Extension of the hybrid force/displacement (HFD) seismic design method to 3D steel moment-resisting frame buildings
Extension of the hybrid force/displacement (HFD) seismic design method to 3D steel moment-resisting frame buildings
The hybrid force/displacement (HFD) seismic design method for planar steel frames developed by the authors is extended to 3D steel buildings using moment-resisting frames. HFD combines the advantages of both the displacement-based and the force-based seismic design methods and reduces or eliminates their disadvantages. An extensive response databank is developed through nonlinear dynamic analyses on 38 steel space frames designed according to Eurocodes 3 and 8 and subjected to 42 pairs of earthquake ground motions. This response databank is then utilized for the development of empirical formulae providing the behavior factor as a function of the geometrical and dynamic characteristics of the building, including its accidental eccentricity, as well as the target maximum interstorey drift ratio and local ductility. Thus, the proposed seismic design method, eventhough works as a force-based design one, controls structural and non-structural damage through the use of a behavior factor, which is a function of seismic deformation demands. Numerical examples are presented to illustrate the proposed method and demonstrate its merits over the force-based seismic design method of Eurocode 8.
Steel space frames, Hybrid force/displacement design, Moment resisting frames, Regular Frames , Behaviour factor controlling deformation
486-504
Tzimas, A.S.
672c8796-d18f-4126-b92c-bef73bc2c6aa
Karavasilis, T.L.
15850eb0-6af4-4b6e-bab4-d5bde281b769
Bazeos, N.
a7030733-6d22-4723-860c-71f0e0d4a53c
Beskos, D.E.
9fa0ddd7-599f-46b3-953b-0b1950992c87
15 September 2017
Tzimas, A.S.
672c8796-d18f-4126-b92c-bef73bc2c6aa
Karavasilis, T.L.
15850eb0-6af4-4b6e-bab4-d5bde281b769
Bazeos, N.
a7030733-6d22-4723-860c-71f0e0d4a53c
Beskos, D.E.
9fa0ddd7-599f-46b3-953b-0b1950992c87
Tzimas, A.S., Karavasilis, T.L., Bazeos, N. and Beskos, D.E.
(2017)
Extension of the hybrid force/displacement (HFD) seismic design method to 3D steel moment-resisting frame buildings.
Engineering Structures, 147, .
(doi:10.1016/j.engstruct.2017.06.013).
Abstract
The hybrid force/displacement (HFD) seismic design method for planar steel frames developed by the authors is extended to 3D steel buildings using moment-resisting frames. HFD combines the advantages of both the displacement-based and the force-based seismic design methods and reduces or eliminates their disadvantages. An extensive response databank is developed through nonlinear dynamic analyses on 38 steel space frames designed according to Eurocodes 3 and 8 and subjected to 42 pairs of earthquake ground motions. This response databank is then utilized for the development of empirical formulae providing the behavior factor as a function of the geometrical and dynamic characteristics of the building, including its accidental eccentricity, as well as the target maximum interstorey drift ratio and local ductility. Thus, the proposed seismic design method, eventhough works as a force-based design one, controls structural and non-structural damage through the use of a behavior factor, which is a function of seismic deformation demands. Numerical examples are presented to illustrate the proposed method and demonstrate its merits over the force-based seismic design method of Eurocode 8.
Text
HFD_PAPER - Corrected
- Accepted Manuscript
More information
Accepted/In Press date: 6 June 2017
e-pub ahead of print date: 7 August 2017
Published date: 15 September 2017
Keywords:
Steel space frames, Hybrid force/displacement design, Moment resisting frames, Regular Frames , Behaviour factor controlling deformation
Identifiers
Local EPrints ID: 414176
URI: http://eprints.soton.ac.uk/id/eprint/414176
ISSN: 0141-0296
PURE UUID: 581c3764-98cb-422f-a149-28919504fd98
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Date deposited: 15 Sep 2017 16:30
Last modified: 16 Mar 2024 05:36
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Contributors
Author:
A.S. Tzimas
Author:
T.L. Karavasilis
Author:
N. Bazeos
Author:
D.E. Beskos
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