Optimized retrofit of seismically designed structures to withstand progressive collapse

Georgios S. Papavasileiou; Dimos C. Charmpis

doi:10.7712/120115.3639.1651

Optimized retrofit of seismically designed structures to withstand progressive collapse

Georgios S. Papavasileiou^*, Dimos C. Charmpis^*

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Citation (Scopus)

Abstract

Seismically designed buildings possess the necessary properties to withstand the design earthquake excitations and limit structural damage to the desired level. This is achieved by appropriately defining individual member capacities, interstorey and global stiffnesses and energy dissipation mechanisms based on the provisions of current design codes. However, such provisions do not suffice, in order to protect a structure from disproportional extent of damage when a local failure occurs. Hence, in order to increase their progressive collapse resistance, existing seismically designed buildings need to be appropriately retrofitted. This paper presents an optimization procedure for the retrofit of seismically designed buildings, in order to increase their capacity to sustain local damage without extensive propagation leading to severe structural failure (partial/full collapse). Two retrofit methods for seismically designed steel-concrete composite buildings are presented and assessed with respect to their cost-effectiveness. The retrofit methods are based on: (a) the strengthening of beams in the structure or (b) the installation of bracings in the horizontal direction. Structural optimization aims to minimize the total retrofit cost, in order to determine the lowest possible need for retrofit material, enabling at the same time the comparative assessment of the two retrofit methods on a 'fair basis'.

Original language	English
Title of host publication	COMPDYN 2015 - 5th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering
Editors	M. Papadrakakis, V. Papadopoulos, V. Plevris
Publisher	National Technical University of Athens
Pages	3568-3579
Number of pages	12
ISBN (Print)	9789609999472
DOIs	https://doi.org/10.7712/120115.3639.1651
Publication status	Published - 2015

Keywords

alternate load path
column loss
damage tolerance
local failure
progressive collapse
retrofit
robustness
seismic design
structural optimization

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10.7712/120115.3639.1651

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Papavasileiou, G. S., & Charmpis, D. C. (2015). Optimized retrofit of seismically designed structures to withstand progressive collapse. In M. Papadrakakis, V. Papadopoulos, & V. Plevris (Eds.), COMPDYN 2015 - 5th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (pp. 3568-3579). National Technical University of Athens. https://doi.org/10.7712/120115.3639.1651

Papavasileiou, Georgios S. ; Charmpis, Dimos C. / Optimized retrofit of seismically designed structures to withstand progressive collapse. COMPDYN 2015 - 5th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering. editor / M. Papadrakakis ; V. Papadopoulos ; V. Plevris. National Technical University of Athens, 2015. pp. 3568-3579

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abstract = "Seismically designed buildings possess the necessary properties to withstand the design earthquake excitations and limit structural damage to the desired level. This is achieved by appropriately defining individual member capacities, interstorey and global stiffnesses and energy dissipation mechanisms based on the provisions of current design codes. However, such provisions do not suffice, in order to protect a structure from disproportional extent of damage when a local failure occurs. Hence, in order to increase their progressive collapse resistance, existing seismically designed buildings need to be appropriately retrofitted. This paper presents an optimization procedure for the retrofit of seismically designed buildings, in order to increase their capacity to sustain local damage without extensive propagation leading to severe structural failure (partial/full collapse). Two retrofit methods for seismically designed steel-concrete composite buildings are presented and assessed with respect to their cost-effectiveness. The retrofit methods are based on: (a) the strengthening of beams in the structure or (b) the installation of bracings in the horizontal direction. Structural optimization aims to minimize the total retrofit cost, in order to determine the lowest possible need for retrofit material, enabling at the same time the comparative assessment of the two retrofit methods on a 'fair basis'.",

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Papavasileiou, GS & Charmpis, DC 2015, Optimized retrofit of seismically designed structures to withstand progressive collapse. in M Papadrakakis, V Papadopoulos & V Plevris (eds), COMPDYN 2015 - 5th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering. National Technical University of Athens, pp. 3568-3579. https://doi.org/10.7712/120115.3639.1651

Optimized retrofit of seismically designed structures to withstand progressive collapse. / Papavasileiou, Georgios S.; Charmpis, Dimos C.
COMPDYN 2015 - 5th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering. ed. / M. Papadrakakis; V. Papadopoulos; V. Plevris. National Technical University of Athens, 2015. p. 3568-3579.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AB - Seismically designed buildings possess the necessary properties to withstand the design earthquake excitations and limit structural damage to the desired level. This is achieved by appropriately defining individual member capacities, interstorey and global stiffnesses and energy dissipation mechanisms based on the provisions of current design codes. However, such provisions do not suffice, in order to protect a structure from disproportional extent of damage when a local failure occurs. Hence, in order to increase their progressive collapse resistance, existing seismically designed buildings need to be appropriately retrofitted. This paper presents an optimization procedure for the retrofit of seismically designed buildings, in order to increase their capacity to sustain local damage without extensive propagation leading to severe structural failure (partial/full collapse). Two retrofit methods for seismically designed steel-concrete composite buildings are presented and assessed with respect to their cost-effectiveness. The retrofit methods are based on: (a) the strengthening of beams in the structure or (b) the installation of bracings in the horizontal direction. Structural optimization aims to minimize the total retrofit cost, in order to determine the lowest possible need for retrofit material, enabling at the same time the comparative assessment of the two retrofit methods on a 'fair basis'.

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KW - column loss

KW - damage tolerance

KW - local failure

KW - progressive collapse

KW - retrofit

KW - robustness

KW - seismic design

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PB - National Technical University of Athens

ER -

Papavasileiou GS, Charmpis DC. Optimized retrofit of seismically designed structures to withstand progressive collapse. In Papadrakakis M, Papadopoulos V, Plevris V, editors, COMPDYN 2015 - 5th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering. National Technical University of Athens. 2015. p. 3568-3579 doi: 10.7712/120115.3639.1651

Optimized retrofit of seismically designed structures to withstand progressive collapse

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Keywords

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