活性粉末混凝土抗多次侵彻实验研究及数值预测

徐世烺 吴平 周飞 李庆华 曾田 蒋霄

徐世烺, 吴平, 周飞, 李庆华, 曾田, 蒋霄. 活性粉末混凝土抗多次侵彻实验研究及数值预测[J]. 爆炸与冲击, 2021, 41(6): 063301. doi: 10.11883/bzycj-2020-0165
引用本文: 徐世烺, 吴平, 周飞, 李庆华, 曾田, 蒋霄. 活性粉末混凝土抗多次侵彻实验研究及数值预测[J]. 爆炸与冲击, 2021, 41(6): 063301. doi: 10.11883/bzycj-2020-0165
XU Shilang, WU Ping, ZHOU Fei, LI Qinghua, ZENG Tian, JIANG Xiao. Experimental investigation and numerical prediction on resistance of reactive powder concrete to multiple penetration[J]. Explosion And Shock Waves, 2021, 41(6): 063301. doi: 10.11883/bzycj-2020-0165
Citation: XU Shilang, WU Ping, ZHOU Fei, LI Qinghua, ZENG Tian, JIANG Xiao. Experimental investigation and numerical prediction on resistance of reactive powder concrete to multiple penetration[J]. Explosion And Shock Waves, 2021, 41(6): 063301. doi: 10.11883/bzycj-2020-0165

活性粉末混凝土抗多次侵彻实验研究及数值预测

doi: 10.11883/bzycj-2020-0165
基金项目: 国家自然科学基金(51678522,51622811)
详细信息
    作者简介:

    徐世烺(1953- ),男,博士,教授,slxu@zju.edu.cn

    通讯作者:

    李庆华(1981- ),女,博士,教授,liqinghua@zju.edu.cn

  • 中图分类号: O383

Experimental investigation and numerical prediction on resistance of reactive powder concrete to multiple penetration

  • 摘要: 活性粉末混凝土(reactive powder concrete,RPC)具有超高的强度和优异的阻裂性能。为了研究RPC在多次冲击荷载下的损伤规律,采用25 mm口径滑膛炮对直径为600 mm、高600 mm的RPC圆柱形靶体进行了多次侵彻实验,得到了每次侵彻后靶体的破坏数据,并根据实验数据确定了Forrestal经验公式中的相关系数。基于K&C本构模型和现有RPC基本力学性能的实验数据,修正了K&C模型的强度面参数、损伤参数、状态方程参数、损伤演化模型以及应变率效应相关参数,系统地确定了RPC的K&C模型参数。采用LS-DYNA软件中的重启动功能模拟了弹体多次侵彻RPC靶体的破坏结果,模拟结果与实验结果基本一致,验证了模拟方法的有效性。对长2 200 mm、宽2 200 mm、高1 260 mm的RPC靶体抗侵彻实验进行了数值预测,得到了侵彻深度与弹速之间的关系、弹体贯穿靶体时的极限速度以及弹体侵彻过程中的峰值加速度。
  • 图  1  弹体尺寸

    Figure  1.  Projectile sizes

    图  2  侵彻实验设备布置

    Figure  2.  Arrangement of penetration experiment equipments

    图  3  高速摄影机记录的弹体撞击靶体过程

    Figure  3.  Process of the projectile impacting the targetrecorded by a high-speed camera

    图  4  2%钢纤维掺量下不同强度RPC的Forrestal公式中的S*

    Figure  4.  S* in the Forrestal formula of RPC with differentcompressive strengths at 2% steel fiber content

    图  5  RPC多次侵彻实验结果

    Figure  5.  Experimental results of RPC multiple penetrations

    图  6  多次侵彻实验后的靶体剖面

    Figure  6.  Profile of targets after multiple penetration experiments

    图  7  有限元模型

    Figure  7.  Finite element model

    图  8  混凝土和RPC三轴围压实验数据

    Figure  8.  Triaxial confining pressure experimental data of concrete and RPC

    图  9  拉伸和压缩应力应变曲线

    Figure  9.  Tensile and compressive stress-strain curves

    图  10  不同b3值对应的三轴拉伸应力应变曲线

    Figure  10.  Triaxial tension strain stress curvescorresponding to different b3 values

    图  11  状态方程

    Figure  11.  State equation

    图  12  第1次侵彻RPC靶体的模拟结果

    Figure  12.  Simulation results of the first penetration of the RPC target

    图  13  第2次侵彻RPC靶体的模拟结果

    Figure  13.  Simulation results of the second penetration of the RPC target

    图  14  第3次侵彻RPC靶体的模拟结果

    Figure  14.  Simulation results of the third penetration of the RPC target

    图  15  弹体与钢筋分布示意图(单位:mm)

    Figure  15.  Schematic diagram of the distribution of projectiles and reinforcement (unit: mm)

    图  16  有限元模型

    Figure  16.  Finite element model

    图  17  850 m/s弹速下的侵彻结果

    Figure  17.  Penetration results at the projectile velocity of 850 m/s

    图  18  1 150 m/s弹速下的贯穿结果

    Figure  18.  Penetration results at the projectile velocity of 1 150 m/s

    图  19  弹速与侵彻深度之间的关系

    Figure  19.  Relationship between projectile velocity and penetration depth

    表  1  RPC材料配合比

    Table  1.   Mixture proportions of RPC

    kg/m3
    材料胶凝材料减水剂钢纤维
    RPC1 23892817.7234.3159
    下载: 导出CSV

    表  2  RPC基本力学性能参数

    Table  2.   Basic mechanical performance parameters of RPC

    材料fc/MPaft/MPaE/GPaμρ/(g·cm−3
    RPC1209.2746.20.222.44
    下载: 导出CSV

    表  3  靶体多次侵彻实验结果

    Table  3.   Experimental results of targets subjected to multiple penetrations

    侵彻次数v0/(m·s−1h/mmS/cm2H/mmNWmax/mm
    1511.5129.1329.7 59.5 0 0
    2552.5257.4344.1 79.812 2
    3560.0290.3354.8114.91313
    下载: 导出CSV

    表  4  弹体、钢箍以及钢筋材料模型参数

    Table  4.   Model parameters of projectile, steel culvert and steel bar material

    材料ρ/(kg·m−3E/GPaμσy/MPa
    弹体7 8502100.31 650
    钢箍/钢筋7 8002100.3 300
    下载: 导出CSV

    表  5  损伤演化函数η(λ)

    Table  5.   Damage evolution function η(λ)

    λη λη
    00 4.0×10−60.51
    2.7×10−50.626.7×10−40.37
    6.8×10−50.921.2×10−30.27
    8.0×10−50.992.0×10−30.20
    1.0×10−41.005.5×10−30.10
    1.4×10−40.961.6×10−20
    2.6×10−40.66
    下载: 导出CSV

    表  6  活性粉末混凝土的K&C模型应变率效应特征点取值

    Table  6.   K&C model strain rate characteristic points of reactive powder concrete

    $\dot \varepsilon/{\rm{s}^{-1} }$$\psi $$\dot \varepsilon/{\rm{s}^{-1} }$$\psi $$\dot \varepsilon/{\rm{s}^{-1} }$$\psi $
    –30 0009.97–101.27–1×10–41.07
    –4 7829.97–31.24–1×10–51.03
    –1 0005.41–11.2201.00
    –3003.45–0.11.18301.00
    –1002.29–0.011.142652.94
    –251.28–1×10–31.1130 0002.94
    下载: 导出CSV

    表  7  RPC的K&C模型8号状态方程参数

    Table  7.   Parameters of No. 8 equation of state in the K&C model of RPC

    εV
    εV1εV2εV3εV4εV5εV6εV7εV8εV9εV10
    00.00150.00430.01010.03050.05130.07260.09430.1740.208
    σV/GPa
    σV1σV2σV3σV4σV5σV6σV7σV8σV9σV10
    00.0410.0940.2920.8811.6222.5113.5738.71411.579
    Kav/GPa
    Kav1Kav2Kav3Kav4Kav5Kav6Kav7Kav8Kav9Kav10
    27.527.527.88529.28834.84340.42545.98050.186112.915137.5
    下载: 导出CSV
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出版历程
  • 收稿日期:  2020-05-25
  • 修回日期:  2020-10-22
  • 网络出版日期:  2021-04-21
  • 刊出日期:  2021-06-05

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