RU2019527C1 - Method of soil treatment from the oil pollution - Google Patents

Abstract

FIELD: microbiological treatment of soil. SUBSTANCE: soil surface is treated with aqueous suspension of bacterial culture Rhodococcus erythropolis E-15 in the mixture with mineral fertilizer - nitro-ammophoska or nitro-ammophoska and sodium nitrate. Aqueous suspension is prepared in solution of one-third of nitro-ammophoska required quantity, and the rest fertilizer quantity is added as a dry substance. Consumption of bacterial culture is 1-10 g/m² soil, that of nitro-ammophoska is 115 g/m² soil, and sodium nitrate is 400 g/m² soil. Invention provides acceleration of oil hydrocarbons degradation at the low temperatures. EFFECT: improved method of soil treatment. 3 cl, 2 fig, 2 tbl

Description

 The invention relates to the field of microbiological treatment of soils contaminated with oil and oil products and can be used in environmental protection.

 A known method of cleaning soils from oil products, which consists in treating the contaminated surface with microorganisms for biodegradation of oil and introducing into the soil a sufficient amount of nitrogen and phosphorus in the form of nitrogen and phosphorus fertilizers. As microorganisms, a bacterial culture of Cellulomonas is used.

 The closest in technical essence is a method of cleaning soils and water from oil pollution, in which the contaminated surface is treated with an aqueous suspension of a bacterial culture of the natural strain "Pseudomonas putida 36 mixed with mineral fertilizer - nitroammophos.

 The known method provides high quality cleaning - up to 90% after 2 months after a single treatment.

 A disadvantage of the known methods is their low efficiency in areas with a cold climate.

 The purpose of the invention is the acceleration of the biodegradation of petroleum hydrocarbons at low temperatures.

This goal is achieved by the fact that in the method of purification of soils from oil pollution, including the treatment of an aqueous suspension of a bacterial culture in a mixture with mineral fertilizer - nitroammophos, bacteria Phodococcus erythropolis E-15 in the amount of 1-10 g / m ^{2 of} soil are used as a bacterial culture, and nitroammophos is administered in an amount of 115 g / m ² .

 Moreover, an aqueous suspension of a bacterial culture is prepared in a mixture with 1/3 of the required amount of mineral fertilizer, and the rest is administered in dry form.

In addition, in order to increase the share of assimilable nitrogen, in addition to the nitroammophosk, sodium nitrate can also be introduced in an amount of 400 g / m ^{2 of} soil (16% of assimilable nitrogen).

Used in the invention, the strain remains viable and active at a temperature of 8-10 ^about C.

 The used strain E-15 was isolated from the water of the Yenisei River on paraffin medium and identified as Phodococcus erythropolis.

 Cultural signs. On a medium with paraffin in the young culture, the colonies are shiny, colorless, mucous; in the old (2 weeks) colonies are drier, cream-colored, sometimes brownish. The diameter of the colonies is 1-5 mm, the edge is thin, sometimes rugged, the central part is strongly convex. On the IPA, the culture has a similar appearance. The strain develops very well in a liquid environment with paraffin.

 Morphological signs. On MPA, the daily culture is fixed sticks 0.8-1.0 microns thick, 2-4 microns long. There are curved cells and short twigs. At the age of 3 days, the sticks are shortened and rounded. On a solid medium with paraffin, an 8-hour culture also looks like sticks, but shorter than on MPA, often connected at 2 and 3 at an angle.

Physiological and biochemical properties. The culture is gram-positive, slightly acid resistant. Gelatin does not dilute, milk does not change, sucrose does not invert, fiber does not destroy, nitrates do not restore. It grows well on media with n-alkanes C ₁₄ -C ₁₈ as the only source of carbon and energy. Contains C ₃₂ -C ₄₀ mycolic acids.

 Strain E-15 is stored in the collection of the museum of the Department of Hydrobiology of Moscow State University.

 The bacterial preparation is R.erythropolis E-15 cells lyophilized or spray dried.

 The use of strain E-15 in combination with mineral fertilizer - nitroammophos, which is a source of nitrogen, phosphorus and potassium, can improve the efficiency of oil decomposition and provide a high degree of cleaning the soil surface at low positive temperatures.

The method is as follows. Nitrogen-phosphorus fertilizer (nitroammophosk or nitroammophosk and sodium nitrate) is added to the soil contaminated with oil, an aqueous suspension of the bacterial preparation is added in an amount of 1-100 g / m ^{2 of} soil in a mixture with 1/3 part of the fertilizer. After that, the soil is dug up and left for 1.5-2 months.

 The effectiveness of the method and the achievement of the goal is illustrated by the data in table. 1 and 2 and in FIG. 1 and 2.

 The content of petroleum hydrocarbons (OH) in the tundra soil, depending on the application of nitrogen and phosphorus fertilizers and a bacterial preparation are presented in table. 1, and in FIG. 1 and 2 show the effect of different concentrations of the bacterial preparation on the destruction of oil in the soil (Fig. 2) and the results of the destruction of oil without introducing the bacterial preparation (Fig. 1).

The designations adopted in figure 1: a - without mineral fertilizers, b - with the addition of nitroammophoski, c - with the addition of nitrate and nitroammofoski. In FIG. 2 curve a shows the effect on the destruction of oil in soil without a preparation, b - with the addition of 10 g of the preparation per 1 m ^{2 of} soil, c - with the addition of 100 g of the preparation per 1 m ^{2 of} soil, g - with the addition of 1 g of the preparation per 1 m ^{2 of} soil .

From the data obtained it follows that:
1) the introduction of only nitrogen- and phosphorus-containing fertilizers into the tundra soil containing oil causes a slight acceleration in the biodegradation of petroleum hydrocarbons; 2) the introduction of a bacterial preparation even at a minimum dose of 1 g / m ² (table. 1, example 1) increases the effectiveness of biodegradation by 5 times, compared with the control; 3) an increase in the dose of bacterial preparation to 100 g / m ² does not lead to an increase in the efficiency of oil biodegradation.

 The effectiveness of the method by the number of oil-oxidizing bacteria R.erythropolis E-15 in tundra soils after 7 weeks is shown in table. 2.

From the table. 2 shows that the number of cells of the oil-oxidizing bacteria E-15 at the end of the experiment (after 7 weeks) remains at a very high level - 10 ⁷ cells / 1 g of soil. Only in option 9, which did not contain oil, was it reduced by an order of magnitude. This indicates the high viability of the bacteria E-15 in the conditions of the northern tundra soils.

 The tundra soils of the test site have an acid reaction, pH 4.8-5.0. Before testing, liming can be carried out and the pH adjusted to 6.0-6.5.

PRI me R 1. On a test area of 1 m ² uniformly apply 1 kg of oil, a suspension of 1 g of the drug in ≈ 3 l of an aqueous solution 1/3 of the nitroammophos (≈30 g), the rest of the nitroammophos (≈85 g) make in dry form. The site is dug up and an average sample is taken. Then take samples after 4, 5 and 7 weeks. All samples are analyzed for the content of OH, and the last for the number of cells of the introduced oil-oxidizing bacteria E-15. The amount of OHC in the soil after 7 weeks decreased by 89% and amounted to 770 mg / 100 g of soil versus 6179 mg / 100 g of soil in the zero sample. The number of active oil-oxidizing bacteria was 1.3 · 10 ⁷ cells / 1 g of soil.

PRI me R 2. On a test plot of 1 m ² uniformly apply 1 kg of oil, a suspension of 10 g of the drug ≈ in 3 l of an aqueous solution of nitroammofoski. Other operations are similar to those described in example 1. After 7 weeks, the amount of OHC in the soil decreased by 81% and amounted to 1287 mg / 100 g of soil against 6701 mg / 100 g of soil in a zero sample. The amount of active oil-oxidizing bacteria was 3.3 × 10 ⁷ ml / g.

Example 3. On a test area of 1 m ² apply evenly 1 kg of oil and a suspension of 100 g of the drug in 5 l of an aqueous solution of nitroammophos (≈ 50 g). The remaining amount of nitroammophoski (65 g) is applied dry. Subsequent operations are similar to those described in example 1. After 7 weeks, the amount of OHC in the soil decreased by 88% and amounted to 767 mg / 100 g of soil against 6234 mg / 100 g of soil in the zero sample. The amount of active oil-oxidizing bacteria was 1.0 × 10 ⁷ cells / g.

PRI me R 4. On a test plot with an area of 1 m ² apply evenly 1 kg of oil and a suspension of 10 g of the drug ≈ in 3 l of an aqueous solution of 1/3 part (≈ 30 g) nitroammofoski. The remainder of the nitroammophoska (≈ 85 g) and 400 g of nitrate are brought in dry form. Subsequent operations are similar to those described in example 1. After 7 weeks, the amount of OHC in the soil decreased by 88% and amounted to 694 mg / 100 g of soil versus 5890 mg / 100 g of soil in the zero sample. The number of active oil-oxidizing bacteria was 2.6 · 10 ⁷ cells / g.

 PRI me R 5 (by a known method). The use of the Putidul preparation (the active base is Pseudomonas putida 36 cells) in tundra soils was ineffective. The destruction of NU was not observed. This is due to the fact that P.putida bacteria do not develop at low temperatures.

Thus, the proposed method can be used to clean the soil with oil pollution up to 1 kg / m ² in conditions of low positive temperatures with greater efficiency than known methods.

Claims (3)

1. METHOD FOR CLEANING SOILS FROM OIL CONTAMINATIONS, including treating an aqueous suspension of a bacterial culture in a mixture with mineral fertilizer nitroammophos, characterized in that bacteria Rhodococcus Erythropolis E-15 in an amount of 1-10 g / m ^{2 of} soil are used, and nitroammofosku in the amount of 115 g / m ² .  2. The method according to claim 1, characterized in that the suspension of the bacterial culture is prepared in a mixture with one third of the required amount of mineral fertilizer, and the rest of the nitroammophos is administered in dry form. 3. The method according to claims 1 and 2, characterized in that as a mineral fertilizer, sodium nitrate is additionally introduced in an amount of 400 g / m ^{2 of} soil.

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