Shear performance test on demountable double-bolt connectors for steel-concrete composite beams
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摘要:
为提升钢混组合结构中双螺栓连接件的力学性能,对现有双螺栓连接件构造进行了优化;设计制作了M16、M20、M24三种直径双螺栓连接件的抗剪推出试件,其类型包括原型试件与优化后试件;在此基础上,开展了抗剪推出性能试验,并结合实测的连接件剪力-相对滑移曲线及破坏模态,系统评估了优化后双螺栓连接件的抗剪承载力、峰值滑移、抗剪刚度等力学性能。试验结果表明:所有推出试件的最终破坏模态均表现为螺栓杆发生剪切断裂,断裂面呈典型脆性断口特征;优化后双螺栓连接件下侧混凝土仅有微小裂缝、无压溃剥落现象;相较于原双螺栓连接件,优化后双螺栓连接件的抗剪承载力提升约30%,峰值滑移提升约70%,平均抗剪刚度降低约65%;优化后双螺栓连接件在短螺栓与连接套筒之间增设钢垫板,使受剪面位于短螺栓杆的无螺纹段,增大其有效抗剪面积,从而增大连接件的抗剪承载力;钢垫板的加入使短螺栓杆在受剪过程中发生较大弯曲变形,显著提升连接件的延性,但也导致了连接件的抗剪刚度有所降低。提出的抗剪承载力及抗剪刚度计算方法可为双螺栓连接件在钢混组合结构中的应用提供理论参考。
Abstract:To enhance the mechanical performance of double-bolt connectors in steel-concrete composite structures, optimization was performed on the configuration of existing double-bolt connectors. Push-out specimens of double-bolt connectors with diameters of M16, M20, and M24 were designed and fabricated, including both original specimens and optimized specimens. Push-out tests were then conducted. Based on the measured shear force-relative slip curves and failure modes of connectors, the shear capacity, peak slip, and shear stiffness of the optimized double-bolt connectors were systematically evaluated. Experimental results show that the final failure mode of all push-out specimens is shear fracture of the bolt shanks, and the fracture surfaces exhibit typical brittle fracture features. For the optimized double-bolt connectors, only slight cracking occurs in the concrete at the lower side, and no crushing or spalling is observed. Compared with those of the original double-bolt connectors, the shear capacity of the optimized double-bolt connectors increases by approximately 30%, and the peak slip increases by approximately 70%, while the average shear stiffness decreases by approximately 65%. In the optimized double-bolt connectors, a steel cushion plate was added between the short bolt and the sleeve, so that the shear plane was located in the unthreaded region of the short bolt shank. This increases the effective shear area and therefore improves the shear capacity of the connectors. The introduction of the steel cushion plate causes a large bending deformation of the short bolt shank during shear loading, which markedly enhances the ductility of the connectors but also leads to a reduction in their shear stiffness. The proposed calculation methods for the shear capacity and shear stiffness can provide theoretical reference for the application of double-bolt connectors in steel-concrete composite structures.
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图 2 推出试件尺寸及构造(单位:mm)
Figure 2. Dimensions and configurations of push-out specimens (unit: mm)
图 11 螺栓抗剪承载力预测值与试验值比值
Figure 11. Ratio of the predicted to experimental bolt shear capacity
表 1 推出试验分组
Table 1. Grouping of push-out tests
试件编号 螺栓直径/mm 垫板 预紧力 预紧力量值/kN M16-P-T 16 有 有 100 M20-P-T 20 有 有 155 M20-P-O 有 无 M20-N-T 无 有 155 M20-N-O 无 无 M24-P-T 24 有 有 225 M24-P-O 有 无 M24-N-T 无 有 225 M24-N-O 无 无 
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表 2 钢混组合梁可拆卸螺栓连接件抗剪承载力比较
Table 2. Comparison of the shear bearing capacity of demountable bolt connectors for steel-concrete composite beams
来源 试件编号 螺栓直径/mm 螺栓等级 试验值Qt/kN 预测值Qp/kN Qp/Qt 本文 M16-P-T 16 10.9级 168.6 160.8 0.95 M20-P-O 20 268.2 251.2 1.07 M20-P-T 259.5 1.03 M20-N-O 221.8 188.4 1.18 M20-N-T 205.0 1.09 M24-P-O 24 382.7 361.7 1.06 M24-P-T 376.8 1.04 M24-N-O 280.2 271.3 1.03 M24-N-T 276.9 1.02 文献[9] DBLNB-05ST 22 ASTM A193 B7 195.0 196.1 0.99 DBLNB-06ST 176.0 0.90 DBLNB-07ST 180.0 0.92 HTFGB-05ST ASTM A325 246.0 252.3 0.98 HTFGB-06ST 225.0 0.89 HASAA-05ST ASTM A193 B7 165.0 196.1 0.84 HASAA-06ST 154.0 0.79 HASAA-07ST 164.0 0.84 文献[16] BT1 16 8.8级 90.1 96.5 0.93 BT2 87.8 0.91 BT3 87.9 0.91 BT4 92.7 0.96 文献[18] BT7-1 16 8.8级 100.7 102.5 0.98 BT7-2 104.1 1.00 BT7-3 100.0 0.98 BT8-1 10.9级 109.3 129.0 0.85 BT8-2 109.2 0.85 BT8-3 105.1 0.82 文献[21] TIBC12-1 12 8.8级 45.9 58.4 0.79 TIBC12-2 48.6 0.83 TIBC12-3 49.9 0.85 TIBC16-1 16 82.3 105.6 0.78 TIBC16-2 83.4 0.79 TIBC16-3 81.0 0.77 文献[22] B1 18 8.8级 165.6 157.1 1.05 B2 174.5 1.11 B3 22 256.8 224.7 1.14 B4 213.8 0.95 B5 27 347.1 283.3 1.23 B6 345.8 1.22
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表 3 拟合系数取值
Table 3. Values of fitting coefficient
试件编号 拟合系数 c1 c2 M20-P-O 0.007 0.003 M20-N-O 0.013 0.001 M24-P-O 0.011 0.004 M24-N-O 0.019 0.003
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