Abstract:Research purposes:Because that most of the advanced geological prediction of tunnel seismic reflection method is based on 2D prediction and the accuracy is not high, an effective observation method of advanced geological prediction of three-dimensional seismic reflection is proposed. On this basis, a complete set of technology research on data processing and imaging is carried out, and its feasibility and reliability are verified through numerical simulation and physical experiments, which is effectively applied to the production of advanced geological prediction of railway tunnel. Research conclusions:(1) Based on the basic theory of elastic wave, a three-dimensional seismic wave advance geological prediction observation system based on shear wave is proposed. Compared with the traditional P-wave prediction method, it has higher resolution and is more sensitive to water body. (2) The migration imaging method based on Kirchhoff integral is realized, which uses the energy superposition criterion for three-dimensional velocity scanning, and uses the fast marching method for travel time calculation, which is not limited by the observation system, has high calculation efficiency, and do not need a very accurate velocity model. (3) The finite difference numerical simulation of three-dimensional seismic wave field of tunnel is realized, and the typical adverse geological models such as lithologic interface with different dip angles, faults with different thickness and karst caves with different diameters are established, and their three-dimensional imaging characteristics are analyzed and summarized. (4) Through the physical model and application experiment, the method presented in this paper is feasible and reliable, and can be popularized and applied in tunnel advanced geological prediction.
蔡盛. 基于横波的三维超前地质预报方法及应用[J]. 铁道工程学报, 2022, 39(10): 30-36.
CAI Sheng. The 3D Advance Geological Prediction Method Based on Shear Wave and Its Application. Journal of Railway Engineering Society, 2022, 39(10): 30-36.
钱七虎.地下工程建设安全面临的挑战与对策[J].岩石力学与工程学报,2012(10):1945-1956.Qian Qihu.Challenges Faced by Underground Projects Construction Safety and Countermeasures[J].Chinese Journal of Rock Mechanics and Engineering, 2012(10):1945-1956.
[2]
王思敬.中国岩石力学与工程的世纪成就与历史使命[J].岩石力学与工程学报,2003(6):867-871.Wang Sijing.Century Achievements and New Historical Mission of Rock Mechanics and Engineering in China[J].Chinese Journal of Rock Mechanics and Engineering,2003(6):867-871.
[3]
王梦恕.对岩溶地区隧道施工水文地质超前预报的意见[J].铁道勘查,2004(1):7-9.Wang Mengshu.Hydrologic and Geological Forecast of Tunnel Construction in the Karst District[J].Railway Investingation and Surveying,2004(1):7-9.
[4]
李术才,薛翊国,张庆松,等.高风险岩溶地区隧道施工地质灾害综合预报预警关键技术研究[J].岩石力学与工程学报,2008(7):1297-1307.Li Shucai,Xue Yiguo,Zhang Qingsong, etc.Key Technology Study on Comprehensive Prediction and Early-Warning of Geological Hazards During Tunel Construction in High-risk Karst Areas[J].Chinese Journal of Rock Mechanics and Engineering,2008(7):1297-1307.
[5]
李文瑞.基于TRT系统的隧道三维地质构造分析应用及改进方法研究[D].北京:北京交通大学,2017.Li Wenrui. Research on the Analytical Application and Improvement of Three-Dimensional Geological Structure Based on TRT System[D].Beijing:Beijing Jiaotong University,2017.
[6]
丁鹏程,杨国权,李振春,等.基于三维多模板快速推进算法的复杂近地表射线追踪[J].石油物探,2016(5):483-492.Ding Pengcheng,Yang Guoquan,Li Zhenchun, etc.Ray Tracing Based on 3D Multi-stencils Fast Marching Algorithm for Complex Near-surface Model[J].Geophysical Prospecting for Petroleum,2016(5):483-492.
[7]
张晓丹,佘翼翀,张志禹,等.旅行时快速步进(FMM)波前追踪算法研究[J].国外电子测量技术,2018(5):19-22.Zhang Xiaodan,She Yichong,Zhang Zhiyu, etc. Research on Fast Matching Method Wave Front Tracking of Travelling Time[J]. Foreign Electronic Measurement Technology,2018(5):19-22.
2022, Vol. 39 
版权所有 © 2014 《铁道工程学报》编辑部