Abstract
In this study the effects and costs of implementing a base isolation system for the mitigation of the seismic risk of an existing externally-braced steel frame rack structure are analysed by means of nonlinear static (pushover) analysis. Various plan asymmetric variants, with different realistic distributions of the payload mass and occupancy levels, have been investigated under two seismic intensities. The results obtained are presented as floor plan projection envelopes of the top displacements and as plastic hinge damage patterns of the superstructure. In the presented cost evaluation, the cost of the implementation of the proposed base isolation system is compared with the estimated costs of structural repairs to the damaged structural members of the superstructure, as well as with estimated expenses of the downtime period and content damage. The results have shown that base isolation is, in general, not economically feasible for lower ground motion intensities, whereas it could be of great benefit in the case of moderate and high intensities. A simple rough cost estimation study, based on the obtained plastic hinge patterns, showed that the inclusion of the downtime period costs and content damage costs might be important parameters, which — if taken into account — could make such an isolation system viable also for lower ground motion intensities. The other benefits brought by seismic isolation, such as savings on the building design costs, reductions in the threat to employees’ lives, and others, were, however, not included in the presented study. The comparison is done only for two deterministic scenarios of seismic attack, e.g. for design ground motion intensity (a g =0.175 g) and for increased intensity with a g =0.25 g indicating the Maximum Considered Earthquake level.
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Note.-Discussion open until November 1, 2013. This manuscript for this paper was submitted for review and possible publication on November 14, 2011; approved on March 7, 2013.
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Kilar, V., Petrovčič, S., Koren, D. et al. Cost viability of a base isolation system for the seismic protection of a steel high-rack structure. Int J Steel Struct 13, 253–263 (2013). https://doi.org/10.1007/s13296-013-2005-6
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DOI: https://doi.org/10.1007/s13296-013-2005-6