RU2080298C1 - Method of cleaning surfaces from petroleum and petroleum products - Google Patents

Abstract

FIELD: purification of oil-polluted water. SUBSTANCE: as substance suitable to remove oil, linear polymer is utilized capable of unlimited swelling in petroleum and petroleum products. Polymer is applied onto light-weight mineral or organic filler. EFFECT: increased cleaning efficiency. 7 cl

Description

 The invention relates to the removal of spills of oil and oil products from the surface of the soil or water, as well as the purification of water from various industrial sources.

 A known method of removing oil spills by using compositions consisting of a polymer and a crosslinking agent (Technical information of the company, "BP Chemicals" on the purification of water from oil, 1987).

 However, the known method is ineffective and requires a large consumption of the composition.

 The objective of the invention is to remedy these disadvantages.

 The problem is solved by creating a means consisting of dispersed particles with an outer polymer layer. As the polymer used linear polymers with an unlimited degree of swelling. Upon contact of the ultrafine polymer with the liquid to be separated, a gel-like mass is formed rather quickly, which can be easily removed using simple mechanical means.

 To ensure the buoyancy of the gel-like mass, it is necessary to use an inert (non-chemically interacting) filler with a density lower than the density of the separated liquid.

To avoid separation of the swollen polymer and the light filler, the polymer is applied to the surface of the filler. Microparticles of a polymer with an average size of 5 • 10 ^-8 5 • 10 ^-7 m of latex are deposited on the surface of the hollow particles of the filler, which ensures physical coalescence of the polymer with the filler. Thus obtained powdery composite material (sorbent) is placed on the surface of the separated liquid, where the polymer swells, absorbing the completely separated liquid, forming an almost instantly continuous gel-like mass, which is collected and disposed of in the following possible directions, taking into account local conditions:
returning the spent product after refining, for example, at oil production sites, to a crude oil tank, where the polymer layer is completely dissolved in accordance with the nature of such a polymer, and the thickened oil returns to its original state; dispersed particles after their peeling are removed and used for re-preparation of the composite polymer material;
mixing the spent product with a sand-gravel mixture and using the mixture to create a bearing base for roads (road waterproofing);
mixing the waste product with road bitumen and using the mixture as road asphalt concrete;
mixing the spent product with roofing bitumen and using the mixture to create a soft roof of buildings and structures;
use of the spent product in the production of expanded clay;
use of the spent product as fuel.

 For the problem to be solved, a wide range of polymers can be used: polybutyl acrylate, copolymers of ethylene and propylene, butadiene and styrene, butyl and isoprene, and the like.

 To solve some problems of separation of liquid products, it is possible to use a powdery polymer without a filler to thicken.

 The filler should provide reliable buoyancy of polymer-thickened oil.

 Suitable filler materials are hollow spherical materials, for example glass, silicate, phenol-formaldehyde, polystyrene, gelatin or polyethylene capsules, having a specific gravity less than the density of the separated liquid.

 In addition, in order to reduce the consumption of composite material and reduce its cost, light dispersed particles, such as ash microspheres prepared from waste ash generated during the operation of thermal power plants, hollow mineral microspheres from lava deposits, vermiculite, perlite, can be used as filler , crushed husks of buckwheat, rice and other light available and cheap materials that can additionally absorb the separated liquid.

 For example 1. Tests for cleaning water from spilled oil were subjected to 14 samples of oil from Russian and CIS fields and 8 samples from Argentina, Kuwait oil, gas condensate and various oil products.

For each test oil sample, 150 ml of water is poured into a 200 ml beaker, onto which surface 1 g of oil is added dropwise. Next, a powdery composite material (sorbent) is applied to the oil film, and a change in the weight indication as the sorbent is added is noted. Various weights of the sorbent are applied to the oil film and kept at room temperature (20 ^o C), with cooling (5 ^o C) and with temperature control (50 ^o C). The exposure time of the sample depends on the individual properties of the oil or on the thermodynamic means of the polymer-solvent pair. An oil sample is considered to be fully collected if, during stirring, a visually visible oil film and non-oil particles of a sorbent do not appear, and its consumption is calculated from the amount of sorbent necessary for this.

After the sorbent treats the oil slick, a viscoelastic mass is formed almost instantly on the water surface, which is easily removed from a clean water surface. After removing it from the water surface by chromatographic method, analyze the residual oil content in the water. The determination was carried out on a chromatograph with a plasma-ion detector at a column temperature of 200 ^o C and an evaporator temperature of 150 ^o C, carrier gas-argon 3 HP For column packing, N-AW chromaton (Fr. 0.200 ^{° C.} 0.250) soaked in 5% Silicone SE-30 was used.

Test object
1. Distilled water, seawater with an initial oil content of 0.

2. Oil fields in Russia and the CIS:
Priozerskaya (Khanty-Mansiysk), Ust-Balyk, Tazovskaya, Van Yegan, Embinskaya, Martyshinskaya, Mangyshlakskaya, Shaimskaya and industrial drains of Tuapse;
deposits of Argentina:
Canadon Secoi, Palmar Largo, Malargue Mendoz Tierra Del Fuego, Mendoza Nacional, Neuguen, Rio Negro, Rio Gallgos;
and light Kuwaiti oil.

 3. Sorbent light carrier (glass microspheres MCO A9, silicate microspheres Q-Cell, perlite, vermiculite, ash microspheres) treated with a linear polymer from the latex form (butyl rubber, a mixture of butyl and isoprene rubber, a mixture of isoprene and styrene butadiene, butadiene styrene).

4. Test results (in all experiments):
oil thickening time, min: 1 40;
sobrent consumption, g / g: 0.08 0.2;
residual oil content in water, mg / l: 0 0.15 (for reference): the permissible oil content in drinking water according to GOST 2874-82 is 0.3 mg / l).

Example 2. Conduct tests to purify water from petroleum products (according to example 1)
Test object
1. Distilled and sea water;
2. Petroleum products: gasoline, diesel fuel, fuel oil, gas condensate, kerosene, oils (motor, transformer);
3. Sorbent: light carrier (hollow glass microspheres IG-101, silica microspheres "Q-Cell"), treated with a linear polymer from the latex form (butyl acrylate rubber with acrylonitrile, hexyl acrylate rubber, diethylhexyl acrylate rubber).

4. Test results:
thickening time, min: 5;
sorbent consumption, g / g: 0.1;
residual oil content in water, mg / l: 0 0.1.

Example 3. Tests are conducted to purify water from oil in a stainless steel pool measuring 1.6 • 1.5 m installed in the open. Fill the pool with water with pH = 0.8. The ambient temperature is 26 ^o C. 2.5 L of Rio Grande oil (Argentina) is poured onto the surface of the water. An oil slick under the influence of wind comes into contact with the walls of the pool and adheres to them. After the sorbent is treated with an oil slick with a flow rate of about 0.1 g / g, it is held for 20 hours, after which the thickened oil is removed from the water surface with a perforated shovel.

Test results
1. The lateral metal surface of the pool (the place of contact with oil) is clean, which is established by wiping with a white cloth.

 2. The residual oil content in water of 0.3 mg / l.

 Example 4. Conduct tests to clean the surface of the soil from spilled oil. 50 L of Tyumen light oil is poured onto the soil surface and then treated with a sorbent at a rate of 0.1 • 0.15 g / g. The thickened oil is easily removed from the soil surface with improvised mechanical means. Almost instantly, oil thickening on the soil surface prevents its penetration into the soil layer and makes it easy and convenient to remove oil from the soil surface.

 Example 5. Carry out tests to clean the surface of the concrete base from spilled aviation kerosene TS-1. Sorbent crumb of ethylene propylene rubber.

 To prevent kerosene from spreading over the concrete surface, a cylindrical roller filled with a sorbent is installed. The shell of such a roller is a perforated fabric. 30 l of TS-1 kerosene are poured and sprinkled with sorbent. After 5 minutes, the thickened kerosene was collected in a scoop and removed. The surface of the concrete base is clean and dry.

 Tests are conducted to clean the surface of metal and concrete substrates from spilled oil products.

 Test object: acetone, benzene, toluene, hexane, heptane, octane.

Test Results:
sorbent consumption, g / g: 0.05 0.08;
thickening time, min: 1 ^o C3;
the treated surface after removal of the thickened product is dry and clean.

 Example 6. Conduct tests for the purification of oily waters.

Oil-containing water with an oil concentration of 0.3-300 mg / l in water is pumped through a bag filter, where butyl rubber with an unlimited degree of swelling, applied from a latex form to perlite, is used as a packing. The flow rate of the treated water in the experiments was up to 25 m ³ / h. The residual oil content in the treated water did not exceed 0.1 mg / L.

 Example 7. Conduct tests to prevent pollution of the coastal zone of the water basin from the release of oil spills.

 From the leeward side, 50 l of Tyumen oil is poured onto the water surface of the lake near the coastal zone (beach). The coastal zone (the place of the planned ejection of an oil slick pebbles, sand) is sprinkled with a sufficient layer of sorbent. After the oil spill is completely ejected by the waves onto the shore, the “polluted” oil is washed off by the same waves back to the lake’s water surface, or the surface layer (the contact point) together with the sand is shifted into the water. Sand settles to the bottom, and light particles of polymer composite material with thickened oil float to the surface of the water. After removing the thickened oil from the surface of the water, the residual oil content in the sample of water with sand was 0.02 mg / L.

 Due to the fact that the active layer of the sorbent possesses all types of sorption: ad-, ab- and chemisorption, oil is bound and “thickens”. In this state, it does not pose a danger of environmental pollution, whether bound on the water surface and washed ashore, or “thickened” on the shore and washed back into the water.

 In addition, a significant additional environmental effect brings the inventive method. Special experiments have established that the burning rate of "thickened" gasoline by this method is reduced by 10 times.

Claims (7)

 1. A method of cleaning surfaces from oil and oil products, comprising surface treatment with a dispersed polymer-containing composite material followed by regeneration or disposal of the spent product, characterized in that the polymer is a linear polymer with an unlimited degree of swelling in the oil product, applied to an inert mineral or organic filler.  2. The method according to p. 1, characterized in that the regeneration is carried out by mixing the waste product with an excess of the original oil or oil product.  3. The method according to p. 1, characterized in that the disposal of the spent product is carried out by mixing with a sand-gravel mixture and used as a bearing base for roads.  4. The method according to p. 1, characterized in that the disposal is carried out by mixing the waste product with road bitumen and use the mixture as asphalt concrete.  5. The method according to p. 1, characterized in that the disposal is carried out by mixing the waste product with roofing bitumen and used to create a soft roof of buildings.  6. The method according to p. 1, characterized in that the disposal is carried out by using the waste product in the production of expanded clay.  7. The method according to p. 1, characterized in that the spent product is used as fuel.