CS215462B1 - Method of groundwater treatment in situ - Google Patents

Abstract

The invention solves the problem of qualitative pretreatment | of groundwater extracted in situ in a rock environment, while solving some disadvantages and shortcomings of existing water treatment methods for groundwater with respect to the requirements of the drinking water standard. The invention uses natural chemical and biochemical processes in the aquifer in the area of the so-called "reactor zone" of the extraction facility. By applying the theory of operation control of chemical flow-through reactors, it creates conditions for controlling the process of pretreatment of the qualitative composition of the extracted groundwater. Based on the verification of the dependence of the output concentration of the pretreated groundwater component on the pumped amount of water from the facility, the hydraulic characteristics of the rock layer around the facility and the knowledge of the movement of the reactor zone inlet surface in its vicinity, it controls and optimizes the operation of the natural reactor. The entire process is controlled by adjusting the residence time of groundwater in the reactor zone around the collection facility, selecting the optimal amount of groundwater collected from the facility, changing the hydraulic properties of the rock layer leading the groundwater to the collection facility, or changing or selecting the technical equipment and layout of the collection facility.

Description

The invention solves the problem of qualitative pretreatment collected groundwater in situ in the rock environment, while addressing some of the disadvantages and drawbacks of existing water treatment methods for groundwater treatment with regard to the requirements of the drinking water standard. The present invention utilizes natural chemical and biochemical processes in the water-bearing layer in the region of t. "Reactor zones" of the collecting facility. Application of the theory of operation of chemical through-flow reactors creates conditions for control of the pre-treatment process of the qualitative composition of the collected groundwater. Based on the verification of the dependence of the output concentration of the pre-treated groundwater component on the pumped amount of water from the building, hydraulic characteristics of the rock layer in the surroundings of the building and knowledge of movement of the inlet area of the reactor zone. The whole process is controlled by adjusting the residence time of the groundwater in the reactor zone in the vicinity of the collecting facility, by selecting the optimum amount of collecting groundwater from the facility, by changing the hydraulic properties of the rock layer leading the groundwater to the collecting facility. the choice of technical equipment and equipment of the collection facility.

The invention relates to a method of treating groundwater in situ. The invention solves an effective method of treating the qualitative composition of groundwater, especially soluble substances such as NO ₃ ^- , Fe ³⁺ , Mn ²⁺ and others including microbiological recovery of groundwater without the use of chemical or other substances affecting the course of chemical and biochemical reactions directly in the rock a layer leading water to the receiving object.

Groundwater is the most important and main source of drinking and service water for the population. A significant part of groundwater is often of unsatisfactory quality in terms of the requirements of ČSN 83 0611 “Drinking water”, especially the content of NO ₃ ions, iron, manganese and others, including microbiological recovery. Therefore, these waters often require technological treatment, which is carried out in an investment and energy intensive manner in water treatment plants. At the same time as the population increases and their standard of living increases, so does the need for water. However, the increase and intensification of industrial and especially agricultural production brings with it an increase in the negative impact on the quality of groundwater even under the legal regulations and regulations. This leads to an increase in the demands and needs for the treatment of groundwater, and some of these substances, such as nitrates, are often not removable by conventional technological processes or are eliminated by high-cost processes. The technological methods of groundwater treatment used so far are extremely expensive in terms of investment, operation and energy.

The above mentioned drawbacks and disadvantages of the existing water treatment methods of groundwater treatment with regard to the requirements of ČSN 83 0611 solve the method of groundwater treatment in situ according to the invention, whose essence lies in the fact that treatment of chemical and microbiological composition of collected water is carried out in of the receiving object, wherein the course of treatment is governed by the selection of the optimum value of the collected amount of water from the object or / and the filtration coefficient and effective porosity of the rock layer leading water to the receiving object and / or the technical equipment and equipment of the receiving object. BRIEF DESCRIPTION OF THE DRAWINGS The invention is illustrated by the accompanying drawings, in which FIG. the course of concentrations over time is drawn and Fig. 2 shows the types of dependence of the component also on time.

The advantage is that natural, chemical, microbiological and biochemical processes are utilized in the water-bearing layer in the vicinity of the groundwater collection facility, which it manages and optimizes directly in the collection facility using a groundwater collection device. It is based on the differences in the chemical composition of groundwater in the rock environment and in the collecting structure, which is caused by the differences in determining thermodynamic factors (oxidation-reduction potential Eh, hydrogen ion concentration pH, partial pressure of carbon dioxide P _C o ₂ ). . The rock environment in the vicinity of the collecting facility acts as a chemical and biochemical flow reactor. It is also a continuous cultivator for microorganisms. Ongoing chemical and biochemical processes cause, in consequence, fouling of the rock environment in the vicinity of the collecting structure, the well is aging. The residence time in this reactor, ie in our case in the rock surroundings of the collecting facility where the chemical reactions take place, determines the time during which the reactions affecting the resulting chemical composition of the groundwater taken from the building take place.

The reactions in the water-rock-gas-biomass system aim to create an equilibrium state, which is determined by the relationship with the surface atmosphere in the well or in the receiving object. The porous environment of the rock layer in the vicinity of the borehole saturated with groundwater corresponds to a flow system with a very slow flow rate at which the starting substances are continuously; they are fed to the inlet (inlet to the reactor - imaginary cylindrical surface in the vicinity of the borehole, the so-called borehole reactor zone) and at the same time at the outlet (the actual receiving object) we get a mixture of output products. The conversion in the reactors is given by the fraction c _t i / c _{o i} is the concentration of the component i at the entry into the i reactor zone around the well b and c _(i is the concentration of the same component at the exit - the receiving object). :

(«ΛΑ + (c _{t> i} / c _{o> i} ) -1 = 0 where R; - rate of chemical reaction in unit of volume.

The resulting concentration of the component i undergoing reaction in the depressive cone of the receiving object decreases very rapidly as the radius of depression progressively widens. However, practical verifications have shown that not only is there a decrease but also an increase or stagnation in the concentrations of the reactants. Schematic diagrams of concentration changes with time in pumped wells at a constant pumped amount Q (groundwater level reduction is a function of pumping time) are shown in Fig. 1. Movement of chemical reaction point (imaginary input reactor surface) caused by differences in well conditions in the rock environment it is slower than the movement of the edge of the depression cone away from the borehole.

The development of concentrations over time in the pumped well corresponds to the dependence shown in Fig. 1.2. The movement of the starting point (area) is relatively slow, as practical experience has shown. The observed change in concentrations is based on the dependence:

log c _{t> i} = A. log t _č + B t _č - pumping time A, B - constants

This means that the course of time, reactions increases or decreases logarithmically, and hence the speed of movement of the starting point (area) from or to the well changes logarithmically.

Suppose now that for the depression radius of the collecting object R, the following applies:

R> R _r > r _s r _s - radius of the collecting object

R _r - reactor zone radius

i.e., the reactor inlet surface (reactor zone) has a radius smaller than that of the receiving object. Furthermore, we can assume that the value of R _r can have limit values

1. R _r = const. (curve 2 in Fig. 1)

2. lim ^. ^ R _r - »R (curve 1 in Fig. 1)

3. lim ^ R _r -> r _s (curve No. 3 in Fig. 1) »i

Let us first consider the case ad 1) (constant radius of the input surface). We start from the hydraulic characteristics of the reactor with non-ideal flow. In the first pumping phase, the conversion of the reactor is reduced due to the reduction of the residence time in the reactor. At the moment when the depression cone goes to a distance greater than R _r , the rate of descent even at the point R _r from that moment is the same as the speed and descent in the pumped well. That means the slope and groundwater level to the borehole is constant from this point and when pumping Q = const. the residence time in such a reactor is also constant. The time course of development of concentrations in the collecting object is as follows: this is given by the envelope of gradual concentration distributions, which is represented by a straight line and parallel to the time axis. The conversion rate is constant, the stationary state of the reactor is established, the output product concentration is invariant over time (Fig. 2a). The distance R _r is determined by the magnitude of the depression radius R at the time the onset of the output concentration is linearly dependent on time.

Case ad 2) (increasing R _r with time):

At the time of pumping, the reactor inlet surface is moving away from the well. This increases the residence time in the reactor, resulting in increased conversion with time. The rate of increase of the radius R _r can be at most equal to the increase of the radius j of depression. The course of concentrations (increasing conversion) is shown in Fig. 2b. The inflection point of the enveloping curve in this Fig. 2b indicates the radius of the zone of influence of the aquifer by an undrawn well.

Case ad 3) (decreasing R _r with time):

The reactor inlet area approaches the well. Theoretically, in such a case, after a certain time, we should get water of the same composition in the well as in the rock environment. However, we have to realize that the closer we get to the reactor inlet surface, the more the reaction rate increases. Therefore:

linv ·. E _m 0 where E _m is a conversion. The course of concentrations with the pumping time I is shown in Fig. 2c. The inflection point of the curve c _t i = f (t _no ) again determines the range of influence by the unpumped borehole.

All the above conclusions are valid provided there are no changes in the groundwater composition at the entrance to the well zone. If these changes occur, these modifications will be reflected in the type curves shown in Figure 2c after a period corresponding to the groundwater passage time from the reactor inlet area to the well.

Experimental measurements have shown that the velocity of movement of the starting point (area) of reactions modifies these dependencies in bilogarithmic expression to lines, ie transformations to the type of log - log dependence occur.

The method of groundwater treatment according to the invention is solved by water treatment technology in an efficient, low-cost and energy-efficient way, based on verification of the dependence of output concentrations of the component in the receiving object on the pumped amount and water, hydraulic characteristics of rock; and the knowledge of the movement of the reactor zone inlet around the building controls the operation of the existing natural reactor and optimizes its function.

[The control of the whole process is carried out with regard to the fact that they are continuous flow systems, by adjusting the residence time of the groundwater in the reactor zone around the receiving object, i.e. by adjusting the reaction time. It uses the natural biochemical and chemical processes leading to degradation in particular ^_ NO _3, Fe ^2+, Fe ^3+, Mn ^2+, and further including a reduction in total microorganisms. Adjustment of reaction time is caused by:

a) by selecting the optimum amount of groundwater collected from the building through a sampling device,

b) changing the hydraulic characteristics of the rock layer leading the water to the collecting object (filtration coefficient, effective porosity) using regeneration methods.

It can also be influenced by selecting (for new) or. by changing the technical equipment and equipment of the collection facility.

Ongoing chemical and biochemical reactions spo- ¹ gether with microbiological recovery loss cause unwanted substances from ground water in the soil environment, thereby speeding up the processes colmatage receiving object. Indeed, the essence of the groundwater treatment method according to the invention is the intentional acceleration of the colmatation processes, leading to an improvement in the quality parameters of the groundwater obtained. After reaching a certain limit of perpendicularity, it is necessary to cyclically adjust the hydraulic properties of the rock layer in the vicinity of the collecting object (see adjustment of reaction time using regeneration methods). The length of individual cycles depends on the intensity of the induced chemical and biochemical processes in the vicinity of the collecting structure, on the rate of reactor conversion and is usually 2–3 years.

Example

As an example of the application of the invention, we present a solution for the treatment of the iron content of the moving groundwater. Before using the solution according to the invention, the iron content of the collected water at a pumped amount of Q = 3 s ^{-1 was} 3 mg Fe.l ^-1 . By adjusting the values of the filtration coefficients in the vicinity of the borehole, the iron content of the collected water was reduced to 1 mg Fe.l ^-1 at the same pumped amount using the optimization solution according to the invention.

Claims (1)

SUBJECT A method for the treatment of in situ groundwater, in particular groundwater containing nitrate, ferrous, ferric and manganese ions, including the microbiological recovery of groundwater, characterized in that the chemical and microbiological composition of the collected water is treated in a water-bearing rock layer in the vicinity of the receiving object. In another case, the nitrate ion content in the collected groundwater varied from 90 to 110 mg ΝΟ ^ .Γ ¹ . By changing the amount of water collected from the building and adjusting the values of the filtration coefficients, the content of nitrate ions in the collected water decreased to values of 49–60 mg NO ₃ ^- .l ^-1 . BACKGROUND OF THE INVENTION the course of treatment is governed by the selection of the optimum value of the water collection rate from the object or / and the filtration coefficients and the effective porosity of the rock layer leading the water collection object and / or the technical equipment and equipment of the collection object.