吉林大学学报(工学版) ›› 2025, Vol. 55 ›› Issue (12): 3928-3941.doi: 10.13229/j.cnki.jdxbgxb.20240450

• 交通运输工程·土木工程 • 上一篇    

装配式桥墩UHPC湿接缝的剪切强度计算方法

周敉1(),田兴旺1,朱国强1,马雷2   

  1. 1.长安大学 旧桥检测与加固技术交通行业重点实验室,西安 710064
    2.中交第二公路工程局有限公司,西安 710064
  • 收稿日期:2024-04-06 出版日期:2025-12-01 发布日期:2026-02-03
  • 作者简介:周敉(1977-),男,教授,博士.研究方向:桥梁工程的抗震.E-mail:zhoumi@chd.edu.cn
  • 基金资助:
    国家自然科学基金项目(51978062);陕西省重点研发计划项目(2024SF-YBXM-644);山西省交通科技项目(2021-02-03);陕西省交通科研项目(22-05K)

Direct shear strength of UHPC wet joints in precast piers

Mi ZHOU1(),Xing-wang TIAN1,Guo-qiang ZHU1,Lei MA2   

  1. 1.Key Laboratory for Old Bridge Detection and Reinforcement Technology of the Ministry of Transportation,Chang'an University,Xi'an 710064,China
    2.CCCC Second Highway Engineering Co. ,Ltd. ,Xi'an 710064,China
  • Received:2024-04-06 Online:2025-12-01 Published:2026-02-03

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摘要:

针对超高性能混凝土(UHPC)平湿接缝及键齿湿接缝直剪承载力的计算方法进行了研究,结合UHPC湿接缝的构造及受力特点,提出了包括界面黏聚力、摩擦力、键齿骨料黏结力及纤维贡献等关键项的UHPC湿接缝直剪强度模型。基于已有接缝试件直剪推出试验结果和有限元模拟结果,经过线性回归分析,确定界面黏结应力系数及摩擦因数,通过对键齿骨料粘结力的推导和针对纤维贡献项的探讨,给出了UHPC湿接缝的抗剪承载力计算公式。总结9种已有的UHPC湿接缝抗剪承载力计算公式,将本文建议的直剪承载力计算模型、已有9种公式的预测承载力与试验值对比验证。结果表明:随着侧向约束应力的增加,平接缝的破坏荷载呈现非线性关系;本文公式与试验值比值的平均值为1.04,与已有的9种公式相比更接近于1,由此可见,本文公式的预测精度优于已有公式;通过不同试验对UHPC湿接缝的抗剪承载力计算方法进行验证,本文提出的直剪承载力计算方法的预测值与试验值吻合较好,从而证明了计算方法的普适性,并且可为UHPC键齿湿接缝界面的直剪承载力预测提供参考。

关键词: 桥梁工程, 超高性能混凝土, 湿接缝, 键齿, 直剪承载力

Abstract:

The calculation methods for the direct shear carrying capacity of Ultra-High-Performance Concrete (UHPC) flat wet joints and keyed wet joints are investigated. By considering the construction and force-bearing characteristics of UHPC wet joints, a direct shear strength model for UHPC wet joints is proposed, which incorporates key factors such as interfacial cohesion, frictional resistance, aggregate interlock strength of keys, and fiber reinforcement contribution. Based on the results of direct shear tests on joint specimens and finite element simulation, linear regression analysis is conducted to determine the interfacial bond stress coefficient and friction coefficient. Through the derivation of the aggregate interlock strength of keys and the discussion on the fiber contribution, a formula for calculating the shear carrying capacity of UHPC wet joints is presented. Nine existing formulas for calculating the shear carrying capacity of UHPC wet joints are summarized, and the proposed direct shear carrying capacity calculation model is validated by comparing the predicted carrying capacity from the nine existing formulas with experimental values. The results indicate that with the increase in lateral confinement stress, the failure load of flat joints exhibits a nonlinear relationship; the ratio of the proposed formula to the experimental values has an average of 1.04, which is closer to 1 compared to the nine existing formulas, demonstrating superior prediction accuracy of the proposed formula. The verification of different experimental approaches on the shear carrying capacity calculation method for UHPC wet joints shows that the predicted values from the proposed direct shear carrying capacity calculation model align well with experimental values, thus proving the universality of the calculation method. This method can provide a reference for predicting the direct shear carrying capacity of UHPC keyed wet joint interfaces.

Key words: bridge engineering, ultra-high-performance concrete(UHPC), wet joints, keyed teeth, direct shear capacity

中图分类号: 

  • U443

图1

键齿接缝受力状态及破坏过程"

图2

键齿单元体平面应力状态"

图3

键齿微元体摩尔应力圆"

图4

裂缝中钢纤维转角示意图"

图5

三维有限元分析模型"

图6

黏结应力-位移双线性本构模型"

表1

不同侧向约束下试验值和有限元计算结果对比"

试件编号破坏荷载/kN破坏时竖向位移/mm
试验值模拟值试验值模拟值
F-1169.00157.001.731.29
F-2334.60332.902.571.14
F-3481.70489.132.181.14
F-4646.30643.252.651.62

图7

荷载-竖向位移曲线有限元计算值与试验值比较"

表2

平接缝试件直剪有限元计算结果汇总"

约束应力

/MPa

破坏荷载

/kN

约束应力

/MPa

破坏荷载

/kN

175.0010.5433.75
1.590.9011448.20
2102.0011.5460.73
2.5126.9012489.13
3157.0013501.30
3.5171.9014513.45
4198.0015525.15
4.5220.5016540.00
5246.0017553.05
6334.6018566.10
6.5342.9019579.60
7356.8020592.20
7.5369.4521604.80
8383.1322616.95
8.5396.0023630.00
9408.0424643.25
10419.85

图8

平接缝试件抗剪承载力数据拟合"

图9

平接缝试件整体尺寸图(单位:mm)"

图10

三维有限元分析模型"

表3

黏聚力模型参数"

属性法向n切向s切向r
稳定系数0.001
K/(N·mm-31 35820 35820 358
t/MPa5.635.635.63
δ0/mm4.14e-32.77e-42.77e-4
δf /mm0.2410.2410.241

表4

试验实测值与有限元结果对比"

试件编号破坏荷载/kN破坏时竖向位移/mm
试验值模拟值试验值模拟值
F-0 MPa151.68167.720.840.79
F-1 MPa308.59334.311.331.11
F-2 MPa431.42449.391.461.20
F-3 MPa564.71575.341.531.34

图11

荷载-位移曲线:试验值与有限元结果对比图"

表5

平接缝试件直剪有限元计算结果汇总"

约束应力

/MPa

破坏荷载

/kN

约束应力

/MPa

破坏荷载

/kN

0.0167.722.0449.39
0.5257.242.3479.14
1.0334.312.6519.85
1.3364.213.0575.34
1.6409.35

图12

平接缝试件抗剪承载力数据拟合"

表6

文献[15]中的试件尺寸汇总"

试件类型接缝平整面积/mm2键齿根部面积/mm2接缝面总面积/mm2
单键齿试件30 00015 00051 213.2
三键齿试件30 00045 000138 639.6
大键齿试件30 00045 00088 713.2
30 00045 00093 541.0
30 00045 000102 811.5

表7

文献[30]中的试件尺寸汇总"

试件类型接缝平整面积/mm2键齿根部面积/mm2接缝面总面积/mm2
单键齿试件60 00015 00084 270
双键齿试件45 00030 00093 540

表8

UHPC材料强度"

材料来源立方体抗压强度/MPa轴心抗压强度/MPa
文献[15114.898.5
文献[30134.9

表9

试验值与计算结果对比"

试件编号界面阻力/kN键齿抗力/kN纤维贡献/kN预测承载力/kN试验承载力/kN误差/%
文献[15K1-6290.57182.103.005475.67468.951.43
K1-12393.77272.103.005668.87707.235.42
K1-18479.81362.103.005844.92877.233.68
K1-24565.85452.103.0051020.96956.416.75
K3-1.2176.67231.083.005413.76383.707.83
K3-2.4338.05269.013.005610.06608.500.26
K3-3568.89382.413.005954.30878.208.67
K3-12687.52571.413.0051 261.931 229.602.63
KD(50)-2.4221.82384.373.005609.20
KD(100)-2.4233.06384.373.005620.44667.707.08
KD(150)-2.4254.64384.373.005642.02
文献[30K1-6.891 160.88206.100.1231 367.101 149.0019
K2-6.581 183.91321.600.2461 505.761 329.0013

表10

已有公式计算值及试验值对比"

试件编号计算值/kN
式(28)式(29)式(30)式(31)式(32)式(33)式(34)式(35)式(36)试验
K1-0.5143.65328.73683.96425.45608.95502.31497.01307.21327.17468.95
K1-1152.36357.981225.38609.82916.23836.04681.38526.34543.89707.23
K1-1.5161.07387.231766.81794.181 223.511 146.28865.74745.47760.61877.23
K1-2169.77416.492308.23978.551 530.791 445.671 050.11964.60977.33956.41
K3-0.1407.04826.56709.28823.06786.42512.49738.02352.50418.18383.70
K3-0.2409.24842.39990.93922.88919.51788.22815.88440.78505.01608.50
K3-0.5415.84889.911835.891 222.341 318.801 452.931 049.46705.62765.50878.20
K3-1426.84969.103244.151 721.451 984.272 400.131 438.761 147.011 199.661 229.60
KD(50)-0.2409.24539.03990.93850.99735.48716.32522.06440.78505.01
KD(100)-0.2409.24568.37990.93857.94775.50723.27550.48440.78505.01667.70
KD(150)-0.2409.24624.70990.93871.29852.36736.62605.03440.78505.01
K1-6.89155.80548.06919.30631.661 077.01691.10673.00494.74514.341 149
K2-6.58284.84605.591413.38935.881 166.491 037.78733.46597.56637.021 329

表11

已有公式计算值、本文公式计算值与试验值比值对比"

试件编号计算值/试验值
本文式(28)式(29)式(30)式(31)式(32)式(33)式(34)式(35)式(36)
K1-0.51.010.310.701.460.911.301.071.060.660.70
K1-10.950.220.511.730.861.301.180.960.740.77
K1-1.50.960.180.442.010.911.391.310.990.850.87
K1-21.070.180.442.411.021.601.511.101.011.02
K3-0.11.081.062.151.852.152.051.341.920.921.09
K3-0.21.000.671.381.631.521.511.301.340.720.83
K3-0.51.090.471.012.091.391.501.651.200.800.87
K3-11.030.350.792.641.401.611.951.170.930.98
KD(100)-0.20.930.610.851.481.281.161.080.820.660.76
K1-6.891.200.140.480.800.550.940.600.590.430.45
K2-6.581.130.210.461.060.700.880.780.550.450.48
平均值1.040.400.841.741.151.391.251.060.740.80

图13

公式计算值/试验值"

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