Experimental Study on the Force Mechanism of Internal Composite Connectors in Steel–Concrete Composite Sections of Bridge Towers

Experimental Study on the Force Mechanism of Internal Composite Connectors in Steel–Concrete Composite Sections of Bridge Towers

Current research on the stress mechanisms of composite connectors within steel–concrete structures of bridge towers is sparse, and there is a lack of established experimental methods and finite element modeling techniques for studying these mechanisms. This study focuses on a specific type of compos...

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Bibliographic Details
Main Authors: Yunwei Du, Zhenqing Yu, Yuyang Chen, Niujing Ma, Ronghui Wang
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Buildings
Subjects:
single-layer composite connectors
perforated plate connector
shear stud
push-out test
finite element model
failure mode
Online Access:https://www.mdpi.com/2075-5309/15/13/2284
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Summary:Current research on the stress mechanisms of composite connectors within steel–concrete structures of bridge towers is sparse, and there is a lack of established experimental methods and finite element modeling techniques for studying these mechanisms. This study focuses on a specific type of composite shear connector within the steel–concrete section of the Shunde Bridge tower. By employing proposed experimental methods and finite element model analysis, this research examines the load–slip curves and stress distribution of these shear connectors. It aims to elucidate the stress mechanisms and mechanical relationships between the composite connectors and the individual perforated plate connectors and shear stud connectors that comprise them. The results demonstrate that the proposed experimental methods and finite element modeling approaches effectively analyze the stress mechanisms of composite connectors, revealing that the ultimate load-bearing capacity and elastic stiffness of the composite connectors are approximately the sum of those of the individual connectors configured in parallel; The mechanical performance of the composite connectors in the steel–concrete section of the bridge tower is approximately the additive sum of the mechanical performances of the individual connectors comprising them. By comparing the experimentally measured load–slip curves with those calculated from the finite element models, it validates the modeling approach of the finite element model, and the material parameters established through material characteristic tests and literature review are reasonable.
ISSN:2075-5309

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