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    Experimental Investigation into the Seismic Performance of GFRP Tube–Confined Concrete-Encased Cross-Shaped Steel Columns

    Source: Journal of Composites for Construction:;2025:;Volume ( 029 ):;issue: 003::page 04025017-1
    Author:
    Huiyu Bai
    ,
    Weichang Pei
    ,
    Suneel Kumar Yadav
    ,
    Molan Pan
    ,
    Daiyu Wang
    DOI: 10.1061/JCCOF2.CCENG-4941
    Publisher: American Society of Civil Engineers
    Abstract: Modern structures constructed from steel and concrete face two key challenges. Steel corrosion, a major shortcoming, leads to the deterioration of structural performance and can even cause premature failure. The other challenge is the structural damage caused by disasters such as earthquakes. To overcome these drawbacks, a novel composite structure has been proposed. This novel approach is called fiber-reinforced polymer (FRP) tube–confined concrete-encased cross-shaped steel column (FCCSC). Ten specimens were tested under a combined axial compression load and cyclic lateral displacement to investigate the seismic performance of the FCCSCs. The test variables included the axial compression ratio, glass fiber–reinforced polymer (GFRP) tube thickness, steel flange thickness and width, and loading direction. The FCCSCs demonstrated better ductility and energy-dissipation capacity than concrete-encased cross-shaped steel columns without FRP tubes. Additionally, the lateral loading direction was rotated by 45° to simulate bidirectional seismic action. The results revealed that, at low axial compression ratios, the rotated loading direction enhanced the seismic resistance of the FCCSC specimens. However, at high axial compression ratios, it was found to be unfavorable.
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      Experimental Investigation into the Seismic Performance of GFRP Tube–Confined Concrete-Encased Cross-Shaped Steel Columns

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    http://yetl.yabesh.ir/yetl1/handle/yetl/4309306
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    contributor authorHuiyu Bai
    contributor authorWeichang Pei
    contributor authorSuneel Kumar Yadav
    contributor authorMolan Pan
    contributor authorDaiyu Wang
    date accessioned2026-02-16T21:30:32Z
    date available2026-02-16T21:30:32Z
    date copyright2025/06/01
    date issued2025
    identifier otherJCCOF2.CCENG-4941.pdf
    identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4309306
    description abstractModern structures constructed from steel and concrete face two key challenges. Steel corrosion, a major shortcoming, leads to the deterioration of structural performance and can even cause premature failure. The other challenge is the structural damage caused by disasters such as earthquakes. To overcome these drawbacks, a novel composite structure has been proposed. This novel approach is called fiber-reinforced polymer (FRP) tube–confined concrete-encased cross-shaped steel column (FCCSC). Ten specimens were tested under a combined axial compression load and cyclic lateral displacement to investigate the seismic performance of the FCCSCs. The test variables included the axial compression ratio, glass fiber–reinforced polymer (GFRP) tube thickness, steel flange thickness and width, and loading direction. The FCCSCs demonstrated better ductility and energy-dissipation capacity than concrete-encased cross-shaped steel columns without FRP tubes. Additionally, the lateral loading direction was rotated by 45° to simulate bidirectional seismic action. The results revealed that, at low axial compression ratios, the rotated loading direction enhanced the seismic resistance of the FCCSC specimens. However, at high axial compression ratios, it was found to be unfavorable.
    publisherAmerican Society of Civil Engineers
    titleExperimental Investigation into the Seismic Performance of GFRP Tube–Confined Concrete-Encased Cross-Shaped Steel Columns
    typeJournal Article
    journal volume29
    journal issue3
    journal titleJournal of Composites for Construction
    identifier doi10.1061/JCCOF2.CCENG-4941
    journal fristpage04025017-1
    journal lastpage04025017-13
    page13
    treeJournal of Composites for Construction:;2025:;Volume ( 029 ):;issue: 003
    contenttypeFulltext
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