Numerical Study on Reserve Fire Resistance of Continuous Steel Columns in Buildings

Numerical Study on Reserve Fire Resistance of Continuous Steel Columns in Buildings

A simple design method typically applies a Fire Resistance Rating (FRR) to structural components in isolation based on their performance in the fire test. This approach naturally assumes that the interaction between these components does not degrade their fire performance. To assess the reliability...

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Bibliographic Details
Published in:Fire technology Vol. 60; no. 4; pp. 2719 - 2740
Main Authors: Meng, Fan-Qin, Clifton, G Charles, Abu, Anthony, Lim, James
Format: Journal Article
Language:English
Published: New York Springer US 01-07-2024
Springer Nature B.V
Subjects:
Building design
Characterization and Evaluation of Materials
Civil Engineering
Classical Mechanics
Component reliability
Contact force
Design
Earthquakes
Engineering
Fire resistance
Fires
Flanges
Mathematical models
Numerical models
Performance degradation
Physics
Reserve capacity
Resilience
Seismic activity
Simulation
Slabs
Steel
Steel beams
Steel columns
Stiffeners
Structural reliability
Structural steels
Continuous columns
Numerical simulation
Explicit analysis
Reserve fire resistance
Structural fire resilience
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Summary:A simple design method typically applies a Fire Resistance Rating (FRR) to structural components in isolation based on their performance in the fire test. This approach naturally assumes that the interaction between these components does not degrade their fire performance. To assess the reliability of this assumption, this paper numerically investigated the fire performance of continuous steel columns, incorporating the effects coming from connected steel beams and composite slabs. A 3-step numerical validation, using ABAQUS and following a recommended general simulation process, confirmed the numerical model's accuracy for this research through agreement with experimental tests. The simulation results founded that the well-designed interior column subassemblage, T4-90, failed to reach the designed FRR. This is due to compression coming from the continuous bending beam through the beam bottom flange, significantly weakening the column performance. Rib stiffeners between column flanges are proposed to enhance resistance to contact forces from beam flanges during severe fires. However, the simulation found that the steel columns with rib stiffeners might fail immediately after reaching the FRR. Thus, this research introduced the concept of 'reserve fire resistance' (authentic fire resistance to FRR) to evaluate structural steel elements' resilience to fires exceeding the specified FRR, aligning with the concept of reserve capacity of structural resilience to earthquakes. Based on this concept, new limiting temperature design equations were proposed and validated for steel columns derived from their performance, which yielded an average reserve fire resistance of 1.30 herein.
ISSN:0015-2684
1572-8099
DOI:10.1007/s10694-023-01510-8