常规武器二次爆炸作用下浅埋钢筋混凝土拱结构破坏规律

陈昊 卢浩 孙善政 熊自明 岳松林 王德荣

陈昊, 卢浩, 孙善政, 熊自明, 岳松林, 王德荣. 常规武器二次爆炸作用下浅埋钢筋混凝土拱结构破坏规律[J]. 爆炸与冲击, 2023, 43(8): 085104. doi: 10.11883/bzycj-2022-0260
引用本文: 陈昊, 卢浩, 孙善政, 熊自明, 岳松林, 王德荣. 常规武器二次爆炸作用下浅埋钢筋混凝土拱结构破坏规律[J]. 爆炸与冲击, 2023, 43(8): 085104. doi: 10.11883/bzycj-2022-0260
CHEN Hao, LU Hao, SUN Shanzheng, XIONG Ziming, YUE Songlin, WANG Derong. Failure law of shallow buried reinforced concrete arch structure under secondary explosion of conventional weapons[J]. Explosion And Shock Waves, 2023, 43(8): 085104. doi: 10.11883/bzycj-2022-0260
Citation: CHEN Hao, LU Hao, SUN Shanzheng, XIONG Ziming, YUE Songlin, WANG Derong. Failure law of shallow buried reinforced concrete arch structure under secondary explosion of conventional weapons[J]. Explosion And Shock Waves, 2023, 43(8): 085104. doi: 10.11883/bzycj-2022-0260

常规武器二次爆炸作用下浅埋钢筋混凝土拱结构破坏规律

doi: 10.11883/bzycj-2022-0260
基金项目: 国家自然科学基金(51808552)
详细信息
    作者简介:

    陈 昊(1998- ),男,博士研究生,1084456589@qq.com

    通讯作者:

    卢 浩(1987- ),男,博士,副教授,lh829829@163.com

  • 中图分类号: O383

Failure law of shallow buried reinforced concrete arch structure under secondary explosion of conventional weapons

  • 摘要: 为研究常规武器二次爆炸作用下土中浅埋拱结构的破坏规律,对土中浅埋钢筋混凝土直墙拱结构进行爆炸试验和数值模拟。试验对结构模型设置多个缩比工况,同时,利用LS-DYNA对3组工况进行数值模拟。通过对比土中测点压力、结构测点速度和结构挠度等数据,发现模拟结果与试验结果基本一致并拓展了二次爆炸的数值模拟工况。结果表明:比例爆距设置在0.4~0.6 m/kg1/3,以保证结构以整体破坏为主。综合结构毁伤宏观描述和结构最大挠跨比,对整体作用下结构的毁伤等级进行划分。通过讨论结构的初始毁伤及不同爆炸顺序时钢筋混凝土直墙拱结构的破坏规律,结构受爆炸作用发生开裂、弯曲等破坏时,部分混凝土因开裂或进入塑性而退出工作,从而导致结构的刚度发生改变;结构最终毁伤程度受打击顺序影响,初次爆炸对结构最终损伤影响比重较大。
  • 图  1  直墙拱模型尺寸及钢筋布置(单位: mm)

    Figure  1.  Size of structure and layout of steel bars (unit: mm)

    图  2  直墙拱模型现场

    Figure  2.  Straight wall arch model site

    图  3  装药及采集手段布置

    Figure  3.  Layout of charge and acquisition means

    图  4  试验开展流程

    Figure  4.  Test development process

    图  5  模型结构特征毁伤形态

    Figure  5.  Damage forms of model structural characteristics

    图  6  几种典型混凝土拱结构破坏模式

    Figure  6.  Several typical failure modes of concrete arch structure

    图  7  有限元模型及材料示意图

    Figure  7.  Finite element model and material description

    图  8  数值模拟与试验的结构破坏形态对比

    Figure  8.  Comparison of structural failure modes in numerical simulation and test

    图  9  测量点布置示意图(单位:mm)

    Figure  9.  Mapping of measuring points (unit: mm)

    图  10  数值模拟与试验的测点压力、速度时程曲线对比

    Figure  10.  Comparison of pressure and velocity time-history curves at measuring points between simulation and test

    图  11  数值模拟毁伤等级划分示意

    Figure  11.  Numerical simulation of damage grade division

    图  12  二次打击工况结构的初始损伤特征

    Figure  12.  Initial damage characteristics of structures under secondary explosion

    表  1  试验工况设置

    Table  1.   Setting of test conditions

    工况爆炸距离/m装药当量/kg比例爆距/(m∙kg−1/3
    T1-01.05.00.585
    T1-10.85.00.468
    T2-00.85.00.468
    T2-10.87.50.409
    T3-00.87.50.409
    T3-10.87.50.409
    下载: 导出CSV

    表  2  混凝土RHT材料关键参数[18]

    Table  2.   Key parameters of concrete RHT material[18]

    密度/
    (kg∙m−3
    杨氏模量/
    GPa
    剪切模量/
    GPa
    抗压强度/
    MPa
    最小残余
    损伤应变
    244032.516.7400.01
    下载: 导出CSV

    表  3  TNT材料关键参数

    Table  3.   Key parameters of TNT material

    密度/( kg∙m−3)爆速/(m∙s−1)pCJ/GPaE0/GPaR1R2ωA/GPaB/GPa
    1600630028.574.150.950.337303.75
    下载: 导出CSV

    表  4  数值模拟初次打击局部震塌计算

    Table  4.   Numerical simulation of local collapse in initial shock

    试验工况
    (距离-当量)
    震塌系数KZ毁伤描述
    S1-01.0 m-5.0 kg0.371无明显震塌现象
    S2-00.8 m-5.0 kg0.319小范围内混凝土脱落
    S3-01.0 m-7.5 kg0.330小范围内混凝土脱落
    S4-00.8 m-7.5 kg0.284较大范围的混凝土层裂
    下载: 导出CSV

    表  5  初次打击数值模拟计算结果

    Table  5.   Numerical simulation results of initial explosion

    试验工况
    (距离-当量)
    自振周期/ms刚度比挠跨比/%毁伤程度
    S1-01.0 m-5.0 kg6.030.9900.395轻度毁伤
    S2-00.8 m-5.0 kg7.000.7350.772中度毁伤
    S3-01.0 m-7.5 kg6.950.7450.797中度毁伤
    S4-00.8 m-7.5 kg7.240.6871.729中度毁伤
    下载: 导出CSV

    表  6  二次打击数值模拟计算

    Table  6.   Numerical simulation of secondary explosion

    试验工况(距离-当量)拱顶挠度/mm挠跨比/%累积挠度/mm累积挠跨比/%毁伤等级
    S1-11.0 m-7.5 kg7.940.82711.7351.222中度毁伤
    S1-20.8 m-5.0 kg7.900.82311.6951.218中度毁伤
    S1-31.0 m-5.0 kg4.700.4908.4950.885中度毁伤
    S2-11.0 m-5.0 kg5.060.52712.4701.299中度毁伤
    S2-20.8 m-7.5 kg17.201.79224.6102.564重度毁伤
    S2-30.8 m-5.0 kg8.530.87015.7601.642中度毁伤
    S3-11.0 m-5.0 kg4.970.51812.6201.315中度毁伤
    S3-20.8 m-7.5 kg17.201.79224.8502.589重度毁伤
    S3-31.0 m-7.5 kg8.090.84315.7401.640中度毁伤
    S4-10.8 m-5.0 kg22.502.34439.1004.073重度毁伤
    S4-21.0 m-7.5 kg14.301.49030.9003.219重度毁伤
    S4-30.8 m-7.5 kg重度毁伤
    下载: 导出CSV

    表  7  相同工况下不同初始毁伤结构响应对比

    Table  7.   Responses of different initial damaged structures under the same conditions

    试验工况
    (距离-当量)
    初始刚度比初始毁伤程度挠跨比/%
    S2-00.8 m-5.0 kg1.000无毁伤0.772
    S1-20.8 m-5.0 kg0.990轻度毁伤0.823
    S2-30.8 m-5.0 kg0.735中度毁伤0.870
    S4-10.8 m-5.0 kg0.687中度毁伤2.344
    下载: 导出CSV

    表  8  不同起爆次序下结构响应对比

    Table  8.   Structural response under different initiation sequence

    试验工况顺序(距离-当量)累积挠跨比/%
    S2-2先0.8 m-5.0 kg,后0.8 m-7.5 kg2.564
    S4-1先0.8 m-7.5 kg,后0.8 m-5.0 kg4.073
    下载: 导出CSV
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出版历程
  • 收稿日期:  2022-06-15
  • 修回日期:  2022-09-14
  • 网络出版日期:  2022-10-13
  • 刊出日期:  2023-08-31

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