Seismic performance and probabilistic collapse resistance assessment of steel moment resisting frames with fluid viscous dampers.
Seismic performance and probabilistic collapse resistance assessment of steel moment resisting frames with fluid viscous dampers.
This paper evaluates the seismic resistance of steel moment resisting frames (MRFs) with supplemental fluid viscous dampers against collapse. A simplified design procedure is used to design four different steel MRFs with fluid viscous dampers where the strength of the steel MRF and supplemental damping are varied. The combined systems are designed to achieve performance that is similar to or higher than that of conventional steel MRFs designed according to current seismic design codes. Based on the results of nonlinear time history analyses and incremental dynamic analyses, statistics of structural and non-structural response as well as probabilities of collapse of the steel MRFs with dampers are determined and compared with those of conventional steel MRFs. The analytical frame models used in this study are reliably capable to simulate global frame collapse by considering full geometric nonlinearities as well as the cyclic strength and stiffness deterioration in the plastic hinge regions of structural steel members. The results show that, with the aid of supplemental damping, the performance of a steel MRF with reduced design base shear can be improved and become similar to that of a conventional steel MRF with full design base shear. Incremental dynamic analyses show that supplemental damping reduces the probability of collapse of a steel MRF with a given strength. However, the paper highlights that a design base shear equal to 75% of the minimum design base shear along with supplemental damping to control story drift at 2% (i.e., design drift of a conventional steel MRF) would not guarantee a higher collapse resistance than that of a conventional MRF. At 75% design base shear, a tighter design drift (e.g., 1.5% as shown in this study) is needed to guarantee a higher collapse resistance than that of a conventional MRF. Copyright © 2014 John Wiley & Sons, Ltd
2135-2154
Seo, C-Y.
1fb058b5-ec02-4bf7-bb71-4d0bf03fe84c
Karavasilis, T.L.
15850eb0-6af4-4b6e-bab4-d5bde281b769
Ricles, J.M.
04ac4367-e263-4a40-b4c4-5ad106b1a77a
Sause, R.
ac7be883-f8d1-43e2-b8bd-dce430a4d3c3
November 2014
Seo, C-Y.
1fb058b5-ec02-4bf7-bb71-4d0bf03fe84c
Karavasilis, T.L.
15850eb0-6af4-4b6e-bab4-d5bde281b769
Ricles, J.M.
04ac4367-e263-4a40-b4c4-5ad106b1a77a
Sause, R.
ac7be883-f8d1-43e2-b8bd-dce430a4d3c3
Seo, C-Y., Karavasilis, T.L., Ricles, J.M. and Sause, R.
(2014)
Seismic performance and probabilistic collapse resistance assessment of steel moment resisting frames with fluid viscous dampers.
Earthquake Engineering & Structural Dynamics, 43 (14), .
(doi:10.1002/eqe.2440).
Abstract
This paper evaluates the seismic resistance of steel moment resisting frames (MRFs) with supplemental fluid viscous dampers against collapse. A simplified design procedure is used to design four different steel MRFs with fluid viscous dampers where the strength of the steel MRF and supplemental damping are varied. The combined systems are designed to achieve performance that is similar to or higher than that of conventional steel MRFs designed according to current seismic design codes. Based on the results of nonlinear time history analyses and incremental dynamic analyses, statistics of structural and non-structural response as well as probabilities of collapse of the steel MRFs with dampers are determined and compared with those of conventional steel MRFs. The analytical frame models used in this study are reliably capable to simulate global frame collapse by considering full geometric nonlinearities as well as the cyclic strength and stiffness deterioration in the plastic hinge regions of structural steel members. The results show that, with the aid of supplemental damping, the performance of a steel MRF with reduced design base shear can be improved and become similar to that of a conventional steel MRF with full design base shear. Incremental dynamic analyses show that supplemental damping reduces the probability of collapse of a steel MRF with a given strength. However, the paper highlights that a design base shear equal to 75% of the minimum design base shear along with supplemental damping to control story drift at 2% (i.e., design drift of a conventional steel MRF) would not guarantee a higher collapse resistance than that of a conventional MRF. At 75% design base shear, a tighter design drift (e.g., 1.5% as shown in this study) is needed to guarantee a higher collapse resistance than that of a conventional MRF. Copyright © 2014 John Wiley & Sons, Ltd
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Accepted/In Press date: 1 May 2014
e-pub ahead of print date: 5 June 2014
Published date: November 2014
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Infrastructure Group
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Local EPrints ID: 401607
URI: http://eprints.soton.ac.uk/id/eprint/401607
ISSN: 0098-8847
PURE UUID: ef4a5247-9c67-48c3-ad07-f9198e2f8dba
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Date deposited: 18 Oct 2016 15:37
Last modified: 15 Mar 2024 02:51
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Author:
C-Y. Seo
Author:
T.L. Karavasilis
Author:
J.M. Ricles
Author:
R. Sause
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