RU2237711C1 - Method of restoring oil-polluted bleaching earth - Google Patents

Abstract

FIELD: nature conservation.

SUBSTANCE: invention relates to protection of soil resources against oil pollution. To activate oil biodegradation process in bleaching earth, activated sludge from biological waste disposal plants, oxygen compounds, and biomass of consortium of oil-oxidizing microorganisms Bacillus brevis and Arthrobacter species are used. Consortium is added in amount 3-5% on the weight of activated sludge. Method allows content of residual oil products to be reduced by 6.5 tines over a period of 3 months.

EFFECT: enhanced oil biodegradation efficiency.

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Description

The invention relates to the protection of the environment, in particular to the protection of soil resources from oil pollution.

Currently, oil refining complex enterprises using clay for contact post-treatment of base oils (removal of resinous compounds and polycyclic aromatic hydrocarbons) are forced to store their waste in the form of dumps, thereby aggravating the ecological situation and occupying additionally alienated territories.

There are various biological methods for the restoration of soils contaminated with oil or oil products, based on the introduction of specialized microorganisms into such soils, previously isolated from various contaminated sources or genetically modified. The main agents of biodegradation of oil and oil products are bacteria. This is explained by the fact that the use of hydrocarbons in their life activity among bacteria is quite widespread.

A number of researchers have shown that bacteria of the genus Rhodococcus are promising for the creation on their basis of preparations for biodegradation of oil and oil products polluting the soil [1, 2].

Spore-forming bacteria are also widely used to create drugs that help cleanse the soil and water from oil contamination [3-5].

The disadvantages of these drugs is the low efficiency in the reclamation of bleaching earth contaminated with oil products, the bulk of which are resinous substances and polycyclic aromatic compounds.

Closest to the proposed method is the reclamation of bleaching earth contaminated with oil products, where activated sludge from biological treatment plants with the addition of oxygenated compounds, such as superphosphate or hydrogen peroxide, is used to activate the biodegradation of oil products [6].

The disadvantage of this method is the relatively low degree of biodegradation of petroleum products.

The technical task of the proposed method is to increase the efficiency of biodegradation of petroleum products contained in bleaching earths.

The problem is solved by adding to the bleaching earth an additive containing, in addition to activated sludge, biological treatment facilities and oxygenated compounds, an additional biomass of a consortium of oil-oxidizing microorganisms Bacillus brevis IB DT 5-1 and Arthrobacter species IB DT 5-3, introduced in an amount of 3-5 wt.% in relation to activated sludge.

The indicated consortium of bacterial strains was isolated from gray forest soil artificially contaminated with diesel fuel and deposited in the Microorganism Collection of the Institute of Biology of the Ufa Scientific Center of the Russian Academy of Sciences.

Characterization of the strain Bacillus brevis IB DT 5-1.

Morphological and cultural characteristics. Straight sticks with rounded ends. Gram-positive. Movable. Endospores are spherical. On agarized media they form round, with smooth edges, dense in the center of a colony of opaque color, opaque, luminescent. Saprophyte.

Physiological and biochemical properties. Aerobes. Chemorganotrophs. Catalase and oxide are positive. It assimilates sucrose, xylose, fructose, maltose, lactose, mannitol, mannose, arabinose, L-rhamnose, glycerin. Absorbs asparagine, arginine, alanine; weakly assimilates valine, lysine. The Voges-Proskauer reaction is negative. Gas does not form from glucose. Indole does not form. Growth in anaerobic agar is negative. Forms acid from glucose. Starch does not decompose. Able to oxidize oil hydrocarbons. Non-pathogenic.

Characterization of the strain Arthrobacter species IB DT 5-3. Morphological and cultural characteristics. Short sticks shorten with age to cocci. Gram-positive. On dense nutrient media they form round, dull-colored flat colonies, less dense at the edges than in the center. Saprophyte.

Physiological and biochemical properties. Aerobe. Catalase-positive, oxidase-negative. Oxidative metabolism. It assimilates sucrose, fructose, maltose, lactose, xylose, mannitol, mannose, arabinose, L-rhamnose, glycerin. When grown on glucose, it forms a gas. Absorbs asparagine, arginine, alanine; weakly assimilates valine, lysine. Consumes citrates as the sole carbon source. Gelatin does not hydrolyze. Starch does not decompose. Indole does not form. The Voges-Proskauer reaction is negative. Lack of growth on medium with 6% NaCl. Able to oxidize oil hydrocarbons. Non-pathogenic.

The oxidizing activity of a consortium of microorganisms was determined by the final oxidation product, i.e. on the allocation of CO ₂ according to the method described in [7]. Carbon dioxide absorbent Ba (OH) ₂ , 250 ml of Raymond nutrient medium, 2.5 ml of diesel fuel and 5 ml of a three-day culture of the consortium with a cell content of 1.0 · 10 ⁸ CFU / ml and individual pure cultures are introduced into 500 ml flasks (5 ml each) of microorganisms Bacillus brevis IB DT 5-1 and Arthrobacter species CB DT 5-3 with a titer of 1.0 · 10 ⁸ CFU / ml, obtained by isolating them from the specified consortium. The oxidative activity of the consortium in the experiment lasting 30 days was 1990 mg of CO ₂ , while the oxidative activity of Bacillus brevis IB DT 5-1 and Arthrobacter species IB DT 5-3, respectively 750 mg CO ₂ and 870 mg CO ₂ . Thus, the type of said consortium is a natural symbiotic association of two strains of microorganisms. The quantitative content of each of the microorganism strains that make up the consortium was 10 ⁸ CFU / ml in the culture fluid and did not change during prolonged storage under appropriate conditions. By the method of mathematical analysis, it was established that in this consortium Bacillus brevis IB DT 5-1 refers to the dominant form (51%) of all the studied microorganisms in the population. The bacteria Arthrobacter species IB DT 5-3 are a co-dominant culture (49%).

Examples of specific performance.

In laboratory tests of the method of biological reclamation of bleached earth contaminated with oil products, bleached earth taken from the dumps of OJSC “Orsknefteorgsintez”, activated sludge used to treat oily wastewater at biological treatment facilities in Orsk, oxygenated chemical compounds - superphosphate and hydrogen peroxide the biomass of a consortium of microorganisms Bacillus brevis and Arthrobacter species, obtained by their joint fermentation.

A consortium of strains of Bacillus brevis IB DT 5-1 and Arthrobacter species IB DT 5-3 are grown under aerobic conditions on a nutrient medium of the following composition, g / l: Na ₂ CO ₂ - 0.1; CaCl ₂ - 0.01; MnSO ₄ · 7H ₂ O — 0.02; FeSO ₄ · 7H ₂ O — 0.02; NaH ₂ PO ₄ - 1.5; To ₂ HPO ₄ - 1.0; MgSO ₄ · 7H ₂ O — 0.2; NH ₄ NO ₃ - 2.0; distilled water - 1000 ml. Diesel fuel is used as the sole carbon source; the fermentation process is carried out at room temperature until the microorganism titer in the culture fluid reaches 10 ⁸ CFU / ml.

To assess the rate of decomposition of petroleum products, an indicator of the residual content of petroleum products in bleaching earth was used.

The residual oil content was determined by spectrophotometric and weight methods [8]. In the first of these, a sample weighing 10 g was placed in a filter paper cartridge and transferred to a Soxhlet apparatus. The extraction was carried out with 120-150 ml of hexane for 2-3 hours at the boiling point of hexane (69 ° C). The hydrocarbon concentration in the sample was determined by the optical density of the extract on an SF-46 spectrophotometer at a wavelength at which this hydrocarbon mixture had a maximum absorption peak. The maximum absorption peak was determined on a SPECORD UF-VIS spectrophotometer. According to the weighing method, a sample weighing 10 g was placed in a filter paper cartridge and weighed on an electronic balance. The extracted samples together with the cartridges were dried in an oven at a temperature of 100-120 ° C and again weighed on an electronic balance. The difference in the weight of the samples before and after extraction was determined by the content of residual oil products.

The number of the main groups of microorganisms involved in the biotransformation of petroleum products was determined by sowing the soil suspension by the method of limiting dilutions on solid nutrient media [9]: bacteria assimilating organic nitrogen on meat peptone agar (MPA), utilizing mineral forms of nitrogen on starch-ammonium agar (KAAA) ), microscopic fungi (micromycetes) —in Chapek’s environment and hydrocarbon-oxidizing microorganisms in Tsukamura’s environment, where a sterile mixture of hydrocarbons was used as a carbon source obtained after hexane extraction of contaminated bleaching earth.

The experiments were repeated three times.

Scheme of laboratory (model) experience in the restoration of bleaching earth:

1) 150 g of bleaching earth (OZ);

2) 150 g OZ + 150 g activated sludge + 9.6 g superphosphate (or 6.4 wt.% Relative to activated sludge);

3) 150 g OZ + 150 g activated sludge + 17.04 g hydrogen peroxide (33%) (or 11.36 wt.% With respect to activated sludge);

4) 150 g OZ + 150 g activated sludge + 9.6 g superphosphate + 4.5 g biomass of the said consortium of microorganisms;

5) 150 g OZ + 150 g activated sludge + 17.04 g hydrogen peroxide + 4.5 g biomass;

6) 150 g OZ + 150 g activated sludge + 9.6 g superphosphate + 7.5 g biomass;

150 g OZ + 150 g activated sludge + 17.04 g hydrogen peroxide + 7.5 g biomass;

8) 150 g OZ + 150 g activated sludge + 9.6 g superphosphate + 3.0 g biomass;

9) 150 g OZ + 150 g activated sludge + 17.04 g hydrogen peroxide + 3.0 g biomass;

10) 150 g OZ + 150 g activated sludge + 9.6 g superphosphate + 9.0 g biomass;

11) 150 g OZ + 150 g activated sludge + 17.04 g hydrogen peroxide + 9.0 g biomass.

The test results of the proposed method for reclamation of bleaching earth showed that the introduction of activated sludge with oxygenated compounds with the addition of biomass of a consortium of oil-oxidizing microorganisms Bacillus brevis IB DT 5-1 and Arthrobacter species IB DT 5-3 significantly increases the efficiency of the process of biodegradation of oil products in bleaching earth (table. 1). After 30 days of incubation, the degree of reduction in the content of petroleum products by the proposed method was 83.07-87.11 wt.%. The application of the prototype method in experimental conditions was less effective compared to the proposed technical solution, and the degree of biodegradation of oil products did not exceed 62.57-70.9 wt.%. Moreover, the introduction of a biomass of a consortium of microorganisms of less than 3 wt.% Reduced the efficiency of the process of biodegradation of oil products, and the introduction of biomass of more than 5 wt.% Practically did not affect the increase in the efficiency of this process.

The introduction of the biomass of a consortium of oil-oxidizing microorganisms contributes to a significant increase in the number of soil microorganisms involved in the transformation of oil products polluting the bleaching earth - bacteria growing on MPA, CAA, hydrocarbon-oxidizing microorganisms and micromycetes (Table 2-5).

Implementation of the proposed reclamation method at the dumps of OJSC “Orsknefteorgsintez”, where 3000 tons of bleaching earth was dumped on a plot of 15 acres, allowed to reduce the content of residual oil products over 3 months from 34.0 wt.% To 5.2 wt.%, I.e. 6.5 times.

Thus, the proposed method for the biological reclamation of bleaching earth using activated sludge and oxygenated compounds and the additional introduction of biomass of a consortium of microorganisms Bacillus brevis IB DT 5-1 and Arthrobacter species IB DT 5-3 compared with the known one can increase the efficiency of the process of biodegradation of oil in soil, activate microbiological activity of soils.

List of references

1. The bacterial strain Rhodococcus erythropolis used to clean water and soil from oil and oil products: A.s. 1805097 USSR, MKI ⁵ С 02 В 3/34, Е 02 В 15/04 // Yagafarova G.G., Skvortsova I.N., Zinoviev A.P., Yagafarov I.R.

2. A method of cleaning soils from oil pollution: Pat. 2019527, Russia, MKI ⁵ C 02 F 3/34 // Coronelli T.V., Arakelyan E.I., Komarova T.I., Ilyinsky V.V.

3. The bacterial strain Bacillus sp. - Destructor of petroleum products and phenolic compounds: Pat. 1784592, USSR, MKI ⁵ C 02 F 3/34 // Astrova N.G., Moiseeva L.V., Protchenko P.Z.

4. Stabnikova E.V., Selezneva M.V., Reva O.N., Ivanov V.N. The choice of an active microorganism - a hydrocarbon destructor for cleaning oil-contaminated soils. // Applied biochemistry and microbiology. - T.34, No. 5. - S.534-539.

5. The method of reclamation of soils contaminated with oil and oil products: Pat. 2077397, Russia, MKI ⁶ В 09 С 1/10, С 09 К 3/32 // Andreson R.K., Khaziev F.Kh., Deshura BC, Bagautdinov F.Ya., Boyko T.F., Novoselova E .AND.

6. The method of reclamation of bleaching earth contaminated with oil: Pat. 2183142, Russia, MKI ⁷ В 09 С 1/10 // Loginov O.N., Kostyuchenko V.P., Komarov S.I., Silishchev N.N., Boyko T.F., Podpsekhin A.K.

7. RU patent No. 2156169, C 02 F 3/34, B 09 C 1/10, 1998.

8. Gruzdyakova R.A. Spectrophotometric determination of petroleum products in soil samples. // Hygiene and sanitation. - 1993. - No. 3. - S.73 and 74.

9. Zvyagintsev D.G. Methods of soil microbiology and biochemistry. - M .: Moscow State University. - 1980 .-- 223 p.

Claims (1)

A method for reclamation of bleached earth contaminated with oil products by adding an additive containing activated sludge from biological treatment plants and oxygenated compounds to the soil, characterized in that said additive additionally contains the biomass of a consortium of oil-oxidizing microorganisms Bacillus brevis IB DT 5-1 and Arthrobacter species IB DT 5- 3, introduced in an amount of 3-5 wt.% In relation to activated sludge.