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Fire Technology

23.03.2024

Numerical Study on High Strength Q690 Steel Flush End-Plate Connections at Elevated Temperatures

verfasst von: Weiyong Wang, Siqi Li, Tian Ran

Erschienen in: Fire Technology

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Abstract

Exploring fire resistance of high strength steel end-plate connections is one of the key technical bases for fire resistance design and fire safety assessment of high strength steel structures. Numerical simulation and parameter analyses of high strength Q690 steel flush end-plates will contribute to a reasonable design of high strength flush end-plate connections. In this paper, a finite element model of high strength steel flush end-plate connection considering thermal creep effect was established and validated by experimental results. The thermal creep finite element model can simulate accurately heat performance, failure modes and deformations of high strength flush end-plate connections at elevated temperatures. The increase of axial compression ratio has little effect on rotation, deflection, failure time, critical temperature, and critical rotation with elevated temperatures. The increase of bending moment ratio has little effect on the development trend of rotation and deflection. Proper increase of thickness of the end-plate can improve failure time and critical rotation, and the increase range is within 7% and 36% respectively. Proper increase of diameter of bolt can improve failure time, critical temperature, and critical rotation to a certain extent, and the increase range is within 10%, 6% and 27% respectively. Proper increases of thickness of the end-plate and diameter of bolt will improve the fire resistance of flush end-plate connection.

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Metadaten
Titel
Numerical Study on High Strength Q690 Steel Flush End-Plate Connections at Elevated Temperatures
verfasst von
Weiyong Wang
Siqi Li
Tian Ran
Publikationsdatum
23.03.2024
Verlag
Springer US
Erschienen in
Fire Technology
Print ISSN: 0015-2684
Elektronische ISSN: 1572-8099
DOI
https://doi.org/10.1007/s10694-024-01568-y