Robert B. Fleischman scite author profile

Precast concrete facilitates a construction method using durable and rapidly erectable prefabricated members to create costeffective and high-quality structures. In this method, the connections between the precast members as well as between the members and the foundation require special attention to ensure good seismic performance. Extensive research conducted since the 1980s has led to new precast concrete structural systems, designs, details, and techniques that are particularly suited for use in regions of high seismic hazard. This paper reviews the state of the art of these advances, including code developments and practical applications, related to four different systems: (1) moment frames; (2) structural walls; (3) floor diaphragms; and (4) bridges. It is concluded from this review that the widespread use of precast concrete in seismic regions is feasible today and that the jointed connection innovation introduced through precast research leads to improved seismic performance of building and bridge structures.dividual papers. This paper is part of the Journal of Structural Engineering, © ASCE, ISSN 0733-9445. © ASCE 03118001-1 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18. Copyright ASCE. For personal use only; all rights reserved. © ASCE 03118001-2 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18. Copyright ASCE. For personal use only; all rights reserved. © ASCE 03118001-3 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18. Copyright ASCE. For personal use only; all rights reserved. © ASCE 03118001-4 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18. Copyright ASCE. For personal use only; all rights reserved. © ASCE 03118001-5 J. Struct. Eng. © ASCE 03118001-10 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18. Copyright ASCE. For personal use only; all rights reserved. © ASCE 03118001-11 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18. Copyright ASCE. For personal use only; all rights reserved. © ASCE 03118001-18 J. Struct. Eng. J. Struct. Eng., 2018, 144(4): 03118001 Downloaded from ascelibrary.org by University of Notre Dame on 01/17/18.

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Development of deformable connection for earthquake‐resistant buildings to reduce floor accelerations and force responses

Tsampras

Sause

Zhang

et al. 2016

Earthq Engng Struct Dyn

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Summary: This paper presents the development of a deformable connection that is used to connect each floor system of the flexible gravity load resisting system (GLRS) with the stiff lateral force resisting system (LFRS) of an earthquake-resistant building. It is shown that the deformable connection acts as a seismic response modification device, which limits the lateral forces transferred from each floor to the LFRS and allows relative motion between the GLRS and LFRS. In addition, the floor accelerations and the LFRS story shears related to the highermode responses are reduced. The dispersion of peak responses is also significantly reduced. Numerical simulations of the earthquake response of a 12-story reinforced concrete shear wall example building with deformable connections are used to define an approximate feasible design space for the deformable connection. The responses of the example building model with deformable connections and the example building model with rigid-elastic connections are compared. Two configurations of the deformable connection are studied. In one configuration, a buckling restrained brace is used as the limited-strength load-carrying hysteretic component of the deformable connection, and in the other configuration, a friction device is used. Low damping laminated rubber bearings are used in both configurations to ensure the out-of-plane stability of the LFRS and to provide post-elastic stiffness to the deformable connection. Important experimental results from full-scale tests of the deformable connections are presented and used to calibrate numerical models of the connections.Original language English

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Preliminary results of the shake-table testing for the development of a diaphragm seismic design methodology

Schoettler¹,

Belleri²,

Zhang³

et al. 2009

pcij

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Dynamic Behavior of Rocking and Hybrid Cantilever walls in Precast Concrete Building

Belleri¹,

Schoettler²,

Restrepo³

et al. 2014

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Dynamic behavior of perimeter lateral‐system structures with flexible diaphragms

Fleischman

Farrow

2001

Earthq Engng Struct Dyn

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Building structures are typically designed using the assumption that the oor systems serve as a rigid diaphragm between the vertical elements of the lateral load-resisting system. However, long-oor span structures with perimeter lateral load-resisting systems possess diaphragms which behave quite exibly. The dynamic behaviour of such structures is dissimilar to the behavior expected of typical structures. This di erence can lead to unexpected force and drift patterns. If force levels are su ciently underestimated, inelastic diaphragm behaviour can occur, exacerbating the e ects of diaphragm exibility. Such response may lead to a non-ductile diaphragm failure or structural instability due to high drift demands in the gravity system.Analytical models were developed which capture the diaphragm exibility of structures with long-oor spans and perimeter lateral-systems. Modal examination and time-history analyses were performed to determine the e ect of diaphragm exibility and diaphragm inelastic behaviour on the dynamic behaviour of these structures.

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