RU2713796C2 - Method for burial of liquid effluents in geological environment - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to environmental protection, in particular to burial of liquid effluents in geological environment. Initially, extraction is carried out in the geological environment of areas having a developed system of open fractures, having hydrodynamic permeability and presence of a mechanism of downward filtration of fluids. Then, drilling is performed to these areas of pumping wells and pumping of waste water through these wells. At that, extraction in the geological environment of the areas with downward filtration of fluids includes establishment of areas of volcanic rock massif having open active fracture. In the selected areas with downward filtration of fluids from above the depositing cover, represented by sedimentary rocks, adjoins the underlying mass of volcanites, and open acting fracture connects sedimentary cover with bulk of volcanites. Selected areas with downward migration of fluids are analyzed by sampling cores and, if necessary, artificially increasing permeability of said areas around existing fracture.

EFFECT: higher efficiency of burial of liquid effluents in geological environment.

1 cl, 1 dwg

Description

The invention relates to the field of environmental protection from polluting the surface hydrosphere of liquid effluents of any composition and with any pollutants. Provides increased efficiency of the disposal of liquid effluents in the geological environment. The inventive method includes the use for burial of liquid effluents, the geological environment, in the field with a downward migration of fluids, by pumping liquid effluents through wells. For this, according to the data of geophysical studies, areas of the geological environment with downward fluid migration are identified that have an open, active fault, have the necessary filtration regime for burial, or specifically provide the necessary filtration parameters, after which buried sewage is pumped into these areas.

Various methods are known for underground disposal of industrial and municipal liquid waste. The most common ones include: wastewater injection into deep aquifers; burial of wastes in loose rocks of aeration zone of high power (due to the use of sorption capacity of enclosing rocks); landfill in artificially created containers in poorly permeable clay and saline rocks (using mechanical excavation, hydraulic fracturing, underground explosions or salt dissolution); burial in waste mine workings (mines, mines); the use of certain types of wastewater in the oil flooding system in oil fields. In this case, the reservoir in the nearest (within a radius of 20-30 km) neighborhood should not go to the surface or have a connection with the river.

Among these methods, close analogues of the claimed invention include methods for underground disposal of liquid waste by pumping it through absorbing wells into reservoirs (Goldberg V.M., Skvortsov N.P., Lukyanchikova L.G. Underground burial of industrial wastewater. - M .: Nedra, 1994 .-- 282 p.).

A common main disadvantage of these methods is the low efficiency of liquid wastewater disposal, due to the possibility of their penetration to the surface, as well as pollution of the surface of the lithosphere.

As the main prototype was adopted "Method for the disposal of radioactive and other toxic liquid wastes" (RF patent N 2173490, class G21F 9/24, authors - Korobova AD, Soldatkina SI), according to which the disposal of liquid waste is carried out in the bowels of a low-temperature hydrothermal system located in areas of tectono-magmatic activity and functioning in the thickness of an acidic glassy ash-pumiceous material at a depth of 250-400 m. For this, a system of shallow wells drilled in zeolitized wells is used for burial and clayed vitroclastic rocks in the zones of lateral flows of hydrothermal areas in the absence of surface discharge of thermal waters.

The disadvantage of this and other methods is their somewhat limited scope in a geological environment with a low-temperature hydrothermal system, which also has the ability to only lateral flows.

In addition, the disadvantages include the rather low parameters of such technologies: their productivity is 20-35 m ³ / h of liquid effluents (at pressures of 40-60 atm.). The parameters of the absorbing collector have the following values: conductivity coefficient 1.3–4.3 m ² / day, filtration coefficient 0.06–0.2 m / day, and pick-up coefficient 0.5–3.8 m ³ / hour atm.

The objective of the invention is to provide a method that provides the most efficient disposal of liquid effluents in a geological environment.

The solution to this problem is achieved by the fact that initially geophysical methods isolate the geological environment, which has areas with a downward migration of fluids having certain permeabilities (open, active fault) to ensure the proper filtration regime for buried sewage.

The highlighted areas with downward fluid migration are then studied by core sampling and research. If necessary, the permeability of these areas around the existing fault is artificially increased.

Then, through specially drilled injection wells, buried sewage is pumped into these zones, with the possibility of their downward migration.

The use of these operations causes the emergence of a number of new positive advantages of the claimed invention.

According to the above essence of the invention, the first and main difference is the use of a geological environment for burial of liquid effluents, which has areas with downward migration of fluids having certain permeabilities to ensure proper filtration.

In the practice of underground disposal of sewage, the targeted use of a geological environment that has areas with downward fluid migration and has certain permeabilities to ensure the proper filtration regime for transit through them deep into the lithosphere of liquid effluents is not known.

The method is as follows (Fig. 1). Initially, it is necessary to ensure that the methods of geophysics create favorable conditions for moving the buried waters deeper into the geological environment by identifying areas of a massif of volcanic rock type 4, which have an open, active fault 3 and a sufficiently developed system of cracks (moreover, with open fracturing), which turns these rocks into good reservoirs, as well as the presence in them of a mechanism that sucks sewage deep into the lithosphere.

To this end, geophysical methods initially distinguish a geological environment that has areas with downward fluid migration, which have certain permeabilities to ensure proper filtration.

Methods include the study of fracture characteristics of selected areas of the geological environment. It is carried out using cores using the method of luminescent flaw detection (including the MBS-10 microscope with an MFP microphotographic device, a Sony DSC-W200 digital camera, Line 506 ultraviolet irradiator) adapted to rock formations.

Then, if necessary, for example, explosive technologies increase the permeability of these selected areas to ensure an effective speed (30-50 m / day or 1.25-2.0 m / h) of downward migration of wastewater.

To prevent contact with the day surface 1 or the aquifer, a prerequisite is the presence of a sedimentary cover 2 consisting of rocks with low permeability (clay-containing).

Then, through special injection wells 5, drilled to these areas, they carry out the injection of liquid effluents, which, thanks to the current mechanism of downward migration, move deep into the lithosphere 6.

It should be noted that the manifestations of natural downward migration of groundwater have so far been recorded in many parts of the upper lithosphere of the world (but so far this natural mechanism has not been used in the disposal of wastewater). The mechanism of manifestation of this form of downward fluid migration is often associated with a decrease in the hydrodynamic potential with depth, which, in turn, is due to a number of geological factors (due to the difference in lithological structure, capacitance-filtration properties, etc.).

In particular, downward groundwater filtration was recorded in the Kurinsky Depression, which is associated with the natural mechanism of downward groundwater infiltration from the sedimentary cover (sedimentary rock mass) into the depth (mass) of volcanic rocks (1. Borevsky LV, Kremnetsky AA The geological role of groundwater in progressive metamorphism in open and closed systems // Collection: Groundwater and the evolution of the lithosphere. M., Nauka, 1985. T. 2. P. 8-13.

2. Yakovlev L.E. Infiltration of water into the basalt layer of the earth's crust. M., Nauka, 1999 .-- 200 p.).

It should be noted that volcanic strata (green, brown, as well as acidic and calc-alkaline types) are widely developed in various parts of the lithosphere. Thus, detailed documentation of sections of numerous wells in the North-East Ladoga (Russian Federation) showed that here volcanic rocks compose the 2nd strata. In them, a break between lava outflows is recorded by a partial erosion of the lower stratum, a horizon of tuffites and a pack of gravelites with interbeds of mudstones.

Volcanic massifs are also widespread in Kazakhstan - for example, volcanics are characteristic of the Chingiz paleo-island arc, silicic volcanics of Central Kazakhstan.

Claims (1)

The method of burial of liquid effluents in a geological environment, including the allocation in the geological environment of areas with a developed system of open fractures, having hydrodynamic permeability and the presence of a downward fluid filtration mechanism, drilling of injection wells to these areas and pumping wastewater through these wells, characterized in that in the geological environment of areas with downward fluid filtration includes the establishment of areas of an array of volcanic rocks with an open active fault, at the volume in the selected areas with downward fluid filtration from above lying sedimentary cover, represented by sedimentary rocks, adjoins the underlying volcanic massif, and the open acting fault connects the sedimentary cover with the volcanic massif, and the selected areas with downward fluid migration are examined by core sampling and, if necessary, artificially increased the permeability of these areas around the existing fault.

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