2021
DOI: 10.1002/eqe.3570
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Development of rocking isolation bearing system (RIBS) to control excessive seismic responses of bridge structures

Abstract: Rocking structures are recognized as an effective seismic response modification technique due to their peculiar dynamic characteristics. Meanwhile, in bridge structures, strong ground motions have frequently caused a rocking motion of pin bearings around their two toes, resulting in the pulling-out of anchor bolts. This study, motivated by the promising features of rocking behaviors, seeks to develop a rocking isolation bearing system (RIBS) to control excessive response in bridges. An example bridge featuring… Show more

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Cited by 6 publications
(16 citation statements)
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“…The maximum pier displacement tended to increase with a larger α (from 42 to 51 and 62 mm in the X direction, and from 30 to 55 and 80 mm in the Y direction), but was still nearly 50% smaller than that in the fixed bearing condition. These observations indicate that the dynamic characteristics of the bridge structure can also be effectively modified by the inclined angle α, which is consistent with the findings for the Uni‐RIBS 48 . This is important for the application of the Bi‐RIBS as an isolation bearing since the adjustment of a Bi‐RIBS with various inclined angles is easier than the adjustment of its size due to the limited space around the bearing part.…”
Section: Dynamic Characteristics Of the Bridge With Bi‐ribssupporting
confidence: 87%
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“…The maximum pier displacement tended to increase with a larger α (from 42 to 51 and 62 mm in the X direction, and from 30 to 55 and 80 mm in the Y direction), but was still nearly 50% smaller than that in the fixed bearing condition. These observations indicate that the dynamic characteristics of the bridge structure can also be effectively modified by the inclined angle α, which is consistent with the findings for the Uni‐RIBS 48 . This is important for the application of the Bi‐RIBS as an isolation bearing since the adjustment of a Bi‐RIBS with various inclined angles is easier than the adjustment of its size due to the limited space around the bearing part.…”
Section: Dynamic Characteristics Of the Bridge With Bi‐ribssupporting
confidence: 87%
“…In addition, the proposed analytical computational model for the example bridge structure shares some similarities in kinematic characteristics with previous studies in the literature. For example, if either the X or Y components of the motion of the model are assumed to be zero (i.e., at rest in that direction), the proposed model reduces to the model of the Uni‐RIBS that we proposed in our previous study 48 . If the substructure piers are assumed to be a rigid body, the proposed model reduces to a special case of the 3‐D wobbling frame structures, 46,47 where the mass of the 3‐D wobbling columns is neglected.…”
Section: Simplified 3‐d Modeling Of the Example Bridge With Bi‐ribsmentioning
confidence: 99%
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