RU2529771C1 - Biosorbent for elimination of crude oil from water reservoir surface - Google Patents

Abstract

FIELD: biotechnology.

SUBSTANCE: biosorbent for elimination of crude oil from water reservoir surface is proposed. The biosorbent comprises (wt %): clay - 70-80; tailings of brown coal - 19.5-28.5; strain Pseudomonas fluorescents of VCG RCAM00538-0.5-1.5.

EFFECT: effective cleaning of the water reservoir surface from crude oil while reducing the time and costs with use of biosorbent with high hydrocarbon-oxidising activity.

2 tbl, 5 ex

Description

The invention relates to the field of biotechnology and can be used as a substance for cleaning the surface of water bodies, in particular, settling barns for drilling wastewater, for cleaning the surface of water bodies contaminated with oil and products of its processing, localization of oil spills and oil products.

The well-known "Ecobiological product for water purification from oil products" [patent for the invention of the Russian Federation RU No. 2393215 IPC C12N 1/26, C02F 3/34]. A biological product is a culture of biodestructor cells artificially immobilized on a sorbent carrier from hollow spherical particles of regular shape with a diameter of 30 to 350 μm and a wall thickness of 2 to 10 μm, the inner cavity of which is filled with nitrogen and carbon dioxide having a composition (wt.%) : SiQ ₂ - 50-60; Al ₂ O ₂ - 25-30; Fe ₂ SO ₃ - 1.8-2.0; CaO - 1-5; MgO - 0.5-1.5; Na ₂ O - 0.3-1.5; K ₂ O - 0.2-2.9. The strain Pseudomonas fluorescens VKGM 68-44 is used as a biodestructor of petroleum products.

The disadvantage of this drug is the use of liquid culture Pseudomonas fluorescens VKGM 68-44 for cleaning oil. It is known that liquid culture is used immediately after preparation, because during prolonged storage, it deteriorates, i.e. Shelf life is negligible. In addition, the disadvantage of the known drug is the presence of spherical particles of the sorbent to increase its buoyancy and oil absorption ability, filled with nitrogen and carbon dioxide. The use of nitrogen and carbon dioxide increases the cost of a known preparation for purifying water from oil products, which accordingly increases the cost of the cleaning process.

In addition, the use of this drug allows you to clean the surface of the reservoir of oil and oil products for at least 30 days, which is a lengthy process.

It is known that peat is used for drilling wastewater treatment. Before use, it is treated with acids and alkalis, subjected to magnetic field treatment, adding calcium chloride to increase the oil absorption coefficient [F.A. Kamenshchikov, E.I. Mantid "Oil sorbents" Moscow-Izhevsk, 2005, p.152-156]. However, the addition of chlorides will further increase their content in the drilling fluid, which is impractical. In addition, to increase the oil capacity, the addition of organic acids to peat, such as humic acids with calcium chloride (CaCl ₂ ), glycerin, and vegetable oil, significantly increases the cost of the cleaning process.

A known composition for the biochemical elimination of oil pollution from the surface of water bodies, taken as a prototype, based on nitrogen-phosphorus-containing mineral fertilizer, consisting of a hydrophobic powder adsorbent, consisting of hydrophobized expanded perlite, with a relative density of less than one, and a bacterial preparation consisting of a liquid culture of microorganisms Pseudomonas putida 36 [and.with. No. 1710515 IPC C02F 1/40]. Perlite is a mineral material based on silicon oxide, the content of which is 75%. The known composition provides the possibility of biodegradation of oil in any type of water body. However, perlite has weak water-repellent properties, to eliminate which they carry out additional technology for treating perlite with various chemicals, such as carboxylic acids and their salts, which significantly increases the cost of the process.

The objective of the invention is the creation of a biosorbent capable of quickly localizing the spill of oil and oil products, the treatment of sludge pits for drilling wastewater, which has high hydrocarbon-oxidizing activity and the ability to effectively carry out water purification measures.

The technical result of the claimed solution is the effective cleaning of the surface of water bodies from oil while reducing time and costs using a biosorbent with high hydrocarbon-oxidizing activity.

To achieve the technical result, a biosorbent for eliminating oil pollution from the surface of water bodies, based on a hydrophobic powder sorbent, according to the invention, it contains a biodestructor strain Pseudomonas fluorescens VKH RCAM00538 with a filler from brown coal enrichment waste, and contains clay as a filler sorbent in the following ratio of components , wt.%: clay - 70-80; brown coal enrichment waste - 19.5-28.5; strain Pseudomonas fluorescens VKG RCAM00538 - 0.5-1.5.

The claimed combination of features allows to obtain a biosorbent with high hydrocarbon-oxidizing activity. The combined use of clay, a strain of Pseudomonas fluorescens VKH RCAM00538 and waste coal beneficiation allows you to localize the spill due to actively associated oil contaminants with a sorbent carrier (which is used as clay), actively utilize them using a biodestructor microorganism, being on the surface of the water, which ensures the claimed biosorbent high hydrocarbon-oxidizing activity, and allows you to increase the environmental cleanliness of the consequences of treatment.

Clay falling onto the water surface spreads, along with brown coal sludge - filler for the Pseudomonas fluorescens VKH strain RCAM00538, having oil absorption, and at the same time due to the microorganisms of the strain, decomposition from oil occurs. In addition, clay discolors water, removes oil impurities, especially toxic organochlorine compounds, various surfactants and organic compounds.

The cost of clay is ten times lower than artificial sorbents, which significantly reduces the cost of production of the proposed biosorbent, and this, in turn, reduces the cost of treating sludge pits for drilling wastewater (BSW), reservoirs contaminated with oil and products of its processing, and localization of oil spills and oil products .

The inventive sorbent meets the conditions of "novelty" and "inventive step", because the technical result is achieved by a set of characteristics characterizing it.

The microorganism culture Pseudomonas fluorescens VKH RCAM00538 was isolated from Perm Krai soil contaminated with oil products. The strain Pseudomonas fluorescens VKG was deposited 07.07.2011 under registration number RCAM00538 in the collection of the GNU All-Russian Research Institute of Agricultural Microbiology (St. Petersburg).

The strain Pseudomonas fluorescens VKG RCAM00538 is a strict aerobic gram-negative straight sticks with rounded ends located singly. Cell size - width from 0.7 microns to 1.7 microns, length - from 17 microns to 2.6 microns. Cells do not form capsules and spores. On the IPA, the growth along the stroke is plentiful, the coating is continuous with a wavy edge, the surface is shiny, membranous texture, yellowish-greenish tone; growth on MPA in Petri dishes is moderate, small colonies are rounded. On the BCH they form a cloudy environment and a flocculent precipitate. Cells - gram-negative, motile, polytrich.

When using galactose, glucose, sucrose, arabinose - a strong acidification of the nutrient medium and gas evolution. When using lactose, glycerin, xylose, maltose, mannitol - in addition to the above properties - the formation of a film. Hydrolysis of starch for 3-4 days. Use nitrogen. The cells are acid-resistant, stained red according to Ziehl-Nielsen, completely dilute gelatin for 3-4 days, peptone milk, coagulate casein. On an environment with 2.5% sodium chloride - cloudy medium, precipitate; on the medium of 6.5% sodium chloride - cloudy medium, precipitate.

Culture exhibits halophilic properties.

The culture does not form hydrogen sulfide; forms ammonia, indole. Reduces nitrates to nitrites, nitrites to N ₂ .

On Ashby's agar medium, a mild, transparent coating forms. Refers to oligonitrophils. Growth on a synthetic medium - a moderate, transparent coating with dotted colonies.

The cultivation of the strain Pseudomonas fluorescens VKH RCAM00538 is carried out on a nutrient medium at a temperature of 28 ° C and a pH value of 7.2.

Microorganisms are adapted to oil compounds in natural conditions.

The strain Pseudomonas fluorescens VKG RCAM00538 is grown on a mineral medium of the following composition, mass., G / l:

1 ml of a sterile mixture of microelements is added to the nutrient medium prepared and sterilized in an autoclave at 1 atmosphere for 30 minutes. A mixture of trace elements contains in 1 liter of water (r): H ₃ BO ₃ - 5; (NH _{4) 2} MoO ₄ - 5; KJ - 0.5; NaBr - 0.5; ZnSO ₄ · 7H ₂ O — 0.2; Al ₂ (SO ₄ ) ₃ - 0.3. The specified mixture of trace elements is pre-sterilized in an autoclave at a pressure of 0.5 bar for 15 minutes. In a sterile nutrient medium of the above composition, the bacterial strain Pseudomonas fluorescens VKH RCAM00538 was inoculated in an amount of 1 ml with a titer of 10 ^-13 and placed in a thermostat at a temperature of 28 ° C. The strain in the thermostat was aerated using a FAT-mini aerator for 2 days. After 2 days, the liquid bacterial culture of the Pseudomonas fluorescens strain VKH RCAM00538 with a titer of 10 ^-13 is ready for further use, namely, bacterial cells of the Pseudomonas fluorescens strain were immobilized on a filler - brown coal enrichment waste.

The chemical composition of drill coal dressing waste is a mixture of oxides of the following composition (%): manganese (IV) - 0.01; iron (III) - 0.82; potassium - 0.06; sodium - 0.02; sulfur - 0.36. The mass fraction of moisture in the waste, respectively, was 73.7% and the organic matter content was 5.93%.

The claimed biosorbent is prepared as follows.

Brown coal enrichment waste is mixed with a liquid bacterial preparation containing a bacterial culture of Pseudomonas fluorescens VKH RCAM00538 with a titer of 10 ^-13 in an amount of 50:50, the resulting mixture is stirred, laid out on a horizontal surface and dried at room temperature for 2 days. The dried mixture is triturated with a metal roller with a diameter of 10 cm so that there are no large pieces, as a result, a biodestructor with a fractional composition is obtained:

containing the strain Pseudomonas fluorescens VKG RCAM00538 with a titer of 10 ^-13 .

Clay was taken as a carrier sorbent from the quarry of the Bereznikovsky district of the Perm Territory of the following composition (wt.%): SiO ₂ - 54.7; Al ₂ O ₃ - 35.5; Fe ₂ About ₃ - 1.9; CaO - 1.2; MgO - 0.8; Na ₂ O - 0.5; K ₂ O - 0.2; water - 5.2.

The physical properties of the clay used to prepare the proposed biosorbent are presented in table 1 according to the range of soils GOST 25100-95.

The clay for obtaining the sorbent of the carrier was dried at room temperature 20-22 ° C, then subjected to crushing on a grinder “Laboratory core mill - crusher - LSMD - 50”, after which the following fractional composition (wt.%) Was obtained:

Then the sorbent carrier, which is used as clay prepared as described above, is mixed with a biodestructor in the form of a Pseudomonas fluorescens VKH strain RCAM00538 with a filler from brown coal enrichment waste in a predetermined ratio and the claimed biosorbent is ready for use. The technology of surface treatment of a reservoir consists in spraying the prepared biosorbent onto a surface of water with hydrocarbon oil pollution, for example, oil, with oil products. For this purpose, a spray sorbent PAC-1 is used (manufactured by LLC Lesorb, Bryansk).

Example 1. Prepare the proposed biosorbent, including, wt.%: Clay - 80; brown coal enrichment waste - 19.5; bacterial preparation strain Pseudomonas fluorescens VKG RCAM00538 - 0.5.

For this, clay in an amount of 16 g is mixed with a biodestructor containing brown coal enrichment waste in an amount of 3.9 g and 0.1 g of the Pseudomonas fluorescens VKH strain RCAM00538 in dry form.

The obtained biosorbent, by spraying, was introduced into a vessel with a capacity of 5 l with water with an area of 0.02 m ² containing 0.14 g of oil, which is equivalent to 68.5 g of oil per 1 l of water in an area of 10,000 m ² . After 7, 14, 20, 27, 28 days, the residual oil content is determined. The results are presented in table 2.

Example 2. Prepare the proposed biosorbent, including, wt.%: Clay 75; brown coal enrichment waste 24.0; and a bacterial preparation of Pseudomonas fluorescens VKG strain RCAM00538 in an amount of 1.0.

To do this, clay in an amount of 15 g is mixed with a biodestructor containing brown coal enrichment waste in an amount of 4.8 g and 0.2 g of the Pseudomonas fluorescens VKH strain RCAM00538 in dry form.

As in example 1, treated with the obtained biosorbent water surface with an area of 0.02 m ² containing oil in an amount of 0.14 g, which is adequate to 68.5 g of oil per 1 liter of water on an area of 10,000 m ² . After 7, 14, 20, 27, 28 days, the residual oil content is determined. The results are presented in table 2.

Example 3. Prepare a biosorbent, including, wt.%: Clay in an amount of 70; brown coal enrichment waste in the amount of 28.5; bacterial preparation strain Pseudomonas fluorescens VKG RCAM00538 in an amount of 1.5.

To do this, clay in an amount of 14 g is mixed with a biodestructor containing brown coal enrichment waste in an amount of 5.7 g and 0.3 g of the Pseudomonas fluorescens VKH strain RCAM00538 in dry form.

Analogously to example 1 and 2, the same water surface is treated with the prepared biosorbent. After 7, 14, 20, 27, 28 days, the residual oil content is determined. The results are presented in table 2.

Example 4. Prepare a biosorbent, including, wt.%: Clay in an amount of 85%; brown coal enrichment waste - 14.5; bacterial preparation strain Pseudomonas fluorescens VKG RCAM00538 in an amount of 0.5.

To do this, clay in an amount of 17 g is mixed with a biodestructor containing 2.9 g of brown coal enrichment waste and a 0.1 g dry Pseudomonas fluorescens VKH RCAM00538 strain.

Similarly to examples 1, 2 and 3, the same water surface is treated with the prepared biosorbent. After 7, 14, 20, 27, 28 days, the residual oil content is determined. The results are presented in table 2.

Example 5. Prepared biosorbent, including, wt.%: Clay in an amount of 65%; brown coal enrichment waste - 34.5; strain Pseudomonas fluorescens VKG RCAM00538-0.5.

To do this, clay in an amount of 13 g is mixed with a biodestructor containing waste coal lignification in the amount of 6.9 g and 0.1 g of the Pseudomonas fluorescens strain VKH RCAM00538 in dry form.

Similarly to examples 1-4, the same water surface is treated with the prepared biosorbent. After 7, 14, 20, 27, 28 days, the residual oil content is determined. The results are presented in table 2.

As can be seen from table 2, the tests showed that the use of the proposed biosorbent containing 70-80% clay, brown coal enrichment waste 19.5-28.5% and Pseudomonas fluorescens strain VKH RCAM00538 0.5-1.5%, purification from oil occurred on the 20th day and amounted to 93.7-98.8%, with a residual oil content of 0.3-3.3 g.

The proposed biosorbent containing the declared quantitative content of clay components of 70-80%, brown coal enrichment waste 19.5-28.5% and Pseudomonas fluorescens VKH strain RCAM00538 0.5-1.5%, is more effective than when containing these components, given in examples 4 and 5.

So, in example 4 using the proposed biosorbent containing 85% clay, coal enrichment waste - 14.5% and Pseudomonas fluorescens strain VKH RCAM00538 -0.5%, oil was cleaned on the 20th day, the degree of purification was 93, 2%, with a residual oil content of 4.7 g.

In example 5, using the proposed biosorbent containing 65% clay, coal enrichment waste 34.5% and Pseudomonas fluorescens VKH strain RCAM00538 -0.5%, oil was cleaned on the 20th day, but the degree of purification was 85.4 %, with a residual oil content of 5.4 g.

When using the known method, oil cleaning with its initial content on the surface of a reservoir of 40 g occurred only on the 28th day and the degree of purification was 80.0-83.7%, and the residual oil content was 6.5-8.0 g.

Thus, the tests showed that using the proposed biosorbent, water is purified from oil with a water content of 68.5 g / l on the 20th day at 93.7-98.8%. Whereas, in comparison with the analogue, oil purification with its content in water in the amount of 40 g / l occurs on day 28 at 80.0-83.7%.

In addition, the proposed biosorbent contributes to the intensification of the use of industrial waste in order to protect the environment and reduce environmental pollution.

Thus, the claimed biosorbent provides the elimination of oil from the surface of water bodies with minimal costs and for a shorter time than known. The biosorbent allows you to localize the spill due to the active binding oil products by the carrier sorbent, to actively dispose of them using a bioorganic microorganism, being on the surface of the water, which allows to increase the environmental cleanliness of the cleaning consequences.

The cost of clay is ten times lower than that of artificial sorbents. Clay is mined in many regions of Russia, in the immediate vicinity of its place of consumption for water purification, which expands the scope of its application.

Claims (1)

Biosorbent for the elimination of oil from the surface of water bodies based on a hydrophobic powder sorbent, characterized in that the biosorbent contains a biodestructor - Pseudomonas fluorescens strain VKH RCAM00538 with filler from brown coal enrichment waste, and clay as a sorbent in the following ratio of components, wt.%:
clay - 70-80;
brown coal enrichment waste - 19.5-28.5;
strain Pseudomonas fluorescens VKG RCAM00538 - 0.5-1.5.