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疲劳荷载和冻融循环耦合作用下路面混凝土微裂缝扩展行为

郭寅川 申爱琴 何天钦 周胜波

郭寅川, 申爱琴, 何天钦, 周胜波. 疲劳荷载和冻融循环耦合作用下路面混凝土微裂缝扩展行为[J]. 交通运输工程学报, 2016, 16(5): 1-9. doi: 10.19818/j.cnki.1671-1637.2016.05.001
引用本文: 郭寅川, 申爱琴, 何天钦, 周胜波. 疲劳荷载和冻融循环耦合作用下路面混凝土微裂缝扩展行为[J]. 交通运输工程学报, 2016, 16(5): 1-9. doi: 10.19818/j.cnki.1671-1637.2016.05.001
GUO Yin-chuan, SHEN Ai-qin, HE Tian-qin, ZHOU Sheng-bo. Micro-crack propagation behavior of pavement concrete subjected to coupling effect of fatigue load and freezing-thawing cycles[J]. Journal of Traffic and Transportation Engineering, 2016, 16(5): 1-9. doi: 10.19818/j.cnki.1671-1637.2016.05.001
Citation: GUO Yin-chuan, SHEN Ai-qin, HE Tian-qin, ZHOU Sheng-bo. Micro-crack propagation behavior of pavement concrete subjected to coupling effect of fatigue load and freezing-thawing cycles[J]. Journal of Traffic and Transportation Engineering, 2016, 16(5): 1-9. doi: 10.19818/j.cnki.1671-1637.2016.05.001

疲劳荷载和冻融循环耦合作用下路面混凝土微裂缝扩展行为

doi: 10.19818/j.cnki.1671-1637.2016.05.001
基金项目: 

国家自然科学基金项目 51278059

详细信息
    作者简介:

    郭寅川(1983-), 男, 江西九江人, 长安大学副教授, 工学博士, 从事路面材料研究

  • 中图分类号: U416.216

Micro-crack propagation behavior of pavement concrete subjected to coupling effect of fatigue load and freezing-thawing cycles

More Information
    Author Bio:

    GUO Yin-chuan(1983-), male, associate professor, PhD, +86-29-82336305, silver007007@163.com

  • 摘要: 为了定量表征与分析在疲劳荷载和冻融循环耦合作用下路面混凝土内部裂缝的演化规律, 采用SEM与形态学图像分割法对不同疲劳荷载和冻融循环耦合阶段的混凝土微裂缝进行提取, 采用Image-Pro Plus对微裂缝进行量化, 采用灰色关联法研究了裂缝特征参数与耦合作用后路面混凝土弯拉强度损失的相关性。分析结果表明: 路面混凝土内部存在平均宽度为13μm、最大长度为144μm的原始微裂缝, 耦合作用下裂缝的演化沿长度方向为延伸和断裂交替变化, 沿宽度方向为扩张和收缩交替变化, 混凝土破坏时裂缝最大长度达到352.64μm, 裂缝平均宽度达到15.4μm; 当冻融循环150次时, 裂缝面积密度显著增大, 与原始微裂缝相比, 混凝土破坏时裂缝面积密度增大了6.7倍; 耦合作用下路面混凝土裂缝分形维数、平均宽度、最大长度与弯拉强度的相关性较高, 灰色关联度分别为0.957、0.954、0.871;通过回归分析建立了路面混凝土弯拉强度损失与裂缝结构参数之间的方程, 弯拉强度损失与裂缝分形维数、平均宽度、最大长度之间存在较好的线性相关性, 相关系数达到0.97。

     

  • 图  1  疲劳加载试验

    Figure  1.  Fatigue loading test

    图  2  冻融循环试验

    Figure  2.  Freezing-thawing cycle test

    图  3  裂缝结构取样位置

    Figure  3.  Sampling locations of crack structure

    图  4  微裂缝图像处理方法

    Figure  4.  Micro-crack image processing method

    图  5  位置A处分割前后SEM图像对比

    Figure  5.  SEM image comparison before and after segment at location A

    图  6  位置B处分割前后SEM图像对比

    Figure  6.  SEM image comparison before and after segment at location B

    图  7  位置C处分割前后SEM图像对比

    Figure  7.  SEM image comparison before and after segment at location C

    图  8  裂缝面积密度

    Figure  8.  Crack area densities

    图  9  最大裂缝长度

    Figure  9.  Maximum crack lengths

    图  10  平均裂缝宽度

    Figure  10.  Average crack widths

    图  11  裂缝分形维数

    Figure  11.  Crack fractal dimensions

    图  12  耦合Ⅳ阶段的裂缝SEM图像

    Figure  12.  Crack SEM images at coupling stageⅣ

    图  13  弯拉强度

    Figure  13.  Flexural strengths

    图  14  孔隙率

    Figure  14.  Porosity factors

    表  1  路面混凝土配合比设计

    Table  1.   Composition design of pavement concrete

    下载: 导出CSV

    表  2  路面混凝土性能测试结果

    Table  2.   Test result of pavement concrete performance

    下载: 导出CSV

    表  3  耦合试验设计方案

    Table  3.   Design plans of coupling experiment

    下载: 导出CSV

    表  4  弯拉强度与裂缝特征参数的灰相关度

    Table  4.   Grey relational degrees of flexural strengths and crack character parameters

    下载: 导出CSV
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  • 收稿日期:  2016-06-22
  • 刊出日期:  2016-10-25

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