Experimental investigation of force transmission performance in joint of steel truss web member-concrete composite truss arch
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摘要:
为研究新型钢桁腹杆-混凝土组合桁式拱节点的承载力,并为节点剪力连接件的设置提供依据,以乌蒙山大桥为工程背景,开展了4个设置不同剪力连接件的节点试验研究;考察了节点试件的破坏模式及承载力,对比分析了不同剪力连接件的传力效果,并进行了现有规范中剪力连接件承载力计算方法的适用性对比分析。分析结果表明:各节点试件均发生受压腹杆及受压腹杆连接处节点板的屈曲破坏,节点板与混凝土界面黏结良好,未出现破坏现象;各节点试件承载力均大于2倍设计荷载,满足设计要求;剪力连接件能够将弦杆型钢所受腹杆轴力传递给弦杆混凝土,且对节点中心以下1倍腹杆宽度范围内影响最大;贯穿钢筋的传力效果较栓钉更好,仅设置贯穿钢筋和同时设置贯穿钢筋与栓钉的传力效果差异很小,从而得提出适用于贯穿钢筋和栓钉抗剪承载力计算的建议规范。研究成果可为钢桁腹杆-混凝土组合桁式拱节点的设计提供参考。
Abstract:To investigate the bearing capacity of a novel steel truss web member-concrete composite arch joint, and to provide a basis for arrangement of shear connectors of the joint, tests were conducted on four joint specimens with different shear connectors based on the engineering background of the Wumengshan Bridge. The failure modes and bearing capacity of the joint specimens were examined. The force transmission performance of the different shear connectors was comparatively analyzed. The applicability of existing code-based methods for calculating the bearing capacity of the shear connectors was comparatively analyzed. The analytical results show that all joint specimens exhibit buckling failure in the compressed web members and the gusset plates at the connections of the compressed web members. The interfacial bonding between the gusset plate and the concrete remains intact, with no signs of failure observed. All joint specimens exhibit bearing capacities exceeding twice the design load, thereby meeting the design requirements. The shear connectors effectively transfer the axial force from the steel chord, which is applied by a web member, to the concrete chord, and the most significant force transmission occurs within a range equal to one width of web member below the joint center. Penetrating steel bars present a superior force transmission performance compared to studs, and the difference in force transmission between a specimen with only penetrating steel bars and that with both penetrating steel bars and studs is very small. The recommended specifications applicable to the calculation of shear bearing capacities of penetrating steel bars and studs are presented. The research findings can provide reference for the design of steel truss web member-concrete composite truss arch joints.
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图 8 应变和位移测点布置(单位:mm)
Figure 8. Arrangement of strain and displacement measuring points(unit: mm)
图 10 钢-混凝土接触面凿开后照片
Figure 10. Photograph of the steel-concrete interface after chiseling
图 16 K1与K0试件的弦杆混凝土应变比值
Figure 16. Concrete strain ratio of chord members between specimens K1 and K0
图 17 K2与K0试件弦杆混凝土应变比值
Figure 17. Concrete strain ratio of chord members between specimens K2 and K0
图 18 K1与K2试件弦杆混凝土应变比值
Figure 18. Concrete strain ratio of chord members between specimens K1 and K2
图 19 K3与K1试件弦杆混凝土应变比值
Figure 19. Concrete strain ratio of chord members between specimens K3 and K1
表 1 材料力学性能
Table 1. Mechanical properties of materials
材料 fy/MPa fu/MPa Es/GPa Q345 405.5 561.3 208 HPB300 335.2 464.1 210 HRB400 440.6 628.2 202 栓钉 354.8 487.5 205 
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表 2 抗剪承载力计算结果比较
Table 2. Comparison of calculation results of shear bearing capacity
规范 Vd/kN 贯穿钢筋 栓钉 Vu,p/kN Vp/kN Vp/Vd Vu,s/kN Vs/kN Vs/Vd GB 50917—2013 382.2 86.6 606.2 1.59 26.2 524.0 1.37 JTG/T D64-01—2015 382.2 123.2 862.4 2.26 26.8 536.0 1.40 EN 1994-2 382.2 114.7 802.9 2.10 24.5 490.0 1.28
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