Cyclic behavior and failure mechanism of self‐centering energy dissipation braces with pre‐pressed combination disc springs

Cyclic behavior and failure mechanism of self‐centering energy dissipation braces with pre‐pressed combination disc springs

Summary A new type of bracing system composed of friction energy dissipation devices for energy dissipation, pre‐pressed combination disc springs for self‐centering and tube members as guiding elements is developed and experimentally studied in this paper. The mechanics of this system are explained,...

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Bibliographic Details
Published in:Earthquake engineering & structural dynamics Vol. 46; no. 7; pp. 1065 - 1080
Main Authors: Xu, Long‐He, Fan, Xiao‐Wei, Li, Zhong‐Xian
Format: Journal Article
Language:English
Published: Bognor Regis Wiley Subscription Services, Inc 01-06-2017
Subjects:
Bearing capacity
combination disc spring
Cyclic loading
Cyclic loads
Deformation
Destructive testing
Elastic deformation
Elastic limit
Energy dissipation
Energy exchange
Failure mechanisms
Fatigue tests
Hysteresis
hysteretic behavior
low cyclic reversed loading test
Mathematical analysis
Mathematical models
Mechanical properties
Mechanics
self‐centering brace
Springs (elastic)
Stiffness
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Summary:Summary A new type of bracing system composed of friction energy dissipation devices for energy dissipation, pre‐pressed combination disc springs for self‐centering and tube members as guiding elements is developed and experimentally studied in this paper. The mechanics of this system are explained, the equations governing its hysteretic responses are outlined and large‐scale validation tests of two braces with different types of disc springs are conducted under the condition of low cyclic reversed loading. The experimental results demonstrate that the proposed bracing system exhibits a stable and repeatable flag‐shaped hysteretic response with an excellent self‐centering capability and effective energy dissipation throughout the loading protocol. Furthermore, the maximum bearing force and stiffness are predicted well by the equations governing its mechanical behavior. Fatigue and destructive test results demonstrate that the proposed bracing system can maintain stable energy dissipation and self‐centering capabilities under large deformation cyclic loading even when the tube members exceed the elastic limit and that a larger bearing capacity is achieved by the system that has disc springs without a bearing surface. Copyright © 2016 John Wiley & Sons, Ltd.
ISSN:0098-8847
1096-9845
DOI:10.1002/eqe.2844