矿井地面-井下电性源瞬变电磁探测响应规律分析
Analysis of grounded Transient Electromagnetic with surface-tunnel configuration in mining
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摘要: 为了避免井下瞬变电磁探测面临的金属强干扰、高瓦斯矿井防爆等要求,对矿井地面布置瞬变电磁发射源,在井下巷道、采场接收的瞬变电磁探测方法进行研究。采用三维时域有限差分法建立电性源瞬变电磁三维正演算法,研究地面电性源发射,井下巷道接收的瞬变电磁响应规律。首先采用均匀半空间模型和层状模型研究地下接收瞬变电磁场的曲线形态特征以及对地层电阻率变化的敏感性,并考察接收排列的最佳方位角和收发距。以层状模型为例设置均布的5条测线接收排列,计算了不同接收点的瞬变电磁响应响应曲线,对比分析曲线形态,得到电性源瞬变电磁地面发射、井下接收采集范围和传播规律,即:1电性源磁响应在垂向(broadside)排列方向比在轴向(inline)排列幅值大,井下接收的最佳测线方向为垂直排列方向;2发射长度为1 km的电性源井下接收有效探测深度可达到1.5 km;3电阻率较高的煤层对接收点响应曲线的影响不大。其次,设计包含顶板水和底板水的模型,计算得到了不同类型含水层的响应规律,对比曲线可以发现明显的异常差异。最后,设计一个包含断层的复杂模型,得出了倾斜充水断层影响下的瞬变电磁响应曲线。得到地面发射-井下接收的瞬变电磁方法的采集范围和传播规律,最佳方位角为垂直排列方向;地面发射-井下接收的瞬变电磁方法对顶板水和底板水有一定的分辨和识别能力;地面发射-井下接收的瞬变电磁方法能够初步对倾斜充水断层的电磁场响应进行识别。该方法仅要求接收机在井下,易于进行本安设计。Abstract: In order to avoid the strong metal interference and gas explosion of Transient Electromagnetic (TEM) detec- tion in mines,a new configuration,which put the transmitting line source on the surface and the receiver in the under- ground mining roadways,was investigated. Its modeling algorithm was developed using finite difference time domain ( FDTD) method in three dimensions. The characteristics of this configuration was studied with numerical experiments. Homogeneous half space and layered models were used to study the curve style and its sensitivity to the earth resistivity changes. The influences from the distance between the transmitter and receiver,the receiver azimuth angle were both compared. Five lines were designed along different positions. Many useful phenomenon were obtained according to the comparison as follows:(1)The TEM responses amplitude from the broadside are quite larger than that of the inline.(2) The valid investigation depth can reach about 1. 5 km using a line source of 1 km in length. (3) The high resis- tivity coalbed has little influences to the simulated acquired data. Then,models including roof and bottom water are simulated. The receiver decay curve has obvious difference which can be used to identify the acquirer. Finally,a com- plex model including dipping fault was used in the simulation. The best azimuth angle is broadside angle. This configu- ration can identify roof and bottom water in mines,and can generally identify dipping fault. This configuration is easy for intrinsically safe design in instruments manufacturing.