吉林大学学报(工学版) ›› 2023, Vol. 53 ›› Issue (6): 1819-1832.doi: 10.13229/j.cnki.jdxbgxb.20230081

• 交通运输工程·土木工程 • 上一篇    

玄武岩纤维活性粉末混凝土与钢绞线粘结滑移过程声学特性表征

宫亚峰1(),吴树正1,毕海鹏1(),周冬明2,谭国金1,黄晓明3   

  1. 1.吉林大学 交通学院,长春 130022
    2.广西壮族自治区玉林公路发展中心,广西 玉林 537002
    3.东南大学 交通学院,南京 210018
  • 收稿日期:2023-01-30 出版日期:2023-06-01 发布日期:2023-07-23
  • 通讯作者: 毕海鹏 E-mail:gongyf@jlu.edu.cn;bihp@jlu.edu.cn
  • 作者简介:宫亚峰(1977-),男,教授,博士.研究方向:桥梁结构健康监测理论及应用.E-mail:gongyf@jlu.edu.cn
  • 基金资助:
    国家重点研发计划项目(2021YFB2600604);吉林省交通运输科技项目(2021-1-1);黑龙江交通运输厅重点项目(2022-1);吉林省科技发展计划项目(20230402048GH);吉林省教育厅科研项目(JJKH20211113KJ);广西玉林市科学研究与技术开发计划项目(202235115)

Acoustic characterization of bond⁃slip process between basalt fiber reactive powder concrete and steel strand

Ya-feng GONG1(),Shu-zheng WU1,Hai-peng BI1(),Dong-ming ZHOU2,Guo-jin TAN1,Xiao-ming HUANG3   

  1. 1.College of Transportation,Jilin University,Changchun 130022,China
    2.Yulin Highway Development Center of Guangxi Zhuang Autonomous Region,Yulin 537002,China
    3.School of Transportation,Southeast University,Nanjing 210018,China
  • Received:2023-01-30 Online:2023-06-01 Published:2023-07-23
  • Contact: Hai-peng BI E-mail:gongyf@jlu.edu.cn;bihp@jlu.edu.cn

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摘要:

针对预应力锚索因粘结失效而导致的高边坡失稳问题,提出将预应力锚索与高性能材料结合应用的方法以提高边坡抗灾韧性。首先,开展了预应力钢绞线与玄武岩纤维活性粉末混凝土(BFRPC)中心拉拔试验,研究了公称直径为15.2 mm的钢绞线在两种浆体材料(BFRPC、M40普通水泥砂浆)下的钢绞线粘结性能,总结其破坏形式;其次,基于声发射特征参数的分布规律,识别应力状态下钢筋混凝土材料的损伤过程;再次,通过对上升时间/振幅-平均频率(RA-AF)值进行对比,明确钢绞线-混凝土拉拔过程中的损伤模式;最后,依据Ib值识别不同应力状态下钢绞线混凝土材料裂纹发展的各个阶段。研究结果表明:3个阶段的能量、幅值变化规律与试件内部裂纹的产生、扩展等损伤过程联系紧密;通过RA-AF分析得出,剪切裂纹主要发生在界面混凝土附近,而拉伸裂纹的宏观体现为垂直于加载方向上的裂纹;Ib值波动差至0.25时可以将其视为一个预警值,以警告预应力钢绞线-混凝土材料即将发生劈裂破坏。

关键词: 岩土工程, 玄武岩纤维活性粉末混凝土, 声发射, 粘结滑移, 损伤模式分析

Abstract:

To address the problem of high slope instability due to bonding failure of prestressed anchor cables, the application of prestressed anchor cables in combination with high performance materials was proposed to improve slope resilience. Firstly, the pull-out tests of prestressed steel strands and Basalt Fiber Reactive Powder Concrete (BFRPC) were carried out in the laboratory. The bonding properties of steel strands with a nominal diameter of 15.2 mm under two slurry materials (BFRPC, M40 ordinary cement mortar) were studied, and the failure modes were summarized. Then, based on the distribution law of characteristic parameters, the damage process of reinforced concrete materials under stress state was identified. Secondly, by comparing the RA-AF values, the damage mode of steel strand-concrete during drawing process was clarified. Finally, according to the Ib-value, the stages of crack development of steel strand concrete under different stress states were identified. The results show that: the energy and amplitude law of the three stages are closely related to the damage process such as the generation and expansion of cracks inside the specimen. Through RA-AF analysis, it is concluded that shear cracks mainly occur near the interface concrete, while the macroscopic manifestation of tensile cracks is cracks perpendicular to the loading direction. When the fluctuation difference of Ib-value reaches 0.25, it can be regarded as an early warning value to warn that the prestressed steel strand-concrete material is about to split.

Key words: geotechnical engineering, basalt fiber reactive powder concrete(BFRPC), acoustic emission, bond-slip, damage analysis

中图分类号: 

  • U417.1

图1

试件各组件尺寸"

图2

试验模具"

图3

BFRPC制备流程"

表1

试件参数"

试件编号d/mm浆体类型锚固长度l/mm数量
BFRPC-115.2BFRPC1003
BFRPC-215.2BFRPC1003
BFRPC-315.2BFRPC1003
OCM-115.2OCM1003
OCM-215.2OCM1003
OCM-315.2OCM1003

图4

试验设备与测试"

图5

试件不同破坏形式"

表2

各试件粘结强度统计"

试件编号

破坏

形式

极限荷载/kN临界粘结应力τcr/MPa极限粘结应力τu/MPa
BFRPC-1-1拔出65.2910.7915.58
BFRPC-1-1拔出62.5910.2114.93
BFRPC-1-3拔出59.3210.1514.15
BFRPC-2-1拔出58.2310.9613.89
BFRPC-2-3拔出57.969.2613.83
BFRPC-2-3拔出59.209.8514.12
BFRPC-3-1拔出61.2210.6114.60
BFRPC-3-1拔出62.7310.6414.96
BFRPC-3-1拔出60.5810.1214.45
OCM-1-1拔出44.307.6110.57
OCM-1-2拔出46.527.8211.10
OCM-1-3拔出42.036.9510.03
OCM-2-1劈裂44.437.9510.60
OCM-2-2拔出45.287.1010.80
OCM-2-3拔出41.066.889.80
OCM-3-1拔出45.617.7010.88
OCM-3-2拔出45.287.6210.80
OCM-3-3拔出44.917.3110.71

图6

典型试件拉拔力-位移图"

图7

曲线分段示意图"

图8

BFRPC和OCM试件能量时程图"

图9

OCM和BFRPC试件幅值时程图"

图10

OCM和BFRPC试件RA-AF时间关系图"

图11

不同裂纹的宏观体现"

图12

OCM和BFRPC的Ib值( β =50,75,100)时程图"

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