Remote sensing quantification investigation method of high-pressure water-rich fault engineering geological rock soil

Abstract

The invention relates to a remote sensing quantification investigation method of high-pressure water-rich fault engineering geological rock soil. The remote sensing quantification investigation method of the high-pressure water-rich fault engineering geological rock soil comprises the steps of investigation preparation of a high-pressure water-rich fault, punching process of the high-pressure water-rich fault engineering geological rock soil, data collection after high-pressure processing of the water-rich fault engineering geological rock soil, special designing of remote sensing quantification transmission control steps and special optimizing of relevant parameters in sequence. Defects that engineering geological rock soil and frozen soil sedimentation in places with complex environments and severe conditions can not be measured remotely and static sounding can not achieve required prospecting depth and accurate detection are overcome. The data collection of the water-rich fault engineering geological rock soil of different structures and with different state parameters after high pressure processing is achieved. Dynamic, high-speed, accurate and real-time collection is achieved. Real-time and accurate control of the investigation is achieved. Good technique effect is achieved.

Description

technical field [0001] The invention relates to the technical fields of geology and geotechnical engineering, and in particular to a remote sensing quantitative survey method for high-pressure water-rich fault engineering geological rock and soil. Background technique [0002] With the rapid development of my country's transportation construction, tunnel engineering may often encounter faults in high-pressure water-rich areas. Faults in high-pressure water-rich areas are generally large in scale, and the rock mass in the faults is broken. Large-scale water inrush and mud (rock) inrush have caused casualties and seriously affected the safety of tunnel construction and operation. [0003] A few days ago, for tunnels crossing faults in high-pressure water-rich areas, generally according to the principle of "mainly plugging", the advanced full-section grouting method is used to reinforce and block water in the fault fracture zone, and a grouting reinforcement ring is formed aroun...

AI Technical Summary

Problems solved by technology

[0014] The object of the present invention is to provide a remote sensing quantitative survey method for engineering geological rock and soil of high-pressure water-rich faults with automatic continuous detection, monitoring and intelligent survey, which overcomes the problems in the prior art: engineering geology in places with complex environments and difficult conditions Geotechnical and permafrost subsidence cannot be remotely measured, and it also solves the problem of exploration depth that cannot be solved by static penetration testing, especially the accurate detection of depth. Through the unique settings of different sensors, the engineering geology of water-rich faults with different structures and state parameters is realized. The data acquisition after high-pressure processing of rock and soil has achieved dynamic, high-speed, and accurate real-time acquisition, thereby realizing real-time and precise control of survey through unique remote sensing quantitative transmission. The remote sensing of high-pressure water-rich fault engineering geological rock and soil The quantitative survey method also realizes geotechnical engineering deformation telemetry in places with complex environments and difficult conditions, and is also suitable for industrial deformation monitoring and remote monitoring in toxic, radioactive, polluted and other hazardous environments and high-radiation sites; it is an effective and accurate survey An Accurate and Reliable Remote Sensing Quantitative Survey Method for Engineering Geological Rock and Soil of High Pressure and Water Rich Faults