隧道爆破现场高速图像采集与精确控制爆破参数研究

龚敏 吴昊骏

龚敏, 吴昊骏. 隧道爆破现场高速图像采集与精确控制爆破参数研究[J]. 爆炸与冲击, 2019, 39(5): 051101. doi: 10.11883/bzycj-2018-0319
引用本文: 龚敏, 吴昊骏. 隧道爆破现场高速图像采集与精确控制爆破参数研究[J]. 爆炸与冲击, 2019, 39(5): 051101. doi: 10.11883/bzycj-2018-0319
GONG Min, WU Haojun. High-speed photography image acquisition system in tunnel blasting and parameters study on precisely controlled blasting[J]. Explosion And Shock Waves, 2019, 39(5): 051101. doi: 10.11883/bzycj-2018-0319
Citation: GONG Min, WU Haojun. High-speed photography image acquisition system in tunnel blasting and parameters study on precisely controlled blasting[J]. Explosion And Shock Waves, 2019, 39(5): 051101. doi: 10.11883/bzycj-2018-0319

隧道爆破现场高速图像采集与精确控制爆破参数研究

doi: 10.11883/bzycj-2018-0319
基金项目: 国家自然科学基金(51678048);重庆市科技开发计划重点项目(cstc2014yykfB30002)
详细信息
    作者简介:

    龚 敏(1963- ),男,博士,教授,博导,gongmin@ces.ustb.edu.cn

  • 中图分类号: O389

High-speed photography image acquisition system in tunnel blasting and parameters study on precisely controlled blasting

  • 摘要: 受隧道内环境恶劣、相机防护等诸多因素制约,隧道现场爆破的高速图像采集与分析尚未实现,而这对精准控制爆破参数非常重要。以重庆某隧道为研究背景,在解决现场测试技术难题基础上,得到隧道爆破过程完整图像并同时获取爆破振动数据;据此分析了隧道爆破岩石破裂现象:炸药起爆15~18 ms后岩体移动,21 ms左右形成空洞并不断扩展后抛出;探讨了同对掏槽眼爆破协同作用时间与微差降振时间之间的矛盾,研究表明兼顾二者作用的起爆时差为8~50 ms;通过分析爆破裂隙扩展曲线特点并结合实测振动数据,确定起爆54 ms时形成第二临空面,较按过去方法确定的时间更精确,以此进行现场掏槽段位设计的降振效果良好;研究结果可为精准控制爆破提供参考。
  • 图  1  高速摄像电控与数据处理系统图

    Figure  1.  Electronic control and data processing system of high-speed camera

    图  2  现场相机控制布设方框

    Figure  2.  Camera control and layout on field

    图  3  上台阶炮孔布设及爆破参数设计图

    Figure  3.  Holes layout of upper bench and design of blasting parameters

    图  4  掏槽雷管样本各段延时范围

    Figure  4.  Initiation time delay ranges of detonators samples per period for cutting

    图  5  隧道现场爆破掏槽区岩石破裂过程图

    Figure  5.  Rock failure processes of cutting blasting on field

    图  6  2015.10.16爆破振动曲线(掏槽区)

    Figure  6.  Blast-induced vibration curve on October 16, 2015 (cutting zone)

    图  7  炮孔起爆初期岩体的移动方向和范围

    Figure  7.  The moving direction and ranges of the rock mass at the initial stage of blasting

    图  8  掏槽区岩体移动面积随时间变化图

    Figure  8.  Moving area change of rock mass with time in cutting blasting

    图  9  移动岩体占掏槽区面积比例随时间变化图

    Figure  9.  The area proportion of moving rock mass in cutting zone change with time

    图  10  隧道单孔单自由面爆破正上方地面振动曲线图

    Figure  10.  Ground vibration curve which is directly above a single shot with single free surface

    图  11  两孔不同微差起爆时间对应的合成振速图

    Figure  11.  Superposition vibration velocity corresponding to two different millisecond delay times between two holes

    图  12  计算合成振动曲线与实测振动曲线的对比

    Figure  12.  Comparation of the calculated superposed vibration curve and the measured one

    图  13  典型起爆时刻空洞尺寸变化的计算结果图

    Figure  13.  Calculation results of the cave’s size change at typical initiation time

    图  14  两个方向爆破空洞长度随时间变化图

    Figure  14.  Cave size change with time in two directions

    图  15  空洞尺寸、振速、起爆时间之间动态关系图

    Figure  15.  Dynamic relationship among cave size, vibration velocity and initiation time

    图  16  优化后的隧道掏槽爆破设计与实测振动曲线图

    Figure  16.  Optimized cut blasting design and vibration curve measured in the tunnel

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出版历程
  • 收稿日期:  2018-08-29
  • 修回日期:  2018-10-24
  • 刊出日期:  2019-05-01

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