RU2296016C1 - Polluted land detoxification method - Google Patents

Abstract

FIELD: environmental protection.

SUBSTANCE: invention concerns lands polluted with various organic and inorganic pollutants such as heavy metals, petroleum products an the like, and can be used for detoxification of various-type lands, e.g. in cases of man-caused pollution of lands, sewage disposal plant sediments etc. containing various types of pollutants in different concentrations. Method is implemented by adding glauconite-containing sorbent to land until specified concentration of polluting substance in the land is achieved. Prior to addition of sorbent, type of pollutant and its concentration K₀ in polluted land sample is determined, after which concentrations K₁, K₂, K₃, and K₄ of polluting substance are measured for land-to-sorbent ratios 1:1, 1:2, 1:3, and 1:4, respectively, after which mass m_s of the sorbent required to be mixed with land polluted with preliminarily determined pollutant in concentration K₀ is determined to achieve desired concentration of pollutant K₃ in terms of following equation: ms = m_L*K₁/[K₃*(K₀/K₁ + K₁/K₂ + K₂/K₃ + K₃/K₄)₄], where m_L is mass of land polluted with preliminarily determined pollutant in concentration K₀, and thereafter polluted land is moistened and calculated mass of sorbent is spread across the surface of polluted land while simultaneously being mixed with polluted land.

EFFECT: increased accuracy in determining mass of sorbent required and sufficient to achieve required norms of concentration of polluting substance in ground and so to reduce consumption of the sorbent.

5 cl, 3 ex

Description

The invention relates to the cleaning of the environment, in particular soil contaminated with various organic and inorganic pollutants (heavy metals, petroleum products, etc.), and can be used to detoxify various types of soils (technologically contaminated soil, sediment treatment plants (OOS) and etc.) containing various types of pollutants with different concentrations.

There is a method of sorption extraction of thorium from soil, natural and industrial waters, which consists in the fact that thorium is extracted using a porous composite material including vermiculite, activated carbon, glauconite, dextrin with an equal ratio of components (RF patent for the invention No. 2166216, IPC G 21 F 09/12, published on April 27, 2001).

There is also a method of sorption extraction of thorium from soil, natural and technological waters, which consists in the fact that thorium is extracted using a porous composite material including vermiculite, activated carbon, glauconite, dextrin, characterized in that the composite material additionally contains perlite filter powder equal ratio of components (RF patent for the invention No. 2212068, IPC G 21 F 09/12, publ. 09/10/2003).

Common disadvantages of the known methods is the lack of calculation of the required amount of sorbent to bring the residual concentration of pollutants to the level of the required concentration, for example, the normative maximum permissible concentration (MPC), which in turn negatively affects the economic side of the issue, since the sorbent must be moved to the processed object , and this includes transport costs and the cost of the sorbent itself. Moreover, if after treatment with the sorbent the level of the required concentration of the object is not achieved, then this treatment is ineffective.

The closest technical solution is a known method of purifying water in a natural reservoir contaminated with radioactive isotopes by introducing a natural sorbent onto the surface of the reservoir. At the same time, glauconite sand is used as the sorbent, which is introduced during the freezing period. Then, in a subsequent period of ice formation, the surface of the reservoir is covered with a layer of clay, repeating these operations until the degree of water purification in the reservoir of the appropriate concentration is achieved. During ice-freezing, a layer of 30-50 cm of glauconite sand is applied to the surface of a reservoir contaminated with radioactive isotopes (for example, strontium 90, strontium 89, cesium 137, etc.). During ice melting, glauconite sand falls to the bottom of the reservoir and, by means of an ion-exchange mechanism and sorption, extracts radionuclides from the soil of the reservoir (silt) and water. In the subsequent period of freeze-up, a clay layer of 50-70 cm is similarly applied to the surface of the reservoir, and it, in turn, sinking to the bottom of the reservoir, closes the layer of glauconite sand with radionuclides extracted into it. In subsequent years, if necessary (after analyzing the water for the presence of radionuclides in it), these operations are repeated until the degree of water purification in the reservoir is achieved, corresponding to the concentration (see RF patent for invention No. 2203511, IPC G 21 F 09/12, C 02 F 01/28, E 02 B 15/00, publ. 04/27/2003).

In this technical solution, it is indicated that if the reservoir is contaminated, it is necessary to purify both the water and the soil (silt) of the reservoir as a place of accumulation of radionuclides. However, the disadvantage of this method is the lack of an accurate calculation of the mass of the sorbent necessary for introduction into a polluted environment (water and soil of a reservoir). After the first stage of applying the sorbent, two options are possible:

- the contaminated environment is not sufficiently disinfected and it is necessary to repeat the treatment after a long period of time (until the next freeze-up), which entails additional costs for transporting the sorbent to the site of infection and loss of time;

- in a polluted environment, the concentration of radionuclides has reached the desired concentration, but it is impossible to determine the exact amount of sorbent to achieve the goal. Perhaps, it would be necessary to scatter a layer of glauconite not 50 cm, but, for example, 35 cm. This would lead to significant savings in the sorbent and achievement of the goal. Such uncertainty always arises when applying the above method, when it is necessary to perform the final (until the desired concentration of pollutants is reached) purification of the contaminated medium with glauconite.

The objective of the present invention is to provide a method of detoxification of contaminated soil, ensuring optimal sorbent consumption, which results in a predetermined residual concentration of pollutants, while saving energy and raw materials.

The technical result achieved in solving this problem is to increase the accuracy of determining the mass of the sorbent, necessary and sufficient to achieve the required standards for the concentration of pollutant in the soil while reducing the consumption of sorbent.

The specified technical result is achieved by the fact that in the method of detoxification of contaminated soil by introducing a natural sorbent into it until a predetermined concentration of a pollutant in the soil is achieved, while a glauconite-containing substance is used as a sorbent, according to the invention, the type of pollutant and its concentration are determined before the sorbent is introduced into the soil To ₀ in a sample of contaminated soil, then measure the concentrations of K ₁ , K ₂ , K ₃ , and K ₄ , a pollutant when mixing samples of contaminated soil nta with the sorbent, respectively, in the proportions of the soil: sorbent - 1: 1, 1: 2, 1: 3, 1: 4, after which the mass m _{c of the} sorbent necessary for mixing with soil contaminated with a previously determined contaminant with a concentration of K _{0 is} determined, and the achievement in the soil of a given concentration of a pollutant K _s , based on the following ratio

m _c = m _gr · K ₁ / [K _s · (K ₀ / K ₁ + K ₁ / K ₂ + K ₂ / K ₃ + K ₃ / K ₄ ) / 4]

where m _gr is the mass of soil contaminated with a previously determined pollutant with a concentration of K ₀ ,

moisten the contaminated soil, then distribute the calculated mass of the sorbent over the surface of the contaminated soil while mixing the sorbent with the contaminated soil.

It is advisable that the contaminated soil is moistened before it reaches a moisture content of at least 80%.

In addition, before applying the sorbent to the soil by examining samples of the surface of the contaminated soil for the content of the pollutant, areas with different concentrations of the pollutant exceeding a given concentration are determined.

Before processing contaminated soil, it is advisable to grind the sorbent with subsequent separation of the working fraction with a particle size of 0.01-0.1 mm, and treat the contaminated soil with a sorbent at a positive ambient temperature.

As glauconite-containing substance, you can use both natural glauconite sand, and enriched glauconite sand (concentrate) or prepared glauconite clay. Moreover, the smaller the fraction and the greater the content of glauconite in the sorbent, the smaller its amount will be needed for soil treatment.

Carrying out preliminary instrumental measurements of control samples to determine the prevailing type of pollutant and its initial concentration, usually measured in mg / kg, is necessary to unambiguously establish (set) the required residual concentration of this substance in the soil after cleaning and the total amount of sorbent necessary for soil cleaning. In this case, the specified concentration can be both a normatively determined value, for example, the maximum permissible concentration (MPC), and a value determined by the initiator of cleaning, for example, the customer for such work, and possibly different from the MPC both up and down , which may be associated with a certain subsequent use of purified soil, for example, as a storage area (dump) of pollutants (where it is necessary to maintain one level of concentration of pollutants), or ak crop area (where the level of pollutants must be very minimal).

Measurement of concentrations of soil samples when mixed with a sorbent in 1: 1 proportions; 1: 2; 1: 3; 1: 4, i.e. for example, when 1 kg of soil is mixed with 1 kg of sorbent (glauconite-containing substance); 1 kg of soil is mixed with 2 kg of sorbent, etc., due to the following. It was experimentally found that when mixing contaminated soil with a sorbent, there is no linear relationship between changes in the concentration of a pollutant in the soil and the mass ratios of the sorbent and soil with respect to each other. With a general increase in soil mass by a factor of 2, when mixing 1 part of soil and 1 part of a glauconite-containing substance, the concentration of a pollutant in the resulting mixture will not be 2 times less than the initial concentration of a pollutant before mixing with a glauconite-containing substance. So, from field experiments it was found that with an initial concentration of nickel in the soil of 28 mg / kg and mixing 1 kg of such soil with 1 kg of sorbent mixing 1: 1, the mass of the sample increases by 2 times, the concentration of nickel in the soil decreases to 18 mg / kg, i.e. 1.6 times. When mixing 1 kg of soil with a nickel concentration in it of 28 mg / kg with 2 kg of sorbent, i.e. mixing 1: 2, the mass of the sample increases 3 times - the concentration of nickel in the resulting mixture is 8.2 mg / kg and will decrease 3.4 times.

Measurement of concentrations of soil samples when mixed with a sorbent in the proportions of 1: 1; 1: 2; 1: 3; 1: 4 allows you to take into account the nature of the manifestation of the sorption abilities of the sorbent in each particular case and calculate the exact mass of the sorbent necessary for disinfecting the soil to the required predetermined concentration of the pollutant. Obtaining the exact estimated mass of the sorbent will allow you to plan the delivery of just such an amount of sorbent to the place of contamination that is necessary and sufficient to achieve the required (necessary) level of concentration of the pollutant in the soil, making optimal use of material, human and technical resources.

Glauconite-containing substance, for example glauconite sand, glauconite clay, extracted, for example, in different deposits, differ in the concentration of glauconite (active sorbing substance) from each other, and accordingly, they will affect the contaminated soil purely individually. Carrying out such measurements with a mixture of contaminated soil in various proportions with the sorbent allows you to take into account these individual abilities of the sorbent in each case.

It should also be noted that glauconite is most efficiently applied to moistened soil, for example, to a moisture content of 80%, and mixed with it, which will make it possible to optimally use the features of the ion-exchange mechanism of the adsorption and desorption properties of the sorbent, which is used as glauconite sand, while also saving energy and raw materials, in particular by reducing the consumption of green earth.

Before applying the sorbent to the soil, it is possible to determine areas with different concentrations of the pollutant by examining samples of the surface of the contaminated soil for the content of the pollutant and compiling a map of the concentrations of pollutants. This is due to the uneven contamination of the soil with a contaminant (its various concentration) due to a number of factors, for example, soil moisture, its structure, etc.

Such events are not strictly required, since, for example, at a number of enterprises that have wastes enriched with heavy metals and regularly deposit these substances into the soil, such maps are constantly maintained and updated. However, as the proposed method requires, before the introduction of a glauconite-containing substance into the soil for the efficiency and accuracy of the calculation of the sorbent mass necessary for disinfecting the soil and the subsequent verification of the achievement of the required predetermined concentration, in all cases it is necessary to check the type and initial concentration of the pollutant.

Grinding of glauconite-containing substance, for example glauconite sand, which is carried out using any known device, is necessary because glauconite sand contains a complex potassium-containing sheet-like aluminosilicate - glauconite, i.e. a multicomponent mixture containing minerals with varying degrees of crystallization. Preliminary preparation, i.e. grinding of the sorbent (glauconite sand) with subsequent separation of the working fraction with a particle size of 0.01-0.1 mm and its use at a positive temperature can improve the quality of the sorbent by increasing the contact surface, increasing the speed (activation, intensity) of ion-exchange processes, strengthening it adsorption and desorption properties, and, accordingly, reduce the detoxification time (processing time) of the contaminated medium to the required predetermined concentration.

In addition, grinding of glauconite allows to increase the sorption surface, moistening and mixing promotes better contact of heavy metals and oil products with the sorbent, reducing intermolecular distances, and in this case the exchange of charged particles of ions and cations occurs with a higher probability.

Thus, the set of essential features of the independent claim makes it possible to calculate the necessary mass of the sorbent for detoxification of soil contamination, at which the residual concentration of heavy metals, oil products reaches the required level, for example, does not exceed the MPC standards, and it is optimal to use the features of the ion-exchange mechanism of the adsorption and desorption properties of the sorbent, which uses glauconite sand, while saving energy and raw materials .

Under technogenic pollution in the framework of the present description refers to pollution obtained as a result of the application of technology and other human activities, which produce side pollutants that are harmful to humans and the environment.

Under a given concentration of a pollutant is meant the value of the concentration of a pollutant in the soil, which must be achieved after cleaning the soil.

The claimed method is implemented as follows.

Before introducing the sorbent (glauconite) into the soil, control measurements are carried out to determine the type of pollutants and their concentrations. To determine the boundaries of the contaminated soil site and the depth of the pollutants, the concentrations of which exceed a predetermined level, wells are drilled and sampled according to the RF Ministry of Natural Resources. Methodological recommendations ″ Sampling of soils, soils, sediments of biological treatment facilities, industrial sewage sludge, artificially created bottom sediments reservoirs, storage ponds and hydraulic structures ″ PNDF 12.1: 2: 2.2: 2.3.2-03. Guidelines are approved for state environmental control. Moscow, 2003

The area of contaminated soil probed in this way can be divided into zones according to the type of pollution and their concentration. For each zone, the volume of soil to be cleaned is determined (by multiplying the depth of the pollutants by the area of infection). By weighing a control volume of contaminated soil, determine the density of the soil and then calculate the mass of contaminated soil m _g using the values defined above.

As mentioned above, in the presence of a concentration map on it, as a rule, the boundaries and depth of the infected areas are already indicated.

According to the developed algorithm, the necessary mass of the sorbent is calculated to reduce pollution to a predetermined norm, for which measurements of concentrations K _{1 are} performed; K ₂ ; K ₃ ; and K ₄ pollutant when mixing samples of contaminated soil with a sorbent in the following proportions of the soil: sorbent - 1: 1; 1: 2; 1: 3; 1: 4. That is, a soil of known mass, for example, 1 kg, is mixed with a concentration of pollutant K _{0 in it} with the same mass of glauconite-containing substance (1 kg) to be cleaned, and a concentration of K _{1 of the} pollutant in the resulting mixture is measured. Then a soil of known mass, for example, 1 kg with a concentration of pollutant K _{0 in it, is} mixed with a mass of glauconite-containing substance equal to twice the mass of soil (2 kg), and a concentration of K _{2 of a} pollutant in the resulting mixture is measured. Similarly to the above, the concentrations of K ₃ and K _{4 are} determined.

After that, the mass m _{c of the} sorbent necessary for mixing with the soil in a given zone is determined by the following ratio:

m _c = m _gr · K ₁ / [K _s · (K ₀ / K ₁ + K ₁ / K ₂ + K ₂ / K ₃ + K ₃ / K ₄ ) / 4]

where K _s - a given concentration of pollutant in the soil.

Such calculations are done for each zone of the contaminated area. If there are several types of pollutants in the area of the contaminated area, then such calculations are done for each type according to the specified formula. From the obtained sorbent masses for each of the simultaneously polluting substances, the largest sorbent mass is selected, which is used to clean contaminated soil. Then, each zone of the area of the contaminated soil is moistened, for example, until it reaches a moisture content of at least 80%, the calculated mass of the sorbent is distributed over the surface of the contaminated soil, while the sorbent is mixed with the contaminated soil. It is advisable to mix throughout the known depth of soil contamination.

Before introducing the sorbent into the infected soil, it is possible to grind the sorbent with the subsequent isolation of the working fraction with a particle size of 0.01-0.1 mm. As mentioned above, it is also advisable to increase the sorption ability of the treatment of contaminated soil with a sorbent at a positive ambient temperature.

After work on soil detoxification, control measurements are carried out after 24 hours. Samples are taken from the entire treated area and depth. If control samples show a level of a given concentration or lower, then the object is considered detoxified.

Detoxification of soil contaminated with heavy metals and petroleum products is illustrated by the following conditional examples.

Example 1. Detoxification of soil contaminated with cadmium.

Soil weighing 1 ton was contaminated with cadmium. The concentration of cadmium in the soil K ₀ amounted to 8.7 mg / kg

When mixing such a soil with a glauconite-containing substance - glauconite concentrate (glauconite content 85%) in proportions of 1: 1, respectively; 1: 2; 1: 3; 1: 4, the following concentrations of cadmium in the soil were obtained - 1.1 mg / kg, 0.7 mg / kg, 0.32 mg / kg, 0.1 mg / kg.

The target cadmium concentration in the soil should be 1.5 mg / kg.

Using the proposed ratio, it was obtained:

Contaminated soil was moistened by irrigation to a moisture content of 75%. After that, the soil was mixed with 0.197 tons of glauconite concentrate.

The exposure time of the concentrate of glauconite with soil was 5 minutes. After that, samples were taken for analysis, which showed that the concentration of cadmium in the soil decreased to 1.5 mg / kg, which corresponds to the required concentration level.

Example 2. As a result of dividing the contaminated site into zones, a zone was obtained contaminated simultaneously with several pollutants, for example, lead, nickel and cadmium.

The following types and concentrations of pollutants were determined with a mass of contaminated soil in an area of 1 ton:

- lead concentration of 30 mg / kg;

- nickel concentration 28 mg / kg;

- cadmium concentration of 10 mg / kg.

As a sorbent, a glauconite-containing substance was used - natural glauconite sand with a glauconite content of 45%.

Knowing the mass of contaminated soil, the type of pollution and the maximum concentration of pollution, according to the developed algorithm, the necessary amount of sorbent was calculated to reduce pollution to the required standards, for which measurements of concentrations K ₁ , K ₂ , K ₃ , and K _{4 of} each pollutant were carried out at mixing samples of contaminated soil with a sorbent, respectively, in the following proportions of the soil: sorbent - 1: 1; 1: 2; 1: 3; 1: 4. As a result, the following concentrations were obtained:

- lead - 25 kg; 8.8 kg; 5.4 kg; 3.9 mg / kg;

- for nickel - 18 kg; 8.2 kg; 3.4 kg; 2.1 mg / kg;

- cadmium - 6 kg; 1.8 kg; 1.6 kg; 1.4 mg / kg.

After that, the mass m _{c of the} sorbent necessary for mixing with the soil was determined by the following ratio:

m _c = m _gr · K ₁ / [K _s · (K ₀ / K ₁ + K ₁ / K ₂ + K ₂ / K ₃ + K ₃ / K ₄ ) / 4],

The required target concentration of lead in the soil should be 6 mg / kg.

Using the proposed ratio, it was obtained:

That is, to achieve the required concentration of lead in 1 ton of soil, 2,362 tons of sorbent are needed.

The required target nickel concentration in the soil should be 4 mg / kg.

Using the proposed ratio, it was obtained:

That is, to achieve the required nickel concentration in 1 ton of soil, 2,313 tons of sorbent are needed.

The required target concentration of cadmium in the soil should be 2 mg / kg.

Using the proposed ratio, it was obtained:

That is, to achieve the required concentration of cadmium in 1 ton of soil, 1.651 tons of sorbent are needed.

Thus, it is clear that for detoxification for all three types of pollutants detected of the same soil mass (1t), 2,362 tons of sorbent must be used, i.e. the amount of sorbent required to achieve the required concentration of lead in the soil.

In this case, a soil weighing 1 ton with the above concentrations of pollutants was moistened by irrigation to a moisture content of 80%, after which it was mixed with 2,362 tons of sorbent.

When re-examining this zone for the concentration of pollutants, the data were:

- lead - 6.0 mg / kg;

- for nickel - 3.8 mg / kg;

- for cadmium - 1.7 mg / kg, which corresponds to a given concentration of pollutants or lower.

Example 3. Detoxification of soil contaminated with oil.

A soil volume of 0.77 m ³ was contaminated with oil products. At the same time, the concentration of oil products over the entire soil was 10,000 mg / kg (K ₀ ). Knowing the density of the soil, its mass was determined equal to 1000 kg.

As a sorbent, a glauconite-containing substance was used - natural glauconite sand with a glauconite content of 45%.

When mixing soil with a sorbent in the proportions of 1: 1; 1: 2; 1: 3; 1: 4, the following concentrations of oil products in the soil were obtained - 4100, 980, 720, 580 mg / kg, respectively.

The required concentration of petroleum products in the soil should be 1000 mg / kg.

Using the proposed ratio, it was obtained:

That is, for disinfecting 1 ton of soil contaminated with oil with a concentration of 10,000 mg / kg in the soil, 1,778 tons of sorbent are needed.

The soil was moistened and mixed with 1,778 tons of sorbent. The exposure time of glauconite sand with soil was 5 minutes. After that, samples were taken for analysis, which showed that the concentration of oil products in the soil decreased to 1000 mg / kg, which corresponds to the required concentration.

As can be seen from the above examples, the nature of the response of the pollutant to the sorbent is purely individual. In this case, this character (change in concentration) will change depending on the initial concentration. Obtaining statistics on changes in the concentration of a particular pollutant when mixed with a specific sorbent allows you to determine the necessary and sufficient mass (volume) of the sorbent for disinfecting the soil to the desired concentration.

It must be borne in mind that the determination of any constant coefficients or constants characteristic of each particular substance and reflecting the so-called sorption coefficient, i.e. the ability of glauconite to “absorb” a pollutant is impossible due to the purely individual characteristics of the soil in each case, as well as the individual properties of the used glauconite. Therefore, it is necessary to carry out the above actions to determine the "statistical" concentrations of the pollutant when mixing the soil with that glauconite-containing substance, which is supposed to further process the soil.

Thus, the use of the proposed method of detoxification of contaminated soil provides, in comparison with existing methods, the following advantages:

a) the ability to effectively clean soil contaminated with heavy metals, oil products using the optimum necessary and sufficient amount of sorbent;

b) the ability to clean soil contaminated with several pollutants at the same time;

c) calculation of the required amount of sorbent is possible both for cheap natural glauconite and for a more effective enriched glauconite concentrate;

d) the calculation of the required amount of sorbent does not require complex mathematical calculations, is efficient and possible in any difficult weather and climate conditions directly at the site of contamination.

In addition, the invention can significantly reduce the cost of detoxifying contaminated soil from technogenic pollutants and use the resulting purified product (soil) that meets environmental, sanitary and epidemiological standards and rules as the basis of artificial soil and organomineral fertilizer, while saving energy and raw materials.

Claims (5)

1. The method of detoxification of contaminated soil by introducing a natural sorbent into it until a predetermined concentration of a contaminant in the soil is achieved, while a glauconite-containing substance is used as a sorbent, characterized in that the type of pollutant and its concentration K ₀ in the sample are determined before the sorbent is introduced into the soil contaminated soil, then produce measurements of concentrations K _1, K _2, K ₃ and K ₄ of the pollutant by mixing the polluted soil with sorbent samples respectively in proportions primer: sorbet t - 1: 1, 1: 2, 1: 3, 1: 4, after which the mass m _a of sorbent needed for mixing with the soil contaminated with certain previously contaminant with a concentration K _0, and achieve in the soil a predetermined concentration of the pollutant To _s , based on the following ratio: m _c = m _gr · K ₁ / [K _s · (K ₀ / K ₁ + K ₁ / K ₂ + K ₂ / K ₃ + K ₃ / K ₄ ) / 4], where m _g is the mass of soil contaminated with a previously determined contaminant with a concentration of K ₀ , the contaminated soil is moistened, then the calculated mass of the sorbent is distributed over the surface of the contaminated soil with simultaneous mixing of the sorbent with the contaminated soil. 2. The method according to claim 1, characterized in that the moistening of the contaminated soil is carried out until it reaches a moisture content of at least 80%. 3. The method according to claim 1, characterized in that before applying the sorbent to the soil by examining samples of the surface of the contaminated soil for the content of the pollutant, sections with different concentrations of the pollutant exceeding a predetermined concentration are determined. 4. The method according to claim 1, characterized in that before processing the contaminated soil, the sorbent is ground, followed by the isolation of the working fraction with a particle size of 0.01-0.1 mm. 5. The method according to claim 1, characterized in that the treatment of contaminated soil with a sorbent is carried out at a positive ambient temperature.