RU2501905C2 - Method to prevent filtration of contaminated high-mineralised industrial wastes into water-bearing horizon of underground water and anti-filtration accumulator - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method consists in maintenance of the level of industrial wastes within the circuit of the anti-filtration accumulator. For this purpose they previously detect density of high-mineralised industrial wastes and density of edge underground water. The distance is identified from the specified point of the bed to the arbitrarily chosen plane of comparison. The maximum permissible drop is defined between them, as well as water density in the specified point of the bed and the arbitrarily chosen plane of comparison. Maintenance of the level of high-mineralised industrial wastes in the anti-filtration accumulator is performed below the natural level of the edge underground (soil) water, and it is monitored by the value of the "given" pressure of the liquid phase of industrial wastes, and using the ratio P_giv = hγ+z(γ+γ₀)/2, where P_giv - given pressure of liquid phase of industrial wastes, M·L^-1·T^-2; h - hydrostatic height (level) of liquid industrial wastes of heterogeneous composition in the accumulator bowl, L; z - distance from the specified point of the bed to the arbitrarily chosen plane of comparison, L; γ and γ₀ - volume weight of water in the specified point and on the arbitrarily chosen plane of comparison, M·L^-2·T^-2. The anti-filtration accumulator for implementation of the method comprises a bowl, an anti-filtration screen, arranged on the bottom of the accumulator and in boards of the bowl, and a water-regulating systems from water-regulating wells. Additionally inside the bowl there are water-distributing wells, which are connected with a water-regulating device and a system of horizontal pipes.

EFFECT: higher reliability of protection against pollution of underground water with brines filtered from an accumulator and other liquid wastes of industrial production that are dangerous for human livelihood, possibility is provided for environmental stability of compositions available in a liquid wastes or brines accumulator and their finalisation to the appropriate technologically stable condition.

7 cl, 1 dwg

Description

The invention relates to the field of ecology, hydraulic engineering, nature and subsoil use, in particular, to preventing the harmful effects of filtering contaminated liquids (brines) from filtration devices into aquifers of groundwater, including groundwater, and can also be used to maintain optimal level mode and quality of contaminated liquids (water content of brines) in filtration devices.

Of particular environmental importance are the tasks related to the protection of underground aquifers and their complexes from the penetration of brines from storage pools or sedimentation basins, which are widely used in the processing of hydromineral raw materials by the basin method, as well as for the storage of production wastes. Means of antifiltration protection, which are usually used in such cases, are the lining of the bottoms and sides of the pools with various permeable materials, for example, polyethylene, bitumen, clay and other screens. All of the listed options for protective screens require significant financial investments for their construction, as well as for the maintenance, operation and environmental monitoring (monitoring).

Known methods based on the operation of a permanent pumping system and antifiltration devices, made in the form of an injection curtain and a well system, several going into water-resistant deposits [1]. However, the creation of an injection curtain, achieved through the continuous operation of the pump system, leads to significant labor-intensive and material costs.

A known method of preventing filtering from the drive, closest to the claimed invention to achieve a technical result [2], adopted as a prototype. The known method is based on filling the drive bowl and the operation of the anti-filter screen on the bottom and sides of the bowl, as well as the device of water control wells around the drive. When implementing the method, the groundwater level in the external circuit is maintained above the groundwater level in the internal circuit by 1.0-1.5 m, and the groundwater level in the external circuit is raised ahead of as the height of the stacked drive body increases [3].

The disadvantage of this method is the unreliability of protection against harmful contamination of groundwater by industrial waste liquids and brines filtered by the drive due to the inability to regulate the level (volume) regime and the quality of stored contaminated liquids, brines, for example, bringing them to a technologically necessary state, regulating their water content , environmental stability and management of the chemical composition of contaminated liquids, brines within the drive bowl.

The technical result of the claimed invention is to increase the reliability of protection against groundwater pollution by brines and other industrial waste liquids hazardous to human life, increasing the possibility of environmental stability of formulations in the accumulator of liquid waste or “brines” and bringing them to the appropriate technologically stable state .

The specified technical result is achieved by the fact that in the method for preventing the filtration of contaminated highly mineralized industrial waste into the aquifer of groundwater, including maintaining the level of industrial waste within the contour of the anti-filter tank, in accordance with the claimed invention, the volumetric weight of highly mineralized industrial waste and the volumetric weight of the underground water, determine the distance from a given point in the formation to an arbitrarily selected area comparison bones determine the maximum allowable difference between the volumetric weights of water at a given point in the reservoir and an arbitrarily chosen comparison plane, and maintaining the level of highly mineralized industrial waste in the antifiltration tank is carried out below the natural level of the contour ground (ground) water, which is controlled by the magnitude of the “reduced” liquid pressure phases of industrial waste, and determined by the ratio

P _ave = hγ + z (γ + γ ₀₎ / 2,

wherein P _ave - the reduced pressure of the liquid phase of industrial wastes, ^M. L ^-1. T ^-2 ;

h is the hydrostatic height (level) of liquid industrial waste of a heterogeneous composition in the drive bowl, L;

z is the distance from a given point in the formation to an arbitrarily chosen comparison plane, L;

γ _0, and γ - volumetric weight of water at a given point and comparing the randomly selected plane ^M. L ^-2. T ^-2 .

The dimension of the equation (P) M L ^-1. T ^{-2 = hγ = hρg = (h} ) L (ρ) M. L ^-3 (g) ^L. T ^-2 = ^M. L ^-1. T ^-2 ;

the ratio of z (γ + γ ₀₎ / 2 also has a dimension ^M. L ^-1. T ^-2 . Thus, the entire equation above has a pressure dimension (http://megapaskal.ru/pribory/davlenie-pribor/82-sistema-edinic-davleniya.html)

In addition, the specified technical result is achieved by the fact that the reduced pressure of the liquid phase of industrial wastes is chosen below the level of underground (ground) water corresponding to the natural pressure, which is recorded by observation wells outside the antifiltration reservoir bowl.

In addition, the specified technical result is achieved by the fact that with a horizontal plane of comparison, the reduced pressure of the liquid phase of industrial waste is determined from the ratio:

P _ave = hγ

wherein P _ave - the reduced pressure liquid phase industrial waste, ^M. L ^-1. T ^-2 .

h is the hydrostatic height (level) of liquid industrial waste of a heterogeneous composition in the drive bowl, L;

γ - volumetric weight liquid industrial waste inhomogeneous composition at a given point drive cup, ^M. L ^-2. T ^-2 .

In addition, the specified technical result is achieved by the fact that in the antifiltration reservoir containing the cup, an antifiltration screen located on the bottom of the reservoir and the sides of the cup, and a water control system from water control wells, in accordance with the claimed invention, additionally, water distribution wells are installed inside the cup that are connected with a water control device and a horizontal pipe system.

In addition, this technical result is achieved by the fact that the antifiltration tank and water distribution wells connected to a water control device and a horizontal pipe system form a single system for maintaining the level regime of an environmentally hazardous liquid phase of contaminated highly mineralized industrial wastes and in the aquifer of groundwater.

In the present invention, thus, preventing the filtration of contaminated highly mineralized industrial waste into the aquifer of groundwater (ground) water is carried out by maintaining the reduced pressure of the industrial waste within the anti-filter storage circuit; in this case, the distance from a given point of the formation to an arbitrarily selected comparison plane is preliminarily determined. At the same time, the maximum allowable difference between them and the volumetric weight of water at a given point in the reservoir and at an arbitrarily chosen comparison plane are determined. It is important to achieve a technical result that the reduced pressure of highly mineralized industrial waste is kept below the corresponding natural pressure level of the underground (ground) water and its control over the “reduced” pressure of the liquid phase of industrial waste.

This "reduced" pressure of industrial waste is determined by the ratio [4]

P _ave = hγ + z (γ + γ ₀₎ / 2,

wherein P _ave - the reduced pressure of the liquid phase of industrial wastes, ^M. L ^-1. T ^-2 .

h is the hydrostatic height (level) of liquid industrial waste of a heterogeneous composition in the drive bowl, L;

z is the distance from a given point in the formation to an arbitrarily chosen comparison plane, L;

γ _0, and γ - volumetric weight of water at a given point and comparing the randomly selected plane ^M. L ^-2. T ^-2 .

For the effective implementation of the inventive method, the main condition is that the “reduced” pressure of the liquid phase of industrial waste is always lower than the corresponding natural pressure level of the circulating underground (ground) water, recorded in observation wells outside the bowl of the antifiltration reservoir. Moreover, when choosing a horizontal reference plane, the reduced pressure of the liquid phase of industrial waste is determined from the ratio:

P _ave = hγ,

wherein P _ave - the reduced pressure of the liquid phase of industrial wastes, ^M. L ^-1. T ^-2 ;

h is the hydrostatic height (level) of liquid industrial waste of a heterogeneous composition in the drive bowl, L;

γ - volumetric weight liquid industrial waste inhomogeneous composition at a given point drive cup, ^M. L ^-2. T ^-2 .

The drawing shows a diagram of an anti-filtration drive of different density, environmentally hazardous liquid industrial wastes located within the aquifer of groundwater. This diagram illustrates the organization of a unified system for maintaining the level regime and the optimal chemical composition of highly mineralized industrial waste in an environmentally hazardous liquid waste storage device. The diagram (Fig.) Presents: a bowl of an anti-filtration tank (1) of different density, environmentally hazardous industrial wastes located within the aquifer of groundwater; the sides of the drive bowl and an anti-filter screen protecting the aquifer of groundwater from the ingress of environmentally hazardous industrial waste from the anti-filtering drive (2); the bottom (3) of the bowl of the anti-filtration drive with sides 2; system of water control wells (4) located around the reservoir bowl; a system of water distribution wells (5) located inside the reservoir bowl; a system of horizontal pipes (6) connecting the systems of water control and water distribution wells; a system of observation (water-reducing) wells (7) located around the antifiltration reservoir bowl. In addition, in order to take into account in the claimed method the maximum possible influence of natural boundary conditions and characteristic features of the filtration area, in FIG. The diagram also presents: day surface (8); groundwater level (9); level (10) of different density, environmentally hazardous industrial wastes of the liquid phase within the bowl of the antifiltration tank; groundwater (ground) water horizon (11), within the limits of which there is an antifiltration accumulator of industrial liquid waste; water-resistant deposits (12), underlying the groundwater horizon.

The essence of the method, claimed as an invention, is to improve environmental safety and reliability of preventing the filtration of contaminated industrial waste into the aquifer of groundwater by taking into account specific environmental conditions and features of the designed anti-filter device-drive.

The reliability of the designed filtration drive will depend on how reasonably the boundary conditions and characteristic features of the filtration area are schematized and taken into account.

Determination of groundwater (ground) water reduction during the construction of the drive bowl is carried out on the basis of taking into account specific environmental conditions and the features of the designed structure. When schematizing natural conditions and justifying the reduction of groundwater (groundwater), it should be borne in mind that in the field of groundwater filtration, the distribution of the main hydrodynamic elements of the flow is determined by the initial and boundary conditions at its borders. Therefore, the accuracy of determining the lowering of groundwater (groundwater) depends on the justification of the schematization and consideration of the boundary conditions and characteristic features of the filtration area in the corresponding scheme.

The claimed invention was tested in the field.

As an example of determining the groundwater (groundwater) water reduction, taking into account the influence pattern of the designed antifiltration drive of different density, environmentally hazardous liquid industrial waste, we can consider the implementation of observation wells of the claimed method located within the aquifer of groundwater (ground) water (Fig.), In the quality of water-reducing, for example, according to the scheme of the "big well" as applied to the created antifiltration drive.

The number of interacting water-reducing wells in the conditions of quasi-steady motion, as well as the general decrease in the level of underground (ground) water at one point or another in the filtration area, for example, in the center of the designed tailing dump, is established on the basis of taking into account the level decreases from the action of each (separate) of the interacting wells, while the decrease in the underground (ground) aquifer (S _calc ) is determined by the formula (6):

S _calc (2H _e -S _calc ) = Q _e {lnR- (lnx ₁ x ₂ ... x _n ) / πk},

where N _e is the thickness of the aquifer of underground (ground) water, L;

k - a filter coefficient groundwater aquifer, ^L. T is ^-1 ;

x ₁ , x ₂ , ..., x _n - the distance from the center of the tailings to each of the interacting water-reducing wells, L;

R is the radius of influence (Z) of the water reduction according to the “big well” scheme as applied to the antifiltration drive, i.e. the distance between the point at which the decrease is determined and the contour, within which the thickness of the aquifer of the underground (ground) water remains equal to He,

Q _i - the total flow rate of all interacting water-reducing wells, located according to the scheme of the "big well" in relation to the antifiltration reservoir, L ³ T ^-1 .

Implementation of the claimed method is as follows (Figure 1). After bringing the anti-filter drive of different density, environmentally hazardous industrial wastes of the liquid phase within the aquifer of underground (ground) water (1) into working condition, it is filled with the liquid phase of environmentally hazardous industrial wastes. The liquid phase is fed through a system of water control wells located around the reservoir bowl (4), a system of water distribution wells located inside the reservoir bowl (5), as well as through a system of horizontal pipes connecting the systems of water control and water distribution wells (6). Monitoring the position of the liquid phase level in the antifiltration reservoir is carried out using a system of observation (water-reducing) wells located around the antifiltration reservoir bowl (7);

Upon reaching the absolute level of the level of different density, environmentally hazardous liquid industrial wastes, corresponding to the calculated value of their “reduced” pressure, their supply to the storage bowl stops.

As an anti-filtration method of protection, the deepening of the reservoir bowl is proposed below the groundwater level. Using the proposed method of antifiltration protection is used simultaneously with the creation of an antifiltration screen. When filling the storage cup with liquid waste through water distribution wells (5) located inside the storage cup, groundwater can be supplied / unloaded into the storage cup within the height determined by the equation h = P / ρg = P / γ, where P is the hydrostatic pressure at points corresponding to the position of the leveled surface of groundwater beyond the tailing contour:

ρ - fluid density (groundwater), ^M. L- ³ ;

g - acceleration of gravity, ^L. T ^-2 ;

γ - volumetric weight of water, ^M. L ^-2. T ^-2 .

The number of water distribution wells (5) placed inside the reservoir bowl is determined by the reliability of the estimate of the average value of the hydrochemical parameter of the liquid waste, which has a certain variation relative to the average size of the tailings, and is calculated by the known ratio [5]:

N = (T _{N, a} -V _{ar / Δ} ) ² ,

where T _{N, a} is the critical value of the student criterion;

Var - limit values of the coefficients of variation;

Δ is the estimation error specified by the researcher.

In the above expression, in addition to the variation, the error Δ specified by the researcher and the critical value of Student's criterion T _{N, a} are included. At limit values of the coefficient of variation Var <5%, depending on the accuracy of the estimate Δ = 10%, and a confidence probability of a = 0.05, the number of wells (tests) necessary to fix the variability of the chemical composition of the liquid phase should be at least N = 10.

The use of a multi-density, environmentally hazardous liquid industrial waste buried below groundwater level (groundwater) can be considered as an effective measure to combat the infiltration of working brines deep into aquifers.

At the same time, the task of maintaining the optimal quality composition (water content) of working brines in the tailing dump bowl itself can be solved using specially equipped wells, from which liquid industrial waste or groundwater will be unloaded into the reservoir, creating the optimal optimal hydrochemical regime in it.

It is known that to prevent the possibility of penetration of different density, environmentally hazardous liquid wastes from filtration devices (reservoirs) into the aquifer underlying it, the level of underground (ground) water must necessarily be higher than the liquid phase (waste) in the reservoir itself.

In this case, the practice of reduced ”pressures is used in practice (ie, the ratio P> P _ol should always be maintained.

Moreover, based on generally accepted provisions in hydraulic engineering, the volumetric weight (γ) of a liquid (i.e., the weight of a liquid contained in a unit volume) and the density (ρ) of a liquid (i.e., in this case, is the mass of liquid, contained in a unit volume) are interconnected by the relation γ = ρ g, where g = 981 cm / s ² .

The product hρg, in accordance with the generally accepted definition, corresponds to the weight pressure p _weight , which is determined by the weight of the liquid itself. Thus, the total or absolute hydrostatic pressure is equal to the sum of the external and weight pressures. At the same time, in practice, they often use not the full hydrostatic pressure p, but only its excess above atmospheric pressure p _atm . This excess or gauge pressure p _{man is} found from the relation: p _man = p-p _atm = p _atm + hρg-p _atm

In the particular case, when the external pressure is equal to atmospheric, for example, in open reservoirs, the gauge pressure in the liquid is equal to the weight: p _man = p _weight = hρg. Traditionally, in practice gauge pressure is denoted by “p”.

The ratio of hydrostatic pressure to the bulk density “pg” of the liquid has a linear dimension. In the case of underground non-pressure (ground) water, it is called the hydrostatic pressure height and is used to measure pressure and characterizes it as a level surface.

Based on this, h = p / ρg, where p is any pressure (absolute, excess or weight), which corresponds to a certain level of groundwater, while the pressure will be p = hρg.

As an example, it can be noted that a pressure of 1 kgf / cm ² (technical atmosphere) corresponds to a column of fresh water with a height determined from the ratio: p / ρ _in g = p / γ _in = 1 / 0.001 = 1000 cm = 10 m.

Hence, the position of the surface level of the underground (ground) in the aquifers can be determined not so much by their movement as by the difference in their bulk weight, taking into account the depth of the horizon.

To exclude the influence of these factors when determining the direction of movement of natural waters, not natural levels are used, but reduced groundwater pressures. Only the differential pressure drop can serve as an indicator of the direction of movement of underground pressure water.

To determine the reduced pressure, any horizontal reference plane is chosen arbitrarily (it is also called the “reduction plane”), with respect to which the pressure of all wells is determined.

The reduced pressure consists of two components:

1) reservoir pressure at a given point in the reservoir;

2) the pressure created by the column of water, from a given point in the reservoir to an arbitrarily chosen reference plane.

In practice, reservoir pressure is measured by pressure gauges, but it can also be determined by the value of the static water level in the well.

The second component depends on the depth of the formation and on the change in the volumetric weight of water contained in the rocks, from a given point in the formation to an arbitrarily chosen reference plane.

This value is determined only by calculation in accordance with the known (or conditionally accepted) dependence of the volumetric weight (γ) or water density (ρ) on depth, as a function of f (z).

In the general case, when the volumetric weight of water in a vertical section changes gradually and the reference plane is located below the point z _{i of} formation pressure measurement, the reduced pressure is determined by the following ratio:

P _ave = hγ + z (γ + γ ₀₎ / 2,

wherein P _ave - the reduced pressure of the liquid phase of industrial wastes, ^M. L ^-1. T ^-2 .

h is the hydrostatic height (level) of liquid industrial waste of a heterogeneous composition in the drive bowl, L;

z is the distance from a given point in the formation to an arbitrarily chosen comparison plane, L;

γ _0, and γ - volumetric weight of water at a given point and comparing the randomly selected plane ^M. L ^-2. T ^-2 .

It should be borne in mind that when comparing the horizontal plane, the value of the value z is equal to 0. Then, the equation P _ave = hγ + z (γ + γ ₀₎ / 2,

becomes P _ave = hγ.

The surface level of the water level in the reservoir (tailing dump) is usually horizontal, however, the density of the liquid phase stored in it can significantly differ (up) from the volumetric weight of groundwater distributed outside it. Therefore, in order to prevent the possibility of penetration from the tailings pond of different density, environmentally hazardous liquid wastes into the aquifer underlying it, the level of groundwater (ground) water (9) in this aquifer h must be necessarily higher than the level corresponding to the given pressure (P _ol ) different density, environmentally hazardous liquid phase (waste) in the tailing dump (1). Adjustment of the position of the level of different density, environmentally hazardous liquid wastes (10) relative to the level of underground (ground) water (9) is carried out using a system of water control wells (4) located around the reservoir bowl (1) and a system of water distribution wells (5) located inside the bowl drive (1) connected by a system of horizontal pipes (6). The system of observation (water-lowering) wells (7) located also around the reservoir bowl (1) is designed to monitor the position of the underground (ground) water level (9), outside the reservoir thicket (1) of different density, environmentally hazardous liquid wastes.

In addition, the system of water-regulating and water-distributing wells makes it possible to feed weakly mineralized into the reservoir bowl (tailing dump) and, thereby, regulate not only the level, but also the chemical composition of the different density, environmentally hazardous liquid phase (waste) directly in the reservoir itself.

The implementation of the claimed method is also carried out by the design of an anti-filtration storage ring, which contains water-regulating wells (4) located around the bowl (1) and water distribution wells (5) located inside the storage bowl, using the connecting system of horizontal pipes (6) used as a system with the help of which the “reduced” pressure (10) and the quality of different density, environmentally hazardous liquid phases (waste) in the drive bowl (1) are regulated, while being installed in the drive bowl (1) the even “reduced” pressure of the liquid phase (waste) (10) must not exceed the absolute mark corresponding to the natural pressure of the underground (ground) water level (9), recorded by observation (water-reducing) wells (7) outside the reservoir bowl (1).

The claimed method is intended to reduce the degree of infiltration of liquid production wastes, brines from tailing dumps into the aquifers underlying them and allows protecting underground (ground) water from pollution.

The claimed method can also be used to prevent infiltration through the thickness of stored solid waste of atmospheric precipitation accumulating in the pore space of landfill masses at solid waste landfills in the liquid phase, which, in turn, also helps to protect underground aquifers from pollution.

Distinctive from known analogues and attractive to achieve a technical result, the feature of the claimed method is the separation of systems that determine the maintenance of the optimal level and quality regimes, groundwater in the aquifer, liquid production waste, brines in the pool (tailing dump). So, if compliance with the level regime, both in the aquifer and in the reservoir, is responsible for the wells used to lower groundwater while deepening the pool (tailings), then for maintaining the optimal quality (water content) of liquid production wastes, working brines in bowl accumulator, specially equipped contour and intercontour wells are used.

Information Sources Used

1. RF patent No. 2408442 (RU).

2. RF patent No. 2068048 (RU).

3. RF patent No. 2392375 (RU) - prototype.

4. Silin-Bekchurin A.I. Groundwater dynamics. M., 1965

5. Ayvazyan S.A. et al. Applied statistics: the basics of modeling and primary data processing. - M.: Finance and Statistics, 1983.

Claims (7)

1. A method of preventing the filtration of contaminated highly mineralized industrial wastes into the aquifer of groundwater, including maintaining the level of industrial wastes within the contour of the seepage filter, characterized in that the density of highly mineralized industrial wastes and the density of the underground groundwater are preliminarily determined, and the distance from a given point of the formation to an arbitrary value is determined the selected comparison plane, determine the maximum allowable difference between them and the density water at a given point in the reservoir and an arbitrarily chosen comparison plane, maintaining the level of highly mineralized industrial waste in the antifiltration tank is carried out below the natural level of the underground (ground) water, which is controlled by the magnitude of the “reduced” pressure of the liquid phase of industrial waste and is determined by the ratio
P _ave = hγ + z (γ + γ ₀₎ / 2,
where R _CR - reduced pressure of the liquid phase of industrial waste, M · L ^-1 · T ^-2 ;
h is the hydrostatic height (level) of liquid industrial waste of a heterogeneous composition in the drive bowl, L;
z is the distance from a given point in the formation to an arbitrarily chosen comparison plane, L;
γ and γ ₀ - volumetric weight of water at a given point and on an arbitrarily chosen comparison plane, M · L ^-2 · T ^-2 . 2. The method according to claim 1, characterized in that the reduced pressure of the liquid phase of industrial waste is selected below the corresponding natural pressure of the underground (ground) water level recorded by observation wells outside the antifiltration reservoir bowl. 3. A method according to claim 1, characterized in that the horizontal plane comparison reduced pressure industrial waste liquid phase is determined from the relation P _ave = hγ. 4. An antifiltration accumulator for implementing the method according to claim 1, comprising a cup, an antifiltration screen located on the bottom of the accumulator and the sides of the cup, and a water control system of water control wells, characterized in that water distribution wells are additionally installed inside the bowl, which are connected to the water control device and horizontal pipe system. 5. The antifiltration tank according to claim 4, characterized in that the water distribution wells connected to the water control device and the horizontal pipe system form a single system for maintaining the level regime of an environmentally hazardous liquid phase of contaminated highly mineralized industrial waste into the aquifer of groundwater. 6. The antifiltration accumulator according to claim 5, characterized in that the reduced pressure of the liquid phase of industrial waste in the antifiltration accumulator bowl is lower than the level corresponding to the natural pressure of the underground (ground) water. 7. The antifiltration accumulator according to claim 5, characterized in that, for a horizontal reference plane, the reduced pressure of the liquid phase of industrial waste in the antifiltration accumulator bowl is maintained from the ratio P _pr = hγ.