Abstract
Earthquake loss estimation in composite-steel moment resisting frames (MRFs) necessitates a proper estimation of the level of damage in steel beam-to-slab connections. These usually feature welded headed shear studs to ensure the composite action between the concrete slab and the steel beam. In partially composite steel beams, earthquake-induced damage in the shear studs and the surrounding concrete occurs due to shear stud slip demands. Within such a context, this paper proposes shear slip-based fragility functions to estimate the probability of being or exceeding four damage states in steel beam-slab connections. These damage states include cracking and crushing of the concrete slab in the vicinity of the shear studs, as well as damage in the shear studs themselves. The developed fragility functions are obtained from a gathered dataset of 42 cyclic push-out tests. They incorporate uncertainty associated with specimen-to-specimen variability, along with epistemic uncertainty arising from the finite number of available experimental results. An application of the proposed fragility functions is conducted on a six-story building with composite-steel MRFs. It is shown that steel beam-slab connections along the building height only exhibit light cracking (i.e., crack sizes of 0.3 mm or less) at design basis seismic events. At seismic intensities associated with a low probability of occurrence seismic event (i.e., return period of 2475 years) the nonlinear building simulations suggest that the 25% reduction of the shear stud resistance in steel beam-slab connections with beam depths of 500 mm or less is not imperative to maintain the integrity of the shear stud connectors.
Highlights
In composite-steel moment-resisting frames (MRFs) seismic loads are transmitted to the MRF through bearing on the column flanges, friction and the shear stud connectors between steel beams and the concrete slab
At seismic intensities associated with a low probability of occurrence seismic event the nonlinear building simulations suggest that the 25% reduction of the shear stud resistance in steel beam-slab connections with beam depths of 500 mm or less is not imperative to maintain the integrity of the shear stud connectors
While this reduction aims at preventing loss of composite action, there is no quantitative information regarding the extent of potential earthquake-induced damage in the steel beam-slab connection to inform post-earthquake repair actions
Summary
In composite-steel moment-resisting frames (MRFs) seismic loads are transmitted to the MRF through bearing on the column flanges, friction and the shear stud connectors between steel beams and the concrete slab. The objective of this paper is to develop fragility functions that permit the estimation of the level of damage in steel beam-slab connections in composite floor systems as a function of the imposed local slip demands on the headed shear stud connectors This is achieved by assembling an experimental dataset of 42 cyclic push-out tests. In order to estimate the likelihood of damage in steel beam-slab connections, slip-based fragility functions are developed based on the assembled dataset of Table 1 These provide the probability of reaching or exceeding a damage state as a function of the peak slip demands on headed shear stud connectors. Based on these values, the potential damage in the steel beam-slab connection is captured by using the developed fragility functions. Figure 13Ashows the likelihood of occurrence of each damage state based on the fragility functions that were derived from the FIGURE 12 | Peak Δs profile for the prototype composite steel MRF at (A) DBE seismic intensity and (B) MCE seismic intensity
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