RU2093478C1 - Method of water and soil treatment from oil, petroleum products and polymeric additions in drilling fluid - Google Patents

Abstract

FIELD: ecology. SUBSTANCE: treatment is carried out with association of the following bacterial strains: Rhodococcus erythropolis VKM Ac-1339D, Pseudomonas putida VKM-1301 and Bacillus subtilis VKM B-1742D (16). This association is able to refine water polluted with oil products and polymeric additions at concentration below 10 g/l and soil - at concentration 10-15 kg/m². EFFECT: enhanced effectiveness of treatment. 2 cl, 6 tbl

Description

 The invention relates to methods for cleaning water and soil from oil, oil products and drill cuttings containing polymer additives in the drilling fluid.

 Drilled sludge due to the variety of mineral composition, oil, oil products and complex polymer additives: CMC (carboxymethyl cellulose), PRS (sulphite-alcohol stillage), PAA (polyacrylamide) and others is capable of contacting natural complexes, their moisture, precipitation, underground and ground waters have an uncontrolled negative impact on the established natural equilibrium of local bio- and agrocenoses with the unpredictable behavior of these complexes in the future. Therefore, the problem of collecting, cleaning and environmentally safe storage of cuttings is extremely urgent.

 A known method of decomposition of oil and oil products using fungi of the genus Actinomycor elegans, strain TC-405, ATCC 20613, Jeotrichum marlum, Thirumalachar sp. nov. ATCC 20614 (1.2).

 The disadvantages of these methods are the low growth rate of the proposed fungal strains and a more complex nutrient medium containing biostimulants of mushroom growth, a longer period of adaptation to petroleum products, the inability to decompose polymer additives in the drilling fluid: CMC, PRS, PAA.

 A known method of purifying water and soil from oil products (RF patent N 2014286, C 15, C 02 F 3/34, E 02 B 15/04).

The method is based on the use of a consortium of microorganisms: yeast, bacteria or bacteria in the following species composition:
Candida tropicalis + Mycoccus lactis
Candida guilliermondii + Acinetobacter olovorum subs. paraphinicum.

 The disadvantage of this method is the low growth rate of the proposed associations in the environment with oil and oil products, the inability to biodegrade polymer additives in the drilling fluid: CMC, PRS, PAA.

 There are known physical and chemical methods for cleaning drill cuttings from oil pollution and polymer additives: methods of fire treatment, heat calcination, additives of coagulants and others (3).

 The closest analogue, i.e., a prototype, is a method for cleaning soil and water from oil and oil products (5). The method is based on the use of a strain of Pseudomonas putida 36 and mineral fertilizer nitroammophos.

 The disadvantage of this method is the low degree of purification of soil and water from oil, oil products and the inability to degrade polymer additives in the drilling fluid: CMC, SSB, PAA.

 The purpose of the invention to increase the degree of purification of soil and water from oil, petroleum products and polymer additives in the drilling fluid.

 The essence of the method (invention) is that they purify water and soil from oil, oil products and polymer additives in the drilling fluid through the association of bacteria: Rhodococcus erythropolis AC-1339D; Pseudomonas putida VKM-1301; Bacillus subtilis VKM-1742D.

 The method is as follows.

Example 1. To assess the biodegradation of oil, oil products through a consortium of bacteria using a mineral medium composition, g / l: NaNO ₃ - 2.0; MnSO ₄ 0.008; K ₂ HPO ₄ 1.0; ZnSO ₄ 0.002; MgSO ₄ • 7H ₂ O 0.5; Fe ₂ (SO ₄ ) ₃ 0.01; distilled water, pH 7.0, 7.2. Oil (Tuymazinsky deposit, Bashkortostan), oil products (diesel fuel, gessadecan or polymer additives: CMC, SSB, PAA at the rate of 100 mg / l) are added to the mineral medium as the only carbon source. As a biostimulator of bacterial growth, a yeast autolysate of 0.001 g / l is added.

A suspension of bacteria is obtained by rinsing from the jamb with a small amount of sterile tap water and introducing it into the test medium at a rate of 3 vol. Bacterial Association: Rhodococcus erythropolis AC-1339D; Pseudomonas putida VKM-1301; Bacillus subtilis VKM-1742D (16) is added in a 1: 1: 1 ratio. Bacteria are cultured in rocking flasks in a thermostatically controlled rocking chair under conditions of intensive aeration at 25-30 ^o C.

 The determination of the content of oil and oil products is carried out by a known method by the weight method (6).

 A quantitative analysis of the content of CMC and PRS is based on the formation of a colored complex with phenol in the presence of concentrated sulfuric acid, the optical density of which was determined spectrophotometrically using a Specol instrument at a wavelength of 490 nm (7).

 The quantitative content of polyacrylamide was determined using dithizone, which gives colored complexes with acrylic polymers, the optical density of which was measured spectrophotometrically using a Specol instrument at a wavelength of 480 ± 5 nm (8).

 The number of bacteria was evaluated by the Koch plate method (9).

 In the table. 1 shows the results of the growth of microorganisms in an environment with individual organic compounds: oil, hexadecane, diesel fuel, CMC, PRS and PAA.

 As can be seen from the data in table. 1, the number of bacterial cells in all environments containing oil, oil products and polymer additives increases on average by two orders of magnitude.

 The results of bio-purification from oil, oil products and polymer additives show that complete destruction of oil, hexadecane, diesel fuel occurs after 2 days. cultivation, and biodegradation in the environment of CMC after 3 days. averages 80% PAA 61% (table. 2).

 The results of bio-purification from oil, oil products and polymer additives are given in table. 2.

 Example 2

 The bio-purification of water containing in its composition in a total amount of 1 g / l: oil, hexadecane, diesel fuel, CMC, SSB, PAA, taken in equal proportions, is carried out in a laboratory unit, which consists of a tank for treated wastewater (10 l ), aeration tank with a stirrer, a settling tank, tanks for preparing an aqueous mixture (model runoff) for biological treatment.

Add salt to the purified water for the mineral medium, g / l: K ₂ HPO ₄ 0.5; MgSO ₄ • 7H ₂ O 0.5; CaCl ₂ • 6H ₂ O 0.05; KH ₂ PO ₄ 1.0; MnSO ₄ • 4H ₂ O 0.01; FeSO ₄ • 7H ₂ O
0.05; 0.01 yeast autolysate; pH 7.0 7.2.

 The growth of microorganisms is controlled by the growth of biomass, which was determined by the gravimetric method using special filters (N1) for bacteria.

 The content of oil, oil products and polymer additives was determined by the above method.

As can be seen from the data given in table. 3, study association Rh. Erythropolis AC-1339D, Ps.putida 1301; B.subtilis BKM B-1742D (16) biodegrades a mixture of oil, oil products, CMC, SSB, PAA. After 3 days. cultivation, the degree of purification from oil, petroleum products, CMC, PRS, PAA is 96 98% and from PAA 59%
Example 3. In porcelain cups of 0.2 l were placed 100 g of chernozem. Soil moisture was adjusted to 60% of the total moisture capacity. In the first series of cups, 1% oil + PRS was added; oil + CMC; oil + PAA and the association of bacteria taken in equal RH ratio. erythropolis AC-1339D; Ps. putida BKM1301; B.subtilis BKM B-1742D (16) in an amount of 3 vol.

Similar dishes, but without the addition of bacteria, served as control. The cultivation of bacteria was carried out in a thermostat at 25 ^o C for 120 days.

 Analyzes on the content of oil, PRS, CMC, PAA and the total number of bacteria growing on MPA were determined in triplicate.

 The research results are given in table. 4 and tab. 5. As can be seen from the data table. 4, in all experimental samples there is an increase in bacteria growing on MPA. Especially significant increase in prototypes containing oil + PRS is an order of magnitude, and in an environment with oil + CMC 2 times. Apparently, such an increase is possible due to biodegradation of oil and polymer additives.

 The biodegradation of oil and polymer additives is evidenced by the data given in table. 5.

 Example 4. Bioremediation of an industrial sample of drill cuttings, selected in OGPD "Yuzharlanneft" (Bashkortostan), was carried out according to example 3.

 The results of biological treatment of drill cuttings from oil, polymer additives CMC are presented in table. 6.

 Proposed Association: Rhodococcus erythropolis AC-1339D; Pseudomonas putida VKM-1301; Bacillus subtilis VKM B-1742D can be used to purify water and soil from oil, oil products and polymer additives in drilling mud in the conditions of the Republic of Bashkortostan, NGDU Yuzharlanneft, NGDU Arlanneft, in the conditions of the Ural-Povolzhye, in the Perm Region, and also in Western Siberia and other regions.

 Scope environmental protection.

 The method is based on the use of an association of non-pathogenic bacteria: Rhodococcus erythropolis AC-1339D; Pseudomonas putida VKM-1301; Bacillus subtilis VKM B-1742D, actively decomposing oil, oil products and polymer additives into drilling mud into environmentally friendly compounds.

 The Association has a wide spectrum of oxidative activity, it destroys light and heavy fractions of oil, PRS, CMC, PAA, decomposing them almost completely.

 The proposed association is able to clean soil and water from oil, oil products and polymer additives in drilling mud in drill cuttings in the joint presence of the above pollutants.

 The association is resistant to chemical pollution of soil and water, for example, pesticides.

The Association is able to purify water with contamination by oil products and polymer additives up to 10 g / l and higher and the soil 10 15 kg / m ² .

Sources of information
1. US patent N 4415662, CL. C 12 N 11/14, 1/26, C10032 / 00.

 2. US patent N 4415661, CL. C 12 N 11/00, 11/26, 1/44, C1032 / 10.

 3. Shemetov V.Yu. Yezhov M.Yu. Prevention of soil contamination with spent drilling fluids. Oil industry. M. VNIIOENG, 1989, N 2, p. 64 67.

 4. Bykov I.Yu. Gumenyuk A.S. Tsivilev R.P. and other drill cuttings. M. VNIIOENG, 1993, 10 13 p. Express information. "Series corrosion protection and environmental protection."

 5. A.S. N 1428809, A14 E 02 B 15/04, C 02 F 3/34.

 6. Lurie Y. Yu. Unified methods of water analysis. M. Chemistry, 1973, p. 75.

 7. Ed. Doctor of Chemistry S.D. Varfolomeeva. Methods of study and properties of cellulolytic enzymes. M. VINITI, 1993. The results of science and technology. "Biotechnology Series", v. 25.

 8. Sharipov A. U. Dolganskaya S.I. Instructions for the quantitative analysis of acrylic polymers in aqueous solutions. Tyumen, 1987.

 9. Tepper E.Z. Melnikova V.K. Pereverzeva G.I. Workshop on microbiology. M. Kolos, 1979, 289 p.

Claims (2)

 1. A method of purifying water and soil from oil, oil products and polymer additives in a drilling fluid, comprising introducing microorganisms, characterized in that the microorganisms use the association of bacterial strains Rhodococcus erythropolis VKM Ac-1339D, Bacillus subtilis VKM B-1742D and Pseudomonas putida VKM 1301 .  2. The method according to p. 1, characterized in that the bacterial strains are in a ratio of 1 1 1.

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