Several reinforced concrete (RC) structures built in Europe in the first decades after WWII do not meet the current safety standards, as those older buildings were built without any regard to the seismic actions and the structural details for ductility. Moreover, to reduce land use and en-vironmental impact due to the construction of new buildings, governments are encouraging the upgrading and the reuse of older ones, rather than their demolition. Consequently, nowadays seismic retrofitting of existing structures is a very frequent request that civil engineers must handle. In general, such a challenge could be addressed combining member- and structure-level techniques. In principle, global (or structure-level) techniques may represent a feasible retrofit solution not only for structures characterized by low lateral stiffness, but also for build-ings exhibiting a significant number of under-designed members with respect to the design seismic action suggested by modern Codes. Furthermore, these techniques could represent a more cost-effective strategy rather than the upgrading of existing members, especially when the potential disruption of occupancy and the replacement of non-structural elements are consid-ered in the design process. More specifically, this paper aims to show how existing RC build-ings can be seismically upgraded through retrofitting by adding external steel bracing systems referred to as “exoskeletons” as they are placed along the outer surface of the building. Alt-hough such a technique has a significant impact on the structural dissipation capacity and al-lows avoiding soft-storey mechanisms, its effectiveness is generally affected by the detailing of the braces and connections against buckling and post-buckling fracture. Consequently, an ac-curate model of the nonlinear response of the exoskeleton is as essential as representing the ex-isting RC structure response in case of rare or very demanding earthquakes. In this context, this paper describes the modelling and analysis of an existing RC frame structure for which an exo-skeleton was designed according to the current Italian code.
SEISMIC RESPONSE ASSESSMENT OF AN EXISTING RC STRUCTURE RETROFITTED WITH STEEL EXOSKELETONS
Francesco Nigro;Enzo Martinelli
2023-01-01
Abstract
Several reinforced concrete (RC) structures built in Europe in the first decades after WWII do not meet the current safety standards, as those older buildings were built without any regard to the seismic actions and the structural details for ductility. Moreover, to reduce land use and en-vironmental impact due to the construction of new buildings, governments are encouraging the upgrading and the reuse of older ones, rather than their demolition. Consequently, nowadays seismic retrofitting of existing structures is a very frequent request that civil engineers must handle. In general, such a challenge could be addressed combining member- and structure-level techniques. In principle, global (or structure-level) techniques may represent a feasible retrofit solution not only for structures characterized by low lateral stiffness, but also for build-ings exhibiting a significant number of under-designed members with respect to the design seismic action suggested by modern Codes. Furthermore, these techniques could represent a more cost-effective strategy rather than the upgrading of existing members, especially when the potential disruption of occupancy and the replacement of non-structural elements are consid-ered in the design process. More specifically, this paper aims to show how existing RC build-ings can be seismically upgraded through retrofitting by adding external steel bracing systems referred to as “exoskeletons” as they are placed along the outer surface of the building. Alt-hough such a technique has a significant impact on the structural dissipation capacity and al-lows avoiding soft-storey mechanisms, its effectiveness is generally affected by the detailing of the braces and connections against buckling and post-buckling fracture. Consequently, an ac-curate model of the nonlinear response of the exoskeleton is as essential as representing the ex-isting RC structure response in case of rare or very demanding earthquakes. In this context, this paper describes the modelling and analysis of an existing RC frame structure for which an exo-skeleton was designed according to the current Italian code.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.