吉林大学学报(工学版) ›› 2025, Vol. 55 ›› Issue (1): 198-210.doi: 10.13229/j.cnki.jdxbgxb.20230282

• 交通运输工程·土木工程 • 上一篇    

砖砌体墙后嵌钢筋-嵌缝砂浆界面黏结强度规律

刘廷滨(),黄滔,王作伟,欧嘉祥,韩雨   

  1. 兰州交通大学 土木工程学院,兰州 730070
  • 收稿日期:2023-03-29 出版日期:2025-01-01 发布日期:2025-03-28
  • 作者简介:刘廷滨(1981-),男,副教授,博士.研究方向:工程结构加固,混凝土耐久性.E-mail:liutingbin@mail.lzjtu.cn
  • 基金资助:
    中央引导地方科技发展资金项目(22ZY1QA005)

Interfacial bond strength between post-embedded reinforcement and caulking mortar in brick masonry wall

Ting-bin LIU(),Tao HUANG,Zuo-wei WANG,Jia-xiang OU,Yu HAN   

  1. School of Civil Engineering,Lanzhou Jiaotong University,Lanzhou 730070,China
  • Received:2023-03-29 Online:2025-01-01 Published:2025-03-28

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摘要:

后嵌钢筋-嵌缝砂浆界面黏结强度是影响无筋砌体抗震加固效果的重要因素。本研究制作了33个砖砌体试件,选用光圆钢筋、变形钢筋和不同强度的水泥砂浆对试件进行嵌缝加固处理,采用自行研发的黏结性能测试装置进行拉拔试验,通过对试件的黏结破坏模式、黏结滑移曲线特征和黏结强度进行分析,得出嵌缝砂浆强度、钢筋直径、黏结长度和钢筋类型等因素对黏结强度的影响规律,建立考虑各因素影响效应的极限黏结强度预测公式,并且从能量角度对黏结强度进行分析。试验结果表明:嵌缝砂浆强度、黏结长度和钢筋类型等对黏结强度均有明显影响,而钢筋直径的变化对黏结强度的影响较小;其他条件相同时,变形钢筋的黏结强度普遍高于光圆钢筋,并且钢筋的黏结强度随嵌缝砂浆强度等级的提高、黏结长度的降低而增大;界面黏结破坏能随嵌缝砂浆强度的变化规律与试验数据规律吻合。研究结果可为嵌筋加固的推广应用提供理论指导。

关键词: 砖砌体结构, 嵌筋加固, 嵌缝砂浆, 拉拔试验, 黏结性能, 黏结强度

Abstract:

The bond strength at the interface between post-embedded reinforcement and caulking mortar is a crucial factor in determining the seismic strengthening efficacy of unreinforced masonry. To investigate this, 33 brick masonry specimens were constructed and reinforced with plain and deformed steel rebars, as well as cement mortar of various strengths. The bond performance of the strengthened specimens was investigated by means of a self-developed pull-out testing device. By analyzing the bond failure mode, bond slip curve characteristics, and bond strength, the bond behavior influencing by the likely impact of factors such as caulking mortar strength, reinforcement diameter, bond length, and reinforcement type on bond strength was evaluated, and a predicting formula of the ultimate bond strength considering various influencing factors was proposed while the predicted bond strength is also analyzed in an energy perspective. The test results showed that the strength of caulking mortar, bond length, and reinforcement type have significantly impact on the bond strength, while changes in reinforcement diameter have little effect. Specifically, the bond strength of deformed rebars has generally higher effect than that of the plain rebars under the same conditions. The bond strength of reinforcement increases with the strength grade of caulking mortar and decreases as the bond length increases. The rule of thumb for the variation of interfacial bond failure energy with the strength of the embedded mortar is consistent with the test data.The research findings provide important theoretical guidance for the wider use and application of embedded reinforcement.

Key words: brick masonry structure, embedded reinforcement, caulking mortar, pull-out test bord performance, bond strength

中图分类号: 

  • TU362

图1

砖砌体拉拔试件详图"

表1

试件参数设计表"

序号钢筋类型钢筋直径/mm嵌缝砂浆强度/MPa黏结长度/mm试件数
1光圆钢筋853703
2光圆钢筋8103703
3光圆钢筋8153703
4光圆钢筋8203703
5光圆钢筋8152403
6光圆钢筋6103703
7变形钢筋853703
8变形钢筋8103703
9变形钢筋8153703
10变形钢筋8203703
11变形钢筋8152403

表2

水泥物理力学性能指标"

等级细度/%

凝结时间

/min

体积安定性

抗折强度

/MPa

抗压强度

/MPa

初凝终凝3 d28 d3 d28 d
P.O.32.55101425满足要求481842

表3

河沙物理力学性能指标"

类别细度模量含泥量/%表观密度/(kg·m-3松散堆积密度/(kg·m-3
河沙2.41.92 7601 600

表4

砂浆力学性能指标"

砂浆类型砌筑砂浆嵌缝砂浆
设计抗压强度等级/MPaM 5M 5M 10M 15M 20
测试抗压强度/MPa6.56.811.915.819.6

表5

砖物理力学性能指标"

试件尺寸(l×b×h

/mm×mm×mm

体积密度/(kg·m-3抗折强度/MPa抗压强度/MPa
240×115×531 7205.6512.30

表6

钢筋物理力学性能指标"

指标直径/mm屈服强度/MPa伸长率/%弹性模量/GPa抗拉强度/MPa
HPB3006374.836200549.5
8361.732200540.2
HRB3358402.316200592.4

图2

试验加载装置"

表7

试件拉拔试验结果"

试件编号Pu/kNτuSu破坏模式
Eu/MPaAVG/MPa?Ep/mmAVG/mm?
P8-370-M5110.801.081.020.050.600.570.04拔出
29.000.970.55拔出
310.401.020.55拔出
P8-370-M10113.501.451.360.060.990.740.31拔出
212.001.290.71拔出
312.501.350.53拔出
P8-370-M15114.501.561.610.541.011.200.15拔出
215.901.711.23拔出
314.501.561.35拔出
P8-370-M20117.001.801.870.102.242.320.07拔出
216.201.742.22拔出
319.302.082.50拔出
P8-240-M15111.501.911.960.050.830.730.14拔出
211.501.910.63拔出
312.502.070.73拔出
P6-370-M1019.401.341.350.030.930.740.25拔出
29.701.390.74拔出
39.101.310.55拔出
R8-370-M5116.601.791.740.332.872.690.08破裂
215.601.682.77劈裂
316.401.772.44劈裂
R8-370-M10119.002.042.080.033.613.310.09劈裂
219.002.042.99劈裂
320.002.153.34劈裂
R8-370-M15121.502.312.330.084.785.140.07劈裂
220.002.155.18劈裂
323.502.535.46劈裂
R8-370-M20122.602.432.590.063.612.960.22劈裂
224.402.632.99劈裂
325.302.722.28劈裂
R8-240-M15115.002.492.600.201.151.330.19劈裂
219.003.151.22劈裂
313.002.161.61劈裂

图3

拔出破坏试件形态"

图4

劈裂破坏试件形态"

图5

后嵌变形钢筋-嵌缝砂浆黏结机理"

图6

不同因素对后嵌钢筋-嵌缝砂浆τ-s曲线的影响"

图7

后嵌钢筋-嵌缝砂浆典型τ-s曲线"

图8

砂浆强度对后嵌钢筋-嵌缝砂浆界面黏结强度的影响"

图9

钢筋直径对后嵌钢筋-嵌缝砂浆界面黏结强度的影响"

图10

黏结长度对后嵌钢筋-嵌缝砂浆界面黏结强度的影响"

图11

钢筋类型对后嵌钢筋-嵌缝砂浆界面黏结强度的影响"

图12

极限黏结强度与峰值滑移之间的关系"

图13

实测极限黏结强度与公式计算值对比"

图14

试件破坏能示意图"

图15

砂浆强度对破坏能的影响"

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