Flexural performance of transverse wet joint in steel-UHPC composite beam under negative bending moments

To mitigate the issues of concrete cracking in the negative bending moment region of traditional steel-concrete composite beams, the concept of a prefabricated steel-UHPC (ultra-high performance concrete) lightweight composite beam was employed. Taking advantage of UHPC's superior tensile prope...

Full description

Saved in:
Bibliographic Details
Published in:Journal of constructional steel research 2024-12, Vol.223, p.109029, Article 109029
Main Authors: Yan, Banfu, Li, Changyue, Qiu, Minghong, Zhu, Yanping, Hu, Meiyun
Format: Article
Language:English
Subjects:
Flexural test
Negative bending moment
Steel-UHPC composite beam
Transverse joint
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:To mitigate the issues of concrete cracking in the negative bending moment region of traditional steel-concrete composite beams, the concept of a prefabricated steel-UHPC (ultra-high performance concrete) lightweight composite beam was employed. Taking advantage of UHPC's superior tensile properties, a wet joint for the negative bending moment region of the steel-UHPC composite beam that includes a normal concrete transverse beam and a UHPC bridge deck is proposed in this study. A 1:2 scaled model bending test was conducted to experimentally study the flexural performance of the proposed wet joint and demonstrate its feasibility. The test results revealed that the interface between the transverse concrete beam and the longitudinal steel beam was generally the weak zone where failure occurred, with the fracture of the UHPC deck slab and the yielding of the steel bars in the deck recorded as the major factors contributing to the failure of the proposed joint structure. Through an actual bridge analysis, the flexural capacity of the joint structure, which was 3.7 times higher than the design load of the bridge, was quantitatively verified to meet the design requirements for practical engineering applications. In addition, the calculation method for computing the ultimate bending capacity of the joint structure was also proposed, in which the connection between the transverse concrete beam and longitudinal steel beam is considered as the crucial zone – with the analytical results showing good agreement with the experimental data. Overall, the calculation method provides a worthy reference datum for the development of steel-UHPC lightweight composite beams and their wet-joint designs in the negative moment region. •A new wet joint comprising normal concrete and UHPC for negative moment region of composite continuous beam is proposed.•Through a 1:2 scaled model validation, the proposed joint meets engineering design requirements.•A calculation method for ultimate bending capacity of the joint structure is proposed.
ISSN:0143-974X
DOI:10.1016/j.jcsr.2024.109029