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桥梁用Q345钢高温蠕变-疲劳时序耦合性能试验

辛灏辉 黄旭 赵乾宇 刘高 倪雅 殷如阳

辛灏辉, 黄旭, 赵乾宇, 刘高, 倪雅, 殷如阳. 桥梁用Q345钢高温蠕变-疲劳时序耦合性能试验[J]. 交通运输工程学报, 2026, 26(6): 104-114. doi: 10.19818/j.cnki.1671-1637.2026.314
引用本文: 辛灏辉, 黄旭, 赵乾宇, 刘高, 倪雅, 殷如阳. 桥梁用Q345钢高温蠕变-疲劳时序耦合性能试验[J]. 交通运输工程学报, 2026, 26(6): 104-114. doi: 10.19818/j.cnki.1671-1637.2026.314
XIN Hao-hui, HUANG Xu, ZHAO Qian-yu, LIU Gao, NI Ya, YIN Ru-yang. Experimental study on high-temperature creep-fatigue sequential coupling performance of Q345 steel for bridge[J]. Journal of Traffic and Transportation Engineering, 2026, 26(6): 104-114. doi: 10.19818/j.cnki.1671-1637.2026.314
Citation: XIN Hao-hui, HUANG Xu, ZHAO Qian-yu, LIU Gao, NI Ya, YIN Ru-yang. Experimental study on high-temperature creep-fatigue sequential coupling performance of Q345 steel for bridge[J]. Journal of Traffic and Transportation Engineering, 2026, 26(6): 104-114. doi: 10.19818/j.cnki.1671-1637.2026.314

桥梁用Q345钢高温蠕变-疲劳时序耦合性能试验

doi: 10.19818/j.cnki.1671-1637.2026.314
基金项目: 

国家自然科学基金项目 52578177

国家自然科学基金重大项目 52595691

国家重点研发计划 2024YFB2605700

详细信息
    作者简介:

    辛灏辉(1991-),男,甘肃陇南人,教授,博士生导师,工学博士,E-mail: xinhaohui@seu.edu.cn

    通讯作者:

    刘高(1970-),男,河北唐山人,教授,博士生导师,工学博士,E-mail: liugao77@seu.edu.cn

  • 中图分类号: U441.4

Experimental study on high-temperature creep-fatigue sequential coupling performance of Q345 steel for bridge

Funds: 

National Natural Science Foundation of China 52578177

Major Program of National Natural Science Foundation of China 52595691

National Key R&D Program of China 2024YFB2605700

More Information
Article Text (Baidu Translation)
  • 摘要: 针对火灾后桥梁钢结构疲劳性能评估的实际需求,以桥梁工程广泛应用的Q345低碳合金钢为研究对象,设计了4类7组共15个圆棒标准狗骨状试件,系统探究了持力状态下不同蠕变损伤时间对钢材冷却后残余变形及疲劳性能的影响规律。研究结果表明:随着高温蠕变时间由0增加至0.7倍蠕变断裂时间,高温蠕变-疲劳时序耦合试件的平均疲劳寿命减少,从32.2万次降低至11.5万次,降低了64.4%;高温蠕变-疲劳耦合作用使断口转为杯锥状并缩小疲劳扩展区,这主要源于氧化脱碳与蠕变损伤导致的材料承载能力下降,从而加速了疲劳破坏;不同高温蠕变时间对试件的疲劳动态弹性模量影响较小,弹性模量软化比接近1.0,初始动态弹性模量最大仅减少了8.7%;临界累积塑性应变随着蠕变时间增加而显著降低,最大降幅达55.6%,而塑性应变累积速率基本不变。随着蠕变时间的增加,高温蠕变损伤降低了时序疲劳的累积塑性变形容限,使材料在更小的塑性应变水平下加速软化与失效。本研究可为火灾受损桥梁钢结构的疲劳性能评估与剩余寿命预测提供试验依据与理论参考。

     

  • 图  1  试件几何构造与尺寸(单位:mm)

    Figure  1.  Specimen geometry and dimensions (unit: mm)

    图  2  试验加载、测量仪器与破坏形态

    Figure  2.  Test loading, measuring instrument and failure mode

    图  3  基本力学性能试验曲线

    Figure  3.  Basic mechanical properties test curves

    图  4  高温蠕变-疲劳时序耦合试验流程

    Figure  4.  High-temperature creep-fatigue sequential coupling test process

    图  5  高温蠕变-疲劳时序耦合试验系统和测点布置

    Figure  5.  System and measurement points layout of high-temperature creep-fatigue sequential coupling test

    图  6  高温蠕变-疲劳时序耦合试件破坏模式

    Figure  6.  Failure pattern of high-temperature creep-fatigue sequential coupling specimens

    图  7  高温蠕变-疲劳时序耦合试件冷却残余变形

    Figure  7.  Cooling residual deformation of high-temperature creep-fatigue sequential coupling specimens

    图  8  动态模量退化与指标

    Figure  8.  Cyclic stiffness degradation and indicators

    图  9  应变幅值指标变化

    Figure  9.  Strain amplitude response and indicator change

    图  10  累积塑性应变响应

    Figure  10.  Cumulative plastic strain response

    表  1  Q345低碳合金钢主要化学成分质量分数和碳当量

    Table  1.   Mass fraction of main chemical elements and CEV in Q345 low-carbon alloy steel

    化学成分质量分数/% C Si Mn P S Ni Als Cr Cu CEV
    0.160 0.330 1.480 0.015 0.006 0.010 0.032 0.060 0.020 0.420
    下载: 导出CSV

    表  2  基本力学性能试验结果

    Table  2.   Test results for basic mechanical properties

    试件编号 力学性能 试件编号 高温蠕变性能 试件编号 疲劳性能
    屈服强度/MPa 极限强度/MPa 弹性模量/MPa 蠕变断裂时间/s 疲劳寿命/次
    JZ-1 346.27 516.83 213 636 RB-1 1 769.52 PL-1 169 872
    JZ-2 344.37 507.09 213 840 RB-2 1 544.02 PL-2 138 340
    平均值 345.32 511.96 213 738 平均值 1 656.77 PL-3 196 686
    平均值 168 299
    下载: 导出CSV

    表  3  时序耦合试验类型与参数设计

    Table  3.   Sequential coupling test categories and parameter design

    试件编号 疲劳上限/MPa 疲劳应力比 疲劳频率/Hz 蠕变持荷应力/MPa 蠕变时间 试件数量/个
    OH-0 460 0.1 10 144.9 0tR 2
    OH-0.1 0.1tR 2
    OH-0.4 0.4tR 2
    OH-0.7 0.7tR 2
    下载: 导出CSV

    表  4  试验主要结果

    Table  4.   Results of the test

    试件编号 δ/mm εa(0.5Nf)/10-2 EN(0.5Nf)/MPa Rε RE Ni/次 Nf/次
    PL(平均) - 0.235 0 177 981.09 1.012 9 0.988 9 167 440 168 299
    OH-0-1 0.059 1 0.222 4 179 908.33 1.008 0 0.988 0 311 000 318 323
    OH-0-2 0.066 6 0.221 6 180 466.93 1.003 4 0.991 2 318 200 325 020
    OH-0.1-1 0.223 4 0.244 3 167 939.90 1.005 5 0.983 5 241 700 243 420
    OH-0.1-2 0.213 1 0.244 8 167 525.80 1.007 2 0.979 0 267 900 269 674
    OH-0.4-1 1.104 6 0.245 2 164 004.21 1.007 2 0.993 9 185 800 191 472
    OH-0.4-2 1.153 1 0.245 6 165 925.84 1.009 9 0.985 8 175 154 175 766
    OH-0.7-1 2.274 6 0.230 4 165 963.38 1.010 1 0.998 0 129 500 134 066
    OH-0.7-2 2.714 8 0.231 3 164 081.33 1.015 6 0.987 2 91 800 95 166
    下载: 导出CSV
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出版历程
  • 收稿日期:  2026-01-05
  • 录用日期:  2026-05-27
  • 修回日期:  2026-02-27
  • 刊出日期:  2026-06-28

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