Capacity Design of Coupled Composite Plate Shear Wall–Concrete-Filled System
Publication: Journal of Structural Engineering
Volume 148, Issue 4
Abstract
Composite plate shear walls–concrete-filled (C-PSW/CF) are a new and innovative lateral force–resisting system intended for high-rise buildings. High-rise building applications of this system are particularly efficient in the coupled wall configuration, in which the walls are C-PSW/CF and the coupling beams are concrete filled steel box sections. This paper presents a capacity design principle for the seismic design of coupled composite plate shear wall–concrete filled (CC-PSW/CF) systems. The capacity design principle implements a strong wall–weak coupling beam approach, in which flexural yielding occurs in the coupling beams before flexural yielding at the base of walls. The coupling beams are sized to resist the calculated seismic lateral force level. The composite walls are sized to resist an amplified seismic lateral force corresponding to the overall plastic mechanism for the structure, while accounting for the capacity-limited forces from the coupling beams and the coupling action between the walls. The paper summarizes the recommendations and requirements for appropriate sizing of the composite coupling beams and walls. These recommendations were used along with the capacity design principle to design four example (8–22-story) structures and evaluate their seismic behavior. The structures were modeled using benchmarked finite-element models and fiber-based models that accounted for the various limit states, including steel yielding, local buckling, fracture, concrete crushing, confinement, and tension cracking. The numerical models were analyzed for monotonic pushover loading and scaled seismic ground motions. The structural responses from the nonlinear pushover analysis and the nonlinear time history analyses were in accordance with the capacity limited design philosophy, thus confirming its efficacy.
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Data Availability Statement
Some or all data, models, or code that support the findings of this study are available from the corresponding author upon reasonable request.
Acknowledgments
The project was supported by the Charles Pankow Foundation and the American Institute of Steel Construction, through CPF research Grant #05-17 awarded to Michel Bruneau from the University at Buffalo and Amit H. Varma from Purdue University. All opinions, findings, conclusions, and recommendations presented in this paper are those of the authors and do not necessarily reflect the view of the sponsors. The researchers are grateful to members of the FEMA P695 peer review panel (Gregory G. Deierlein, Professor, Stanford University; Ron Klemencic, Chairman and CEO, Magnusson Klemencic and Associates; and Rafael Sabelli, Principal and Director of Seismic Design, Walter P. Moore), and members of the project advisory team (Larry Kruth, Vice President, AISC; John D. Hooper, Senor Principal/Director of Earthquake Engineering, MKA; Jim Malley, Senior Principal, Degenkolb Engineers; Bonnie Manley, Regional Director of Construction Codes and Standards, American Iron and Steel Institute; and Tom Sabol, Principal, Englekirk Institution) for their technical guidance.
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Published In
Journal of Structural Engineering
Volume 148 • Issue 4 • April 2022
Copyright
© 2022 American Society of Civil Engineers.
History
Received: Jul 15, 2021
Accepted: Nov 9, 2021
Published online: Feb 7, 2022
Published in print: Apr 1, 2022
Discussion open until: Jul 7, 2022
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