Finite Element Analysis of Eccentrically Braced Frames with Removable Link

Nandor Mago; Kevin Cowie; George Charles Clifton

doi:10.4028/www.scientific.net/KEM.763.518

Paper Titles

Comparison of Hysteretic Models for Steel Beams Calibrated by Means of Multi-Objective Optimisation
p.487

Finite Element Analysis on K-Type External Braced Steel Frame System
p.495

High-Performance Computer-Aided Optimization of Viscous Dampers for Improving the Seismic Performance of a Tall Steel Building
p.502

On-Line Testing of Steel Brace Connections Using Non-Linear Substructuring and Force-Displacement Combined Control
p.510

Finite Element Analysis of Eccentrically Braced Frames with Removable Link
p.518

A Finite Element Study of Non-Orthogonal Bolted Flange Plate Connections for Seismic Applications
p.525

Numerical Model of Cold Press-Formed Square Steel Tube Columns Considered with Degradation Behavior due to Local Buckling and/or Fracture
p.533

Cyclic Performance of a Lightweight Rapidly Constructible and Reconfigurable Modular Steel Floor Diaphragm
p.541

Floor Diaphragm In-Plane Modelling Using Elastic Truss Elements
p.549

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Finite Element Analysis of Eccentrically Braced Frames with Removable Link

Abstract:

Steel eccentrically braced frames (EBFs) are expected to sustain damage during an ultimate limit state design level earthquake through repeated cyclic plastic deformation of the active link. Traditionally the active link has been integral with the collector beam, but following the 2010/2011 Canterbury earthquakes, the benefit of having a readily replaceable active link became apparent. The development of this was undertaken by New Zealand Heavy Engineer Research Association (HERA) and Steel Construction New Zealand (SCNZ), with input from the University of Auckland. This paper describes the finite element analyses performed to determine the behaviour of the system including the bolted endplate connections through the range of inelastic cyclic loading expected. The numerical simulations answer a number of questions, like at which loading cycle the von Mises stress is above 300MPa in collector beam adjacent to the removable link; history of all bolt forces; component forces (shear) in slab and removable link; rotation of the link versus cycles; equivalent plastic strain contour for the last cycle and others. This paper also describes how the interaction with the concrete slab was modelled in the elastic and inelastic range.