Shaking table tests of a resilient bridge system with precast reinforced concrete columns equipped with springs

This paper presents the shake table test results of a novel system for the design of precast reinforced concrete bridges. The specimen comprises a slab and four precast columns. The connections are dry and the columns are connected to the slab by an ungrouted tendon. One of the tendon ends is anchor...

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Bibliographic Details
Published in:Earthquake engineering & structural dynamics 2022-01, Vol.51 (1), p.213-239
Main Authors: Reggiani Manzo, Natalia, Vassiliou, Michalis F., Mouzakis, Harris, Badogiannis, Efstratios
Format: Article
Language:English
Subjects:
Abrasion
Concrete bridges
Concrete columns
Design
disc springs
Earthquake damage
precast bridges
Precast concrete
recentering systems
Reinforced concrete
Rigid structures
rocking
Seismic isolation
Seismic stability
shake table testing
Shake table tests
Stiffness
Tendons
Tests
Uplift
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Summary:This paper presents the shake table test results of a novel system for the design of precast reinforced concrete bridges. The specimen comprises a slab and four precast columns. The connections are dry and the columns are connected to the slab by an ungrouted tendon. One of the tendon ends is anchored above the slab, in series with a stack of washer springs, while the other end is anchored at the bottom of the column. The addition of such a flexible restraining system increases the stability of the system, while keeping it relatively flexible allowing it to experience negative post‐uplift stiffness. It is a form of seismic isolation. Anchoring the tendon within the column, caps the design moment of the foundation, and reduces its size. One hundred and eighty‐one shake table tests were performed. The first 180 caused negligible damage to the specimen, mainly abrasion at the perimeter of the column top ends. Hence, the system proved resilient. The 181st excitation caused collapse, because the tendons unexpectedly failed at a load less than 50% of their capacity (provided by the manufacturer), due to the failure of their end socket. This highlights the importance of properly designing the tendons. The tests were used to statistically validate a rigid body model. The model performed reasonably well never underestimating the median displacement response of the center of mass of the slab by more than 30%. However, the model cannot predict the torsion rotation of the slab that was observed in the tests and is due to imperfections.
ISSN:0098-8847
1096-9845
DOI:10.1002/eqe.3563