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混合桁架桥中钢-混凝土连接节点的力学行为与破坏模式:试验研究

Mechanical Behavior and Failure Mode of Steel-Concrete Connection Joints in a Hybrid Truss Bridge: Experimental Investigation.

作者信息

Tan Yingliang, Zhu Bing, Qi Le, Yan Tingyi, Wan Tong, Yang Wenwei

机构信息

Department of Bridge Engineering, School of Civil Engineering, Southwest Jiaotong University, Chengdu 610031, China.

Department of Civil Engineering, School of Civil and Hydraulic Engineering, Ningxia University, Yinchuan 750021, China.

出版信息

Materials (Basel). 2020 Jun 3;13(11):2549. doi: 10.3390/ma13112549.

DOI:10.3390/ma13112549
PMID:32503245
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7321451/
Abstract

The core part of a hybrid truss bridge is the connection joint which combines the concrete chord and steel truss-web members. To study the mechanical behavior and failure mode of steel-concrete connection joints in a hybrid truss bridge, static model tests were carried out on two connection joints with the scale of 1:3 under the horizontal load which was provided by a loading jack mounted on the vertical reaction wall. The specimen design, experimental setup and testing procedure were introduced. In the experiment, the displacement, strain level, concrete crack and experimental phenomena were factually recorded. Compared with the previous study results, the experimental results in this study demonstrated that the connection joints had the excellent bearing capacity and deformability. The minimum ultimate load and displacement of the two connection joints were 5200 kN and 59.01 mm, respectively. Moreover, the connection joints exhibited multiple failure modes, including the fracture of gusset plates, the slippage of high-strength bolts, the local buckling of compressive splice plates, the fracture of tensile splice plates and concrete cracking. Additionally, the strain distribution of the steel-concrete connection joints followed certain rules. It is expected that the findings from this paper may provide a reference for the design and construction of steel-concrete connection joints in hybrid truss bridges.

摘要

混合桁架桥的核心部分是连接节点,它将混凝土弦杆和钢桁架腹杆连接在一起。为了研究混合桁架桥中钢 - 混凝土连接节点的力学性能和破坏模式,在两个比例为1:3的连接节点上进行了静力模型试验,水平荷载由安装在竖向反力墙上的加载千斤顶提供。介绍了试件设计、试验装置和试验过程。在试验中,如实记录了位移、应变水平、混凝土裂缝和试验现象。与以往的研究结果相比,本研究的试验结果表明连接节点具有良好的承载能力和变形能力。两个连接节点的最小极限荷载和位移分别为5200 kN和59.01 mm。此外,连接节点呈现出多种破坏模式,包括节点板断裂、高强度螺栓滑移、受压拼接板局部屈曲、受拉拼接板断裂和混凝土开裂。另外,钢 - 混凝土连接节点的应变分布遵循一定规律。期望本文的研究结果能为混合桁架桥中钢 - 混凝土连接节点的设计和施工提供参考。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c507/7321451/5a7d0754bfde/materials-13-02549-g014.jpg
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