Shake table tests of highway bridges installed with unbonded steel mesh reinforced rubber bearings

•Shake table tests verify the capability of USRBs to roll over during earthquakes.•The rollover deformation of USRBs effectively controls bearings’ unstable sliding.•USRBs are seismically more efficient in isolating the bridge deck than ULNRs.•Seismic performance of USBRs can be captured through a h...

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Bibliographic Details
Published in:Engineering structures 2020-03, Vol.206, p.110124, Article 110124
Main Authors: Li, Han, Xie, Yazhou, Gu, Yitong, Tian, Shengze, Yuan, Wancheng, DesRoches, Reginald
Format: Article
Language:English
Subjects:
Bearing steels
Bearings
Bridge maintenance
Computer simulation
Decks
Earthquake damage
Earthquake resistance
Earthquakes
Finite element method
Girder bridges
High strength steels
Highway bridges
Rollover
Rollover deformation
Rubber
Seismic activity
Seismic isolation
Seismic zones
Shake table test
Shake table tests
Sliding
Steel
Steel bridges
Steel plates
Stiffness
Transportation engineering
Unbonded laminated rubber bearing (ULNR)
Unbonded steel mesh reinforced rubber bearing (USRB)
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Summary:•Shake table tests verify the capability of USRBs to roll over during earthquakes.•The rollover deformation of USRBs effectively controls bearings’ unstable sliding.•USRBs are seismically more efficient in isolating the bridge deck than ULNRs.•Seismic performance of USBRs can be captured through a hardening material model. Previous earthquakes in China have caused significant seismic damage in short-to-medium span highway bridges due to the uncontrollable sliding of unbonded laminated rubber bearings (ULNRs). This paper investigates the soundness of replacing the ULNRs in these bridges with novel unbonded steel mesh reinforced rubber bearings (USRBs). Distinct from ULNRs that use rigid steel plates, USRBs are reinforced by flexible high-strength steel meshes to enable large and stable rollover deformations when subjected to strong earthquakes. To this end, shake table tests have been carried out for a two-span steel girder bridge that is isolated by ULNRs and USRBs, respectively. The test bridge was designed with a scale factor of 1/15 by maintaining the similarity of the deck mass, pier longitudinal stiffness, and bearing lateral stiffness for a typical prototype bridge in high seismic zones in China. Various types of sensors were used to monitor the dynamic responses of the bridge when excited by four different sets of earthquake motions. Test results show that USRBs not only exhibit a higher isolation efficiency in limiting the deck inertia force, but also outperform ULNRs in controlling the sliding of the bearings. Moreover, a phenomenological material model is utilized to simulate the hysteretic behavior of the USRBs, where the bridge’s time-history responses have been validated against the experimental outcomes. This paper illustrates that the use of USRBs can be a cost-effective, robust, and reliable substitute for the ULNRs to enhance the seismic resilience of the transportation infrastructure in China.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2019.110124