RU2140492C1 - Method for stabilization of ground mass in seismodangerous regions - Google Patents

Abstract

FIELD: protection of the ground mass of the Earth's crust in seismodangerous regions, in particular, methods for action on stress condition of sections of the Earth's crest preventing earthquakes or reducing the force of their disastrous effect. SUBSTANCE: the method consists in removal of strong elastic deformations and internal stresses in a big mass of the Earth's crust for protection against earthquakes and reduction of their destructive force. It is effected by stabilization of the ground mass due to injection of liquid of a definite chemical composition in it through bore-holes and wells, which changes the composition of the supplied ground waters and facilitates removal of elastic stresses in these sections of the Earth's crest. EFFECT: enhanced efficiency. 1 cl

Description

 The invention relates to the field of protection of the soil mass of the earth's crust in seismically hazardous areas, and in particular to methods of influencing the stress state of the earth's crust, preventing earthquakes or reducing the strength of their catastrophic effects.

 There is a method of protecting underground utilities by weakening the contact between the soil and the surface of the pipeline during the period of dangerous displacements of the soil, in which the weakening of the contact is produced by supplying water to the soil to the surface of the pipeline until the soil is completely saturated / 1 /.

 There is also a method of stabilizing the soil of the foundation of the structure, adopted as a prototype, which consists in introducing locally at several points of controlled doses of liquid into the foundation at a predetermined distance from its sole and side walls to ensure stabilization of the soil on which the foundation rests / 2 /.

 Both of these methods are based on reducing the internal stress of the soil, as a result of which it has a lesser effect on underground and surface objects during the period of dangerous soil movements. Moreover, the process of soil displacement itself, in particular as a result of earthquakes, is not eliminated.

 The objective of the invention is to provide a method of relieving strong elastic deformations and internal stresses in a large soil mass of the earth's crust to protect against earthquakes, reduce their destructive force.

 The problem is solved by stabilizing the soil mass by pumping into it through wells and wells an aqueous solution of a certain chemical composition that changes the composition of underground groundwater and thereby helps relieve elastic stresses in these areas of the earth's crust.

 The soil massif here refers to the area of the earth's crust, including the upper layer of sedimentary loose ground rocks and rock crystalline rocks beneath it, where underground groundwater is able to penetrate, the level change of which is recorded by wells and natural sources during earthquake preparation and is one of the most reliable precursors earthquakes.

 In the presence of a medium-term or long-term forecast of an impending earthquake in this area, taking into account hydrogeological data, a number of well and well profiles are drilled across the tectonic fault zone, covering all directions and depths of the groundwater flow. At the same time, samples of soils and rocks are taken and the type of fluid is determined experimentally, which determines the maximum reduction in elastic stress stresses in the soil mass due to an increase in the flexibility of soils to deformations and / or density equalization in its different areas. Then the composition of groundwater is changed, for which the appropriate type and volume of fluid is pumped into the soil mass. The sufficiency of fluid injection is monitored by the appearance of injected fluid in the control wells. At the same time, the number and strength of foreshocks are recorded, with a decrease in which the injection of the solution into the ground is stopped.

 The method is based on the use of the action of two processes in the earth's crust - the effect of adsorption lowering of the strength of solids (the Rebinder effect) and the mechanism of diffusion fluid substitution.

 The Rebinder effect / 3 / manifests itself when surfactants are added to a water solution, which help to reduce the bond strength between individual grains and microcrack walls in soils and rocks, as a result of which both are more easily destroyed and become more plastic, avoiding the occurrence of strong elastic stress deformations leading to earthquakes.

 The mechanism of diffusion fluid substitution / 4, 5 / is manifested during diagenetic and hydrothermal-metasomatic processes in the presence of chemically aggressive solutions to a certain extent, capable of dissolving the components of the soil mass in one place and postponing them in another. The essence of this process is that in the process of tectonic deformations, differences in the density of rocks appear, so that in some of their sections open cracks appear, and in others the rocks are very compressed. During this period, in this environment saturated with mineralized waters, the development of hydrothermal-metasomatic processes begins, in which dissolved chemical components are carried out from densely compressed areas into zones of tectonic cracks, voids, and more unconsolidated rocks. This redistribution is accompanied by the formation of colloidal highly concentrated solutions that fill the fractured voids and crystallize in the end in the form of vein formations of calcite, aluminosilicate silica, fluorite, iron oxide, sulfur sulfide and other compositions. Thanks to these processes, the density of rocks is equalized and thus the very cause of elastic deformations is eliminated.

 Moreover, such phenomena occur not only after a large tectonic fracture of rocks, i.e. after the earthquake, but also before it, when microcracks and microshears, which precede the main tectonic movement, are just beginning to appear in the rocks. This is known, for example, in the nascent centers of earthquakes, where their forerunners are the so-called foreshocks - small seismic impacts that are the result of the initial stages of faults in the rocks.

 Therefore, the inclusion of the Rebinder effect or the diffusion fluid substitution mechanism before the start of the main displacement can reduce the probability and intensity of its discontinuous stage and mitigate its seismic effect, i.e. reduce the likelihood of a catastrophic earthquake.

 It should be noted that the centers of the earthquake can occur at great depths, not accessible for the penetration of groundwater. However, the source itself is created as a result of general geodynamic stresses in a large area of the earth's crust, including in the near-surface ground mass, where groundwater flows. Therefore, it may be sufficient to remove tectonic stress in this near-surface massif in order to reduce the strength of the tectonic impact in the earthquake source, or to move this source itself away from densely populated points, or completely eliminate it.

 The method is implemented in the following sequence of operations. In the seismically active zone, during the period of the medium-term or long-term earthquake forecast, a number of well profiles are drilled across the zone of the alleged fault, so that, taking into account the available hydrogeological data, cover all underground water flows and to the appropriate depth. The layout, the number and depth of boreholes on the earth's surface is determined depending on the orientation of the active tectonic zone, the degree of permeability of the rocks of the soil mass for the solution and their water saturation, the direction of movement of groundwater. They also use the existing network of wells and wells, which served for hydrogeological and other purposes. Several control wells are also being drilled, which will serve to monitor the success of groundwater filling with chemical solutions. Mostly wells are located across a seismically dangerous fault.

 At the same time, samples of soils and rocks are taken from these wells and experimentally determine the type of fluid that can provide a reduction in stress elastic deformations in the soil mass. The effect of two classes of liquids is experimentally investigated - surfactants and chemically aggressive solutions that can dissolve and redeposition the components of the host rocks.

 The first of them, in accordance with the Rebinder effect, reduce the mechanical strength of soils and thereby increase the tendency of rocks to plastic deformations and do not allow the creation of strong elastic stresses leading to earthquakes. The amount of these substances produced by modern industry is very large. The choice depends on the ability of certain substances to penetrate the rocks of the soil massif, which constitutes a seismically dangerous area, as well as on the safety of their use for the population consuming groundwater, and on the high cost. Experiments for this class of liquids are carried out in this way: under pressure in an aqueous medium, cubes of soils and rocks are crushed by adding certain surfactants to the water. The easier crushing of the rock is, the more effective a particular substance is for certain types of rocks.

The second class of liquids is selected based, for example, from experimental studies / 6 / on hydrothermal-metasomatic processes in the earth's crust. As an apparatus for this purpose, an autoclave is used, into which the corresponding liquid is poured and a test tube with pressed finely ground rock is placed inside it. Changing the composition of the liquid at the appropriate temperature and pressure of the earth's depths, determine the degree of its chemical interaction with the rock with the development of diffusion metasomatic processes. The more significant the degree of chemical interaction, the more spectacular is the liquid for use in order to equalize the density in the rocks. It is possible to use, in accordance with experiments / 6 /, acidic and near-neutral chloride, fluoride, boric, carbonic solutions of salts of rock-forming components (Na, K, Ca, Mg, Fe, Al) and the corresponding acids (HCl, HF, H ₂ BO ₃ , H ₂ SO ₄ , H ₂ CO ₃ ) as well as alkaline solutions of hydroxides, carbonates and silicates of sodium and potassium. In many cases, the basis of the solution can be NaCl or KCl, as the predominant components of natural fluids with some acidification of HC or alkalization of aOH to obtain the pH value necessary for the reactions. The concentration of solutions can be from 10 ^-3 to 1.0 m. It is necessary to evaluate the possibility of using such substances at real temperatures in the studied soil massif and, if necessary, to select other substances to activate the diffusion fluid substitution mechanism associated with hydrothermal metasomatic and diagenetic processes.

 One of these substances is oxygen, which, as you know, is used to clean groundwater from impurities with sedimentation along cracks and micropores of iron and manganese oxides. It is possible that in some cases, reagents widely used for underground leaching of ore components in the hydraulic well mining method / 7 / will turn out to be effective for use.

 After conducting experiments, among these two classes of substances, the types of liquids that most effectively affect stress relief in soils, are readily soluble and penetrate into soils, are relatively cheap and harmless to the population consuming groundwater.

 Then, through the prepared wells, the selected solutions are introduced into the soil mass, thereby changing the composition of the groundwater. The penetration efficiency of the injected solution is evaluated by its penetration into the control wells, through which they are not injected. At the same time, the number and strength of foreshocks, which are harbingers of the earthquake, are recorded. A decrease in their number and strength is an indicator of the effectiveness of the measures taken, after which the pumping of the solution into the array is stopped.

 The present invention, in contrast to the known ones, provides a radical decrease in elastic stress stresses in the soil mass, which leads to a decrease in the destructive force of an earthquake or even to complete elimination of its source. Its use equips humanity with new opportunities for regulating the elements of underground resources.

Sources of information:
1. USSR author's certificate N 386069, E 02 D 31/08, 06/14/73.

 2. French Patent N 2692931, E 02 D 3/10.

 3. Rebinder P. A. Selected works. Surface phenomena in dispersed systems. Physico-chemical mechanics. -M.: Science, 1979.

 4. Shabalin L. I. A new principle for explaining the nucleation of vein deposits and acidic igneous rocks based on the mechanism of diffusion fluid substitution. University News. Series: geology and exploration. -1995, N 4, p. 118-126.

 5. Shabalin L.I. A geological example of the mechanism of diffusion fluid substitution during the nucleation of magma-like vein deposits. University News. Series: geology and exploration, 1997, N 1, p. 79-39.

 6. Zaraisky G. P. Zonality and formation conditions of metasomatic rocks. - M.: Science, 1989.

 7. Mountain encyclopedia. - M.: Soviet Encyclopedia, 1991, v. 1, p. 465.

Claims (1)

 A method of stabilizing a soil mass in seismically hazardous areas by pumping liquid into a soil mass, characterized in that in the presence of a medium-term or long-term forecast for an upcoming earthquake in this area, a network of wells is drilled across the tectonic fault zone taking into account hydrogeological data, covering all directions and depths of underground flows groundwater, at the same time, soil samples are taken from the wells and experimentally determine the type of fluid that causes the maximum decrease elastic stresses in the soil mass by increasing the flexibility of the soil to deformations and / or leveling the density in its different sections, then change the composition of groundwater, for which the appropriate type and volume of fluid are pumped into the ground mass through the wells, the sufficiency of the fluid input is monitored by the appearance of the injected fluid in control wells, the number and strength of foreshocks are simultaneously recorded, with a decrease in which the pumping of liquid into the soil mass is stopped.