RU2339466C1 - Method of purification of ground, soil, concrete and building constructions from organic contamination - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: carbamide-formaldehyde polymer, for instance Penoizol, as toxicant sorbent from objects and washing are used. Ratio of purified object and sorbent is from 1:0.05 to 1:1 in volume or not less than 0.05 dm³ per 1 m² of purified object surface. 0.5-1.5 wt % of sodium salt of polyacrylic, methacrylic acids or their mixture and 0.1-5.0% of sodium sulfate and/or silicate are added. Consumption of washing solution constitutes from 0.4 to 2.0 dm³ per 1 kg of soft ground or per 1 m² of hard ground surface, building constructions.

EFFECT: simplification and cheapening of purification; increase of safety of works on purification of objects from hydrocarbon contamination.

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Description

The invention relates to the field of environmental protection and can be used to clean contaminated objects (soil, concrete, soil, sandy beaches, piers, building structures) from pollution by oil products, combustible rocket fuel and other liquid organic toxicants at industrial enterprises, storage bases, stations pumping and refueling of petroleum products during the operation and disposal of equipment, soil remediation, places of spills of pollutants.

Currently, there are a number of methods for cleaning soil, soil, concrete chips, building materials from organic contaminants using mechanical means, thermal desorption, extraction, microbiological and other methods (Russian patents No. 2191643, 2000, 2217246, 2004; patents US No. 6497534, 2004, 4424081, 1984; German patent No. 329652, 1983; Japanese patent No. 3236219, 2002). Oxidative and sorption methods are also known (Russian patents No. 2144954, 1999, 2188072, 2002, 2203155, 2003, 2209694, 2003; US patent No. 6315494, 2002; French patent No. 2806939, 2000 g .; Japanese patent No. 3236219, 2002).

These methods do not provide sufficient cleaning of the soil from oil products and liquid rocket fuels, in particular, from asymmetric dimethylhydrazine combustible (UDMH), T-1 kerosene, oils, hydrocarbon contaminants in oil and other combustible workplaces. Mechanical extraction methods are laborious, time consuming. The thermal method requires a large consumption of fuel for burning soil, leading to additional pollution of the atmosphere with toxic combustion products. Significant disadvantages are characteristic of many microbiological and oxidative methods: high cost, cleaning time, and difficulty in use. After purification with oxygen-reactive reagents, a residual bacteriological effect is possible, leading to the subsequent self-healing of certain contaminants. The use of hypochlorite oxidizing agents is associated with the introduction of chlorine into the environment.

Sorption methods, as a rule, provide a high degree of purification, but are difficult to perform, however, in combination with other methods, they can be simplified.

A known sorption method for cleaning contaminated with oil products soil (Russian patent No. 2144954, 1999, B09C 1/100), which to a lesser extent has the noted drawbacks, we have chosen as a prototype. The method includes mixing (contacting) the soil with a granular sorbent, washing with water, separating the surfaced sorbent, which is used as thermally expanded graphite. The toxicant is separated from the sorbent thermally, mechanically or by ultrasound.

This method uses a relatively expensive reagent - expanded graphite (cost 360 rubles per 1 kg) with a sorption capacity for oil products from 40 to 80 g / g.

The cost of the sorbent needed to clean one ton of soil, with the values of the volumetric ratio of soil and sorbent from 1: 0.1 to 1: 2 and the density of the sorbent 10 kg / m ^3, respectively, from 180 to 3600 rubles. A significant drawback of thermally expanded graphite is its toxicity due to the presence of nanostructures (carbon nanotubes) in it, which, in particular, affect the lungs (World of Materials and Technologies. Technosphere, Sat, edited by P.P. Maltsev, 2006, p. .39).

In addition, this sorbent has high adhesion to the soil, so the process of separating it from the soil is time-consuming and energy-intensive. In the process of separation of the organohydrogen mixture, the solid cleaned object and the sorbent, there are large losses of expensive sorbent. Depending on the properties of the soil, they can reach 15%.

The aim of the invention is to simplify the method of sorption cleaning, reducing cleaning costs and improving the safety of works on cleaning the soil, soil, concrete and building structures.

The goal is achieved in that carbamide-formaldehyde polymers are used as a sorbent with a ratio of the object to be cleaned and the sorbent from 1: 0.05 to 1: 1 in volume or at least 0.05 dm ³ per 1 m ^{2 of the} solid surface of the object to be cleaned. In the wash water add 0.5 ... 1.5 wt.% Sodium salt of polyacrylic, methacrylic acid or a mixture thereof and 0.1 ... 5.0 wt.% Sulfate and / or sodium silicate at a flow rate of wash water from 0 , 4 to 2.0 dm ³ per 1 kg of soft soil or per 1 m ^{2 of the} surface of solid soil or the surface of structures.

Urea-formaldehyde polymers are used due to their following positive properties. They have a developed pore surface, high sorption capacity for low-polar liquids and oil products: fuel UDMH up to 48 g / g, gasoline up to 80 g / g, kerosene up to 85 g / g, diesel fuel up to 83 g / g, fuel oil up to 60 t / g , oil up to 84 g / g. The sorption rate is very high. The sorption time of light oil products is 1.8 ... 8.9 seconds, oil is not more than 3 minutes. Sorbent easily floats, as its density is from 7 to 18 kg / m ³ . It is safe to handle, easily regenerated by extraction and can be reused. When burned, it does not form highly toxic substances such as polyaromatic compounds or dioxins.

Recommended polymers include: Penoizol (TU 2254-001-33000727-99), Penoizol analog - Hypersorb, etc., including polymer foams that can be produced at the place of consumption using the GZhU1 installation (TU 4845-002-18043501- 95) according to a simple scheme from available raw materials (polymer resin, foaming agent and curing catalyst). These polymers easily decompose under the influence of natural factors.

Polymers are used in the form of granules, powder, crumbs, plates of various sizes. When mixing (contact) with the soil, sorbent is used mainly in the form of granules and powder. The preferred granule size is 50 ... 200 microns. Large granule sizes are more effective for light oil products, smaller ones for heavy ones.

To improve the washing properties of the wash water, 0.5 to 1.5 wt.% Sodium salt of polyacrylic or methacrylic acids (including their copolymers with a molecular weight of from 20,000 to 120,000 amu) or mixtures thereof are added to it. Uniflock, Gipan, etc. products are offered as an example of a detergent. These salts displace organic substances from the surface and from the pores of particles of soil, concrete, or the surface of structures to be cleaned. They prevent the emulsification of, in particular, kerosene in the wash water and the reverse absorption of kerosene in the soil. The difference in the density of the components of the mixture "oil product - wash water - soil" makes it easy to separate the system by sludge in a few minutes, and the washing solution is used repeatedly (at least 10 times). For deeper cleaning, the contaminant in the solution can be removed with Penoizol.

In order to improve the washing properties of the wash water, sodium sulfate and / or sodium silicate is also added in an amount of from 0.1 to 5.0 wt.%, Which increase the alkalinity of the solutions and strengthen the monomolecular film on the surface of the object being cleaned. The limit values of the concentrations of the components in the wash water are justified experimentally. If the minimum concentration of Uniflock, silicate and sodium sulfate is reduced, the improving effect of the detergent is lost. If the upper concentration value is exceeded, the increase in efficiency per unit mass of wash water becomes insignificant.

The ratio of the volume of the washed object to the volume of the sorbent is maintained equal to from 1: 0.05 to 1: 1 (from 1: 0.0004 to 1: 0.008 by weight). The minimum limit is used for contamination with light hydrocarbons and combustible UDMH and their minimum concentration (units of maximum permissible concentrations). With an increase in the molecular weight of the pollutant and its content in the cleaned object, the sorbent consumption increases. It is proposed to wash freshly contaminated (up to 6 months) objects with contamination up to 200 g / kg at an ambient temperature of +3 to + 50 ° С.

The washing of contaminated soil or the surface of structures, for example, sea or river berths, places where toxic substances are spilled, is carried out with washing water containing a detergent. The solution is supplied under pressure of 1.5 ... 4.0 atm. The flow rate of wash water is from 0.5 to 2 dm ³ per 1 kg of soil or 1 m ^{2 of} the surface to be cleaned with one to three times its use.

The method is implemented as follows. To contact the sorbent with soil and other objects, Penoizol is applied evenly to the surface of the soil or the object being cleaned, at the rate of not less than 5 dm ³ per 100 dm ^{3 of} soft soil (1 m ³ per 20 m ^{3 of} soil) or not less than 50 cm ³ per 1 m ² surface of solid soil or other object (for example, concrete berth). Soft soil with a sorbent is plowed, discoated or cultivated to mix them. Sorbent deposited on solid soil or concrete, in the presence of wind, is covered with a polymer film.

The required mass of sorbent and wash water is determined based on the size of the area to be cleaned or the volume of the soil to be cleaned and the concentration of the substance to be removed. A drainage ditch is dug on one side of the area to be cleaned for soft soil, and the corresponding stock recess is selected for a solid object. The area to be washed is washed with Uniflock solution, feeding it under pressure to the edge of the drainage ditch along its entire length for at least 1 hour (one cycle). Spend several cycles, bringing the concentration of toxicants in the cleaned object to the desired values. Samples of soft soil or flush from hard surfaces after removal of the washing solution are taken for analysis.

The mobile pulp "kerosene-wash water-soil" is collected in the lower part of the ditch, a special recess or tank. Spend her defending. Booms filled with Penoizol or Penoizol slabs are placed on the pulp surface, Penoizol is held for at least 5 minutes, then the product collected by Penoizol, for example kerosene, is removed from the surface of the wash water and disposed of. Penoizol is squeezed out and reused or disposed of in any way. Wash water after cleaning with a sorbent can also be reused or disposed of with natural factors.

Upon detection of removed contamination (for example, kerosene) in the object to be cleaned or on its surface at a concentration higher than the permissible value, the object's cleaning operations are repeated.

With an area of contamination of 200 m ^{2 the} cleaning time is from 5 to 10 days, depending on the level of contamination.

Examples of the application of the proposed method when cleaning soft soil from kerosene, UDMH and summer diesel fuel, as well as solid soil and concrete from kerosene were carried out in laboratory conditions at temperatures from +3 to + 50 ° C and various ratios of the cleaned object and sorbent (G: C ) and wash water (table). Experiments No. 1, 2 were performed by the prototype method in less expensive modes, close to the mode of experiments by the proposed method.

From these examples it follows that the degree of purification according to the proposed method exceeds the degree of purification according to the prototype, especially in terms of cleaning soft soil from highly toxic nitrogen-containing hydrocarbon - UDMH.

The sorbent consumption is halved. Thermally expanded graphite can be reused no more than 3 times, after which its sorption properties are sharply lost. Penoizol was suitable for use at least 10 times. Repeated use of washing water (at least 10 times) significantly reduces the consumption of sodium salt of polyacrylic, methacrylic acid or a mixture thereof and the cost of cleaning.

It was found that with the five-time use of both Penoizol and washing water, the cost of cleaning soft soil according to the proposed method is from 32 to 512 rubles. for 1 t

If the cost of the sorbent with a single use of the prototype is from 180 to 3600 rubles. per 1 ton, then according to the proposed method - from 18 to 360 rubles. per 1 ton, i.e. 10 times less. With a tenfold use of the washing solution, its costs range from 15 to 260 rubles. for 1 t

Experiments have shown that heat-treated expanded graphite can be reused no more than 2 ... 3 times, since its particles stick together during regeneration and its sorption capacity sharply decreases. The cost of reusing thermally expanded graphite can be reduced to an average of 1390 rubles. per 1 ton, while according to the proposed method, this amount will be about 138 rubles. per 1 ton, i.e. an order of magnitude less. Moreover, the proposed tools and products for their disposal are less toxic compared to the sorbent used in the prototype method. Electricity is practically not expended, ultrasound is not used, and Penoizol losses for 10 cycles of application do not exceed 5 ... 8 wt.%.

Examples of the proposed method for cleaning objects contaminated with fuels Example No. Pollutant Temperature ° C The ratio of G: C, dm ³ : dm ³ Concentration, wt.% Rinsing water consumption, dm ³ / kg The number of cycles for 1 hour Multiplicity of application The degree of purification,% Title Concentration, g / kg Uniflock Na ₂ SO ₄ (Na ₂ SiO ₃ ) sorbent wash water one. Kerosene 200 3 1: 2 - - 2.0 3 2 81.8 2. UDMH 2.0 3 1: 0.1 - - 2.0 3 3 42.3 3. UDMH 2.0 3 1: 0.1 0.5 2.0 0.4 3 one one 83,4 four. UDMH 2.0 3 1: 1 1,5 (0,1) 0.4 3 2 5 99,2 5. UDMH 2.0 fifty 1: 0.05 0.5 10 1,5 3 2 10 98.5 6. UDMH 0.5 fifty 1: 0.05 1,0 2.0 0.4 one 2 5 one hundred 7. Kerosene 200 3 1: 0.05 0.5 (10) 1,5 one one one 82.0 8. Kerosene 200 3 1: 0.5 1,5 0.5 1,5 one one one 88.8 9. Kerosene 200 fifty 1: 1 0.5 10 1,5 2 one 10 97.3 10. Kerosene one hundred fifty 1: 1 1,5 5 2.0 3 10 5 93.2 eleven. Diesel summer one hundred 24 1: 0.5 1,5 0.1 1,5 2 one 2 70.1 12. Diesel summer 210 fifty 1: 1 0.5 10 0.4 one 2 10 58.0 13. Kerosene ¹ 40 ³ 3 1: 1 ⁵ 1,5 5,0 1,0 ⁴ 2 one fifteen 63.0 fourteen. Kerosene ² 40 ³ fifty 1: 0.005 ⁵ 1,5 (5.0) 2.0 ⁴ 2 one 10 99.8 ¹ - hard soil; ² - concrete; ³ - g / m ² ; ^{4, 5} - dm ³ / m ²

Thus, the achieved effect consists in simplifying the method of sorption cleaning, reducing the cost of cleaning contaminated objects by an order of magnitude, reducing the loss of sorbents and improving the safety of cleaning soft soil, hard surfaces and building structures.

Claims (1)

The method of cleaning contaminated soil, soil, concrete and building structures from organic pollution, including contacting the cleaned object with a sorbent and wash water, characterized in that the carbamide-formaldehyde polymer is used as a sorbent with a ratio of the cleaned object and sorbent from 1: 0.05 to 1: 1 by volume or at least 0.05 dm ³ per 1 m ^{2 of the} surface of the object to be cleaned, and 0.5-1.5 wt.% Sodium salt of polyacrylic, methacrylic acid or a mixture thereof and 0.1- 5.0 wt.% Sodium sulfate and / or silicate at a flow rate of wash water of 0.4 to 2.0 dm ³ per 1 kg of soft ground or on 1 m ² of the surface of the solid soil or constructions.