RU2182118C1 - Process of clearing of water from oil products - Google Patents

Abstract

FIELD: ecology, control over environmental pollution. SUBSTANCE: process of clearing of water from oil products includes manufacture of porous sorption material based on natural minerals ( schungite, pearlite, tripoli, diatomite ) with size of particles less than 500 mcm and thermosoftening plastic hydrophobic polymers with size of particles less than 300 mcm. Natural mineral is mixed with thermosoftening polymer in proportion of 100 parts by weight of mineral to 25-130 parts by weight of polymer. Prepared mixture is employed to fill moulds of certain configuration ( discs, cylinders, belts, plates ) and is subjected to thermal treatment at temperature of polymer melting in the course of 5-40 min. To execute the process discs, cylinders or belts are rotated in aqueous medium polluted with oil products. Oil products clinging to surfaces of discs, cylinders, belts in process of rotation are continuously scraped off by scrapers. Sorption material in the form of plates is dipped into water polluted with oil products and is kept in water till concentration of oil products in water reaches permissible value of 0.05 mg/l. When sorption material is saturated with oil products they are removed out of sorption material by vacuum pumping or by centrifugation and after it sorption material can be used again. Efficiency of proposed process amounts to 99.6- 99.8%. EFFECT: raised efficiency of clearing of water from oil products. 8 cl

Description

 The invention relates to the field of ecology and is intended to combat environmental pollution with oil products.

A known method of purification of water from petroleum products at refineries, gas stations, etc. (see V.A. Proskuryakov, L.I. Schmidt Wastewater Treatment in the Chemical Industry, Chemistry Institute, 1977, pp. 396-399.)
The essence of this method is that primary sludge is collected in ponds - sumps or water collectors, in which pop-up oil products are pumped out or dispersed on the surface by powder adsorbents, which, after adsorption of oil products on the surface of particles of these sorption materials, are removed from the surface of the water and burned, then waste water is subjected to reagent treatments (coagulants and flocculants), coagulated oil products are removed from the surface of the sumps by scraper mechanisms, constant prices waste water for further purification from small concentrations of oil dissolved in the water or under the body of water in the form of suspensions, it is supplied to the sand or bulk sorption filters.

The disadvantages of this method:
- the multiplicity of technological operations and the bulkiness of technological equipment,
- difficulties in the processes of loading and unloading bulk sorption filters,
- frequent washing of bulk filters requires a large flow of washing water,
- the use of coagulants and flocculants,
- high energy costs,
- the inability to use the resulting petroleum products for their intended purpose.

 A known method of collecting petroleum products from a water surface by dispersing bulk sorbent materials, such as peat brand Pit-Sorb (Canada), Turbsjet (France), BTK (Russia) or other bulk materials, such as sawdust, agricultural waste Sorboil (Russia) ) (see. Proceedings of the Scientific Research Institute of Physics of Fullerenes and New Materials. Moscow, 1999, Table 1, p. 5).

 Petroleum products associated with these materials are collected by all known methods, for example, nets, scoops, ladles, and the resulting material is burned.

These methods are not without drawbacks:
- the difficulty in dispersing bulk materials on a surface contaminated with petroleum products, and their subsequent collection,
- the need for their burning,
- single use,
- low sorption ability.

 There is also known a method of collecting from the surface of petroleum products by contacting them with bulk non-woven or pile-like polymeric materials, followed by suction, pressing in presses or centrifuges, (see Proceedings of the Scientific Research Institute of Physics of Fullerenes and New Materials. Moscow, 1999, Table 1, page .5).

This method also has the disadvantage of:
- low productivity when collecting light fractions,
- reduction of free volume due to the cohesion of fibers or fibers with petroleum products remaining after extraction,
- low sorption ability,
- high cost and difficulty in the manufacture of pile-like materials.

 The closest in technical essence and the achieved result is a method of purifying water and land from spilled oil and oil products, including the collection of contaminants using adsorbents (RF patent 2123086 C1, class E 02 B 15/04).

 The essence of the method is that the sorbent material is preliminarily prepared by treating natural graphite with chromic acid and resistive heating with a starting current of 90A and a working current of 25–35A, the obtained fluff-like material is dispersed in the water column under a floating layer of oil products or the material is scattered over a surface contaminated with oil products, after sorption of oil products it is collected for regeneration and squeezed, the obtained oil products can be used for its intended purpose.

The disadvantages of this method are:
- the fact that the technological process of water purification from oil products is not continuous,
- the need to create special mechanisms for dispersing and ejecting sorbent material into the water column under a surface contaminated with oil products,
- the need to collect from the surface of the sorbent material together with petroleum products,
- the need to have special equipment for the extraction of the collected material,
- the complexity of the secondary dispersion of the sorption material due to the stickiness of the particles of the latter by the residues of the oil after pressing
- the fact that in the manufacture of the sorbent material an environmentally hazardous substance is used - chromic acid.

 The technical task of the claimed invention is the creation of a continuous process of collecting oil products from the water surface and extracting dissolved or suspended oil products from the aqueous medium with porous sorbent materials made on the basis of natural minerals (schungite, tripoli, perlite, diatomite, flask or mixtures thereof) and thermoplastic hydrophobic polymers.

 The stated technical problem is solved in that porous sorption material is used as adsorbents, preliminarily prepared by mixing a natural mineral selected from the shungite series, or perlite, or tripoli, or diatomite, or flask, or their mixture in the form of a powder with a particle size of not more than 500 microns with a thermoplastic hydrophobic polymer in the form of a powder with a particle size of not more than 300 microns in a ratio of 100 parts by weight mineral 25-135 weight. including polymer, followed by heat treatment at a melting temperature of the polymer for 5-45 minutes, and molded products of various configurations.

 The resulting sorbent porous material, for example in the form of a disk or many disks, a cylinder or a continuous tape, is rotated in water contaminated with oil products. As a result of sorption, oil products adhere to the surface of the sorption material, and they are constantly removed by scraping or suction. As a result of such a technological operation, the extraction of oil products from the aqueous medium occurs continuously at a high speed and with an efficiency of water purification from oil products of 99.5-99.9%.

 To extract oil products dissolved in water or in the form of suspensions and exceeding the maximum permissible concentrations, adsorbents made in the form of porous plates are immersed in settlers in water and can stand for so long until, as a result of sorption, the contaminated water is purified from oil products to concentrations, below the maximum permissible.

The amount of petroleum products extracted by the porous plate from the aqueous medium is determined from the ratio
N = V • p,
N is the amount of oil extracted by the porous adsorbent, g;
V is the pore volume, cm ³ ;
P is the density of petroleum products, g / cm ³ .

 After saturation, the plates are subjected to vacuum or centrifugation to extract oil from the pores of the sorption material, after which they are reused.

The advantages of the proposed method are:
- the continuity of the process of removing pop-up oil products,
- the absence of a dispersion process,
- the absence of a reagent treatment process,
- the extraction of dissolved or in the form of suspensions of petroleum products by sorbing porous plates instead of bulk sorption filters,
- simplification of the technological scheme of purification from oil products,
- reduction of energy costs in the manufacture of sorbent material,
- that the material is not loose, non-toxic, resistant in the aquatic environment.

The minerals used are known natural sorbents:
shungite - a natural mineral that is elemental carbon, which differs from anthracite in its low content of volatile components, and from graphite in the absence of a crystalline structure,
diatomite - the remains of siliceous carapace or skeletons synthesized by diatoms, racichleria or flagella,
perlite - natural opal silicate,
Tripoli - loose opal silica, which is an extremely small or larger round shape of a body with a diameter of 0.002 - 0.02 mm,
flask - dense opal silica, which is an extremely small or larger round shape of a body with a diameter of 0.002 - 0.02 mm

 All these materials have sufficiently high sorption properties.

 During heat treatment of a composition consisting of a powder of a hydrophobic thermoplastic polymer and one of the above minerals, at a temperature above the melting temperature of the polymer, a polymer matrix is formed, in the cells of which there are particles of the mineral. At the same time, the air expanding in the pores of the mineral and evaporating moisture contribute to the formation of a porous system with open pores with a porosity of 50-60%. Due to the lack of adhesion of the polymer to the particles of the mineral, their surfaces are free and accessible to sorption processes. This explains the high capacity of the adsorbent to oil products, which are not only adsorbed on the surface of particles of a natural mineral, but also fill the entire pore volume.

 As a thermoplastic polymer in the claimed method, powders made of high pressure polyethylene or low pressure polyethylene, waste polyethylene, polystyrene, polyvinyl chloride, polyamide and others are used.

Examples of specific implementation of the method:
Example 1. The natural mineral shungite with a particle size of less than 74 microns and low-density polyethylene of high density with a particle size of less than 300 microns are mixed in a ratio of 100 parts by weight of mineral 100 parts by weight. (100 g) of polyethylene and fill the form in the form of a disk with a diameter of 250 mm and a height of 5 mm. Heat treatment is carried out at a temperature of +135 ^o C for 35 minutes, after heat treatment, a disk is removed from the mold, the weight of the disk is 200 g, and the porosity is 55%. The porosity of the sample is determined according to GOST 18898-73. 400 g of crude oil are poured into a container with an area of 1600 cm ² and a depth of 100 mm, the disk is immersed vertically to a depth of 50 mm and rotated at a speed of 30 rpm. The disk is wrapped around with a U-shaped knife to a depth equal to the radius of the disk, with an inclination to a horizontal plane of 20 ^o for gravity flowing oil. After 1 minute 40 seconds, 378 g of oil is collected in a container, the weight of the disk, due to oil adsorbed in the pores, increased by 21 g. Thus, the total weight of oil extracted from water was 399 g, the efficiency of continuous water purification from oil products is 99.8% .

Example 2. Natural mineral shungite with a particle size of less than 74 microns and low-density polyethylene of high density with a particle size of less than 300 microns are mixed in a ratio of 100 parts by weight of mineral 100 parts by weight. (14 g) of polyethylene and formed into a tape 50 mm wide, 2 mm thick and 350 mm long. Heat treatment is carried out at a temperature of +135 ^o C for 35 minutes, after heat treatment, the resulting tape is thermally duplicated on one side with a synthetic winterizer tape of similar sizes, after which the bipolymer-mineral tape is welded into a ring, the weight of the ring is 33 g, porosity is 52%. The resulting ring tape is immersed half in water, onto the surface of which 350 g of crude oil is poured. The tape is wrapped around a U-shaped knife to a width of the tape above the oil level and with a slope of 20 ^o to the horizontal plane for gravity flowing oil. The tape is rotated at a speed of 35 revolutions per minute. After 40 seconds, 344 g of oil is collected in a container, the weight of the belt increased by 5 g. Thus, the total weight of oil extracted from water is 349 g, which corresponds to a continuous cleaning efficiency of 99.7%.

Example 3. The natural mineral shungite with a particle size of less than 74 microns and low-density polyethylene of high density with a particle size of less than 300 microns are mixed in a ratio of 100 parts by weight (40 g) of the mineral 100 parts by weight (40 g) polyethylene and form a plate measuring 100x100x10 mm. Heat treatment is carried out at a temperature of +135 ^o C for 35 minutes. (Plate volume 100 cm ³ , plate weight 80 g, porosity 53%). The plate is immersed in a container of water (water volume 3 l) so that one of the edges of the plate is at the water level. 200 g of crude oil is poured into the water. Every 5 minutes, the plate is weighed. After 35 minutes of contact of the plate with water containing oil, the weight of the plate remains constant and is 110 g. Thus, 100 cm ^{3 of the} porous plate holds 30 g of oil, which is 0.3 g per 1 cm ³ . According to "The main directions of application and the efficiency of the use of carbon-containing materials in the urban economy and the city of Moscow" Moscow, 1999, p. 49, the capacity of a bulk filter of shungite with a volume of 1000 cm ³ is 12 g for oil, which corresponds to 0.012 g per 1 cm ³ .

 Example 4. According to example 3, in an aqueous medium contained 75 mg of oil, which corresponds to a concentration of 25 mg / L. After 45 minutes of aging the sorbent in an aqueous medium containing oil, the residual oil content was 0.012 mg, which is less than the permissible norm (0.05 mg / l).

 Example 5. According to example 1. Take tripoli mineral. The remaining conditions are the same. The efficiency of continuous water purification from oil products is 99.7%.

 Example 6. According to example 1. Take the mineral perlite. The remaining conditions are the same. The efficiency of continuous water purification from oil products is 99.6%.

 Example 7. According to example 1. Take the mineral diatomaceous earth. The remaining conditions are the same. The efficiency of continuous water purification from oil products is 99.8%.

 Example 8. According to example 1. Take the mineral flask. The remaining conditions are the same.

 The efficiency of continuous water purification from oil products is 99.8%.

 Example 9. According to example 1. Take the mineral shungite with a particle size of more than 500 microns. When mixed with polyethylene, the mixture exfoliates; it is not possible to obtain a porous sorbent material.

 Example 10. According to example 1. Take polyethylene with a particle size of more than 300 microns. When mixed with a mineral, the mixture exfoliates; it is not possible to obtain a porous sorbent material.

 Example 11. According to example 1. 100 parts by weight mineral take 24 parts by weight polyethylene. After heat treatment, the material has no strength. Crumbles.

 Example 12. According to example 1. For 100 parts by weight mineral take 135 parts by weight polyethylene. After heat treatment, the material has no porosity.

Claims (9)

 1. The method of purification of water from petroleum products by introducing adsorbents into the layer of petroleum products, characterized in that as the adsorbents use porous materials made on the basis of a natural mineral selected from the range of shungite, or tripoli, or perlite, or diatomite, or flask with particle size not more than 500 microns and a thermoplastic hydrophobic polymer with a particle size of not more than 300 microns in the ratio: per 100 weight. including mineral take 25-130 weight. including polymer, the resulting mixture is heat treated at a melt temperature of a thermoplastic polymer for 5-40 minutes  2. The method according to p. 1, characterized in that as a thermoplastic hydrophobic polymer using high or low pressure polyethylene, waste polyethylene, polystyrene, polyvinyl chloride in the form of a powder.  3. The method according to p. 1, characterized in that after heat treatment the sorbent is formed in the form of products of various configurations.  4. The method according to p. 3, characterized in that the adsorbents are formed in the form of disks with dimensions: thickness 5-15 mm, diameter 150-1000 mm  5. The method according to p. 1, characterized in that the adsorbents are formed in the form of cylinders with dimensions: outer diameter 150-1000 mm, length 250-1000 mm, wall thickness 5-15 mm.  6. The method according to p. 2, characterized in that the adsorbent is formed in the form of a continuous tape with a width of 50-1000 mm and a thickness of 1.5-2 mm, and the resulting tape is duplicated on one side of the adsorbent with non-woven polymer material of equal width and thickness not more than 1 mm at a temperature equal to the melting temperature of the polymer non-woven material.  7. The method according to any one of paragraphs. 4-6, characterized in that the disk, cylinder or continuous tape is placed in an aqueous medium contaminated with oil products and rotated at a speed of 1-120 revolutions per minute, and adsorbed oil products are constantly removed with knives, brushes, suction.  8. The method according to p. 3, characterized in that the adsorbent is molded in the form of plates of various configurations, the resulting plates are immersed in an aqueous medium contaminated with oil products, and incubated with a duration necessary to remove oil products from the aqueous medium to the maximum allowable concentrations of 0.05 mg / l  9. The method according to any one of paragraphs. 6-8, characterized in that the regeneration of the adsorbents is carried out by suction or centrifugation, after which the adsorbents are used again.