and shaping the steel frame’s corners in a way to prevent the brittle failure of the concrete in compression. This system has demonstrated in past researches to be able to overcome the typical problems of SRCWs and to assure, through a capacity design approach, a global ductile behavior. The selection of the main components to be included in the model is carried out on the base of the analysis of the available experimental tests and of the results of accurate 3D Finite Element model analyses. The behaviour of each component is represented though consolidated models present in the current state-of-the-art and, where necessary, calibrated using the results of the experimental and numerical analyses. The capacity of the proposed mechanical model in representing the global behaviour of the SRCWs is finally demonstrated comparing the results in terms of force–displacement curves with the ones obtained through the refined 3D Finite Element models.
Highlights
The paper presents a proposal for a component-based mechanical model of dissipative Steel frames with Reinforced Concrete infill wall (SRCWs)
The mechanical model is developed on the base of both experimental and numerical results obtained in past researches and considers the possible resisting mechanisms contributing to the monotonic global behaviour of the system in terms of stiffness and strength
To have a reliable mean for calibrating and assessing the proposed mechanical model, first of all a refined 3D finite element model is developed on the base of the indications of past researches and calibrated on the base of the available experimental results
Summary
The effects of the interaction between steel or reinforced concrete (r.c.) frames with the infill panels, being the latter made by masonry or reinforced concrete, have being studied by several researchers in the last decades (Caprili et al 2012; Ju et al 2012; Faraji Najarkolaie et al 2017; Milanesi et al 2018; Ricci et al 2018; Elwardany et al 2019) together with the possibility of improving this structural interaction (Preti et al 2012; Morandi et al 2018; Marinković and Butenweg 2019; Tsantilis and Triantafillou 2020). Morelli et al (2019) studied the influence of the shear studs on the dissipative SRCW proposed by Dall’Asta et al (2017) through detailed finite element models, showing that in the case of dissipative SRCW, the integral, non-integral and semi-integral infill frames are characterized by deep differences, both in terms of global capacity and of failure mechanism. These studies showed that assumption of a resisting mechanism based on the formation of a diagonal strut, neglecting the influence of the shear studs distribution. Out-of-plane falling of the infill wall, the SRCW-1 can be reasonably treated as the lower boundary case
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