RU2197321C1 - Surface-cleaning sorbent removing petroleum and petroleum derivatives and a cleaning method using this sorbent - Google Patents

Abstract

FIELD: oil pollution elimination. SUBSTANCE: invention proposes layered sorbent containing basalt fiber material impregnated with active substance and waterproofing agent and provided with reinforcing, shringproofing, and thermocouple-suppressing basalt-cloth elements. Invention provides material composition and method for its use in sorption-regeneration cycles. EFFECT: enabled high cycling of cleaning process, high sorption rate, high oil capacity, and high mechanical strength of sorbent. 4 cl

Description

 The invention relates to the field of ecology and can be used to collect oil and oil products - oils, fuel oil, fuels and hydrocarbons from the surface of the water and / or soil, in response to the consequences of the spill of the latter, as well as their disposal.

 It is known that oil is one of the most significant pollutants that violate the ecology of the world's oceans and inland waters, as well as the land cover of the land.

 One of the areas of environmental protection is the localization of spilled oil, sorption and collection using various sorbents, such as wood shavings, wood flour, hemp, peat, as well as clay, ash, expanded clay, and other mineral components. Synthetic materials based on viscose, synthetic fibers, thermoplastic materials, etc. are also used.

 To give the sorbents hydrophobic properties, they are treated with paraffin, silicone or petroleum oils, monoalkyl ethers of polyethylene glycol, etc. (A.D. Smirnov "Sorption water purification", L., Chemistry, 1982, pp. 92-94).

At the same time, sorption methods of water purification from oil products are mainly developed in the following areas:
a) the distribution of finely dispersed materials on a large surface with subsequent collection;
b) the treatment of contaminated surfaces of water or soil with sorption materials outside the vessel or installation;
c) cleaning in special facilities or ships (same source of information, pp. 93-94).

 A common drawback of the materials used is their insufficiently high sorption capacity for liquid hydrocarbons, and often the inability to reuse them.

 Promising is the use of various fibrous materials, impregnated with the active substance and made in the form of mats, multilayer blocks, etc. (see, for example, RU 2071829, 2071828, 2152250). Fixed sorbents from such materials can be used repeatedly, regenerating them in place by mechanical extraction.

 The closest in technical essence and the achieved result is a sorbent for cleaning and a method for cleaning surfaces from oil and oil products described in RU 2132225, B 01 J 20/28, 1999

Known sorbent contains non-woven fibrous material impregnated with a mixture of fractions of alkyl carboxylic acids from C ₉ to C ₂₇ and aliphatic esters of alkyl carboxylic acids, reinforcing elements of polyethylene filaments in epoxy resin or of thermofibres in thermoplastic polymers and anti-shrink elements of fiberglass.

 A known method of cleaning surfaces involves contacting the obtained sorbent with a cleaned medium and its regeneration.

 The capacity of the obtained sorbent is on average 42-46 kg / kg with the number of sorption-regeneration cycles of 23-36, with a decrease in capacity of 2-5% in each sorption-regeneration cycle.

 The objective of the present invention is to provide increased ability of the sorbent for repeated cyclic use, especially when collecting thick oils.

The problem is solved by the described sorbent for cleaning surfaces from oil and oil products, containing alternating layers of a fibrous base of basalt fibers with a diameter of 0.2-2 microns and a specific surface of 700-1400 m ² / kg, impregnated with an active substance from the class of alkyl carboxylic acids and water-repellent from the class of aliphatic esters of alkyl carboxylic acids, anti-shrink elements from basalt fabric, reinforcing elements from basalt fabric and heat-resistant elements in the form of woven from the outside of the sorbent Gutov or ribbons from the basalt fabric with a specific surface area of 200-700 m ² / kg, wherein the sorbent comprises the above components in the following their Content, wt.%:
Active substance - 1.0 - 5.0
Water repellent - 1.0 - 5.0
Basalt fiber base with V _beats 700-1400 m ² / kg - 70.0 - 93.0
Reinforcing elements - 1.0 - 5.0
Anti-shrink elements - 3.0 - 5.0
Heat resistant elements - 1.0 - 10.0
The problem is also solved by the described method of cleaning surfaces from oil and oil products using the sorbent described above and includes contacting the medium to be cleaned with the sorbent, preferably in a separator, regeneration of the sorbent with steam and additional introduction of the active substance and water repellent into it, preferably in an amount of 0.7- 1.4 wt.% For one sorption-regeneration cycle.

 The claimed sorbent is made as follows.

Take a basalt fiber with a specific surface area of 700-1400 m ² / g with a fiber diameter of 0.2-2.0 μm and place it in a solution containing a mixture of alkyl carboxylic acids, fractions from ₉ to ₂₇ in an organic solvent and an aliphatic ether alkyl carboxylic acids. Fiber is kept in the solution for 1.0-1.5 hours and dried in a stream of air.

Next, anti-shrink elements of basalt fabric with a specific surface area of 200-300 m ² / g are applied to the layer of dried material, and then again a layer of impregnated basalt fiber, then a layer of reinforcing elements of basalt fabric. The resulting layers are stitched to firmly connect them to each other.

The number of layers may vary depending on the required mechanical characteristics of the sorbent. Towels or ribbons of basalt fabric with a specific surface area of 500-700 m ² / g are applied to the outer side of the multilayer stitched web, thereby forming a multilayer web, which is then cut into a specific size of a card or strip depending on further use.

The use of basalt fiber material as a base with specific surface characteristics from 700 to 1400 m ² / kg in combination with the target functional components - reinforcing, anti-shrink and heat-resistant elements from basalt fabrics with V _beats = 200-700 m ² / g, encircling the base from the outside and made in the form of plexuses of bundles and braided tapes, it allows to provide
- the multiple cycles of sorption-regeneration;
- increased rate of sorption of oil, oils, other hydrocarbons;
- resistance to the behavior of technological operations that restore the sorbent (the effects of jets of sharp steam and air flow, providing quick flushing of traces of oil and water from the base and its elements).

 Contacting the resulting sorbent with a contaminated surface can be made by various known methods.

It is recommended to collect oil products from the surface in the following mode:
- contact of the sorbent with oil (delivery to the collection point, lowering into the environment and impregnation);
- sorption (ensuring contact time);
- subsequent separation of the sorbent from the collected substances (exposure to pressure or centrifugal forces);
- treatment with hot steam (for quick cleaning of the sorbent from traces of oil) at t = 100-105 ^o C;
- drainage in the air stream (for quick cleaning of the sorbent from traces of water);
- adding to the sorbent new portions of the active substance and hydrophobic components that complete the restoration of the sorbent for sorption in new cycles.

 The claimed sorbent allows you to increase the number of cycles up to 2000-4000 for one sample of the sorbent. The limit here can be a decrease in the mechanical strength of basalt fibers due to fatigue processes. Reduction of the characteristic sorption time to 10-20 s intervals, realization of the total resource time determined by the product of the characteristic sorption time (10-20) with X (2000-4000) s = (20000-80000) s. Thus, the resource time will be from 6 to 22 hours.

 Studies have shown that with a decrease in the thickness of the oil film spilled over the surface of the water, the characteristic time of its sorption should also decrease significantly. This is especially important when eliminating thin-film pollution in large areas of the water area.

 When the oil film thickness is from a few cm to 20 cm, it is usually necessary to put into operation complex oil collection devices covering the water surface with a film of such a thickness. A similar situation of the oil-water system can occur either in the very early stages of an oil spill, or when oil accumulates ashore near a water edge.

 Designs that work like suction systems will work more efficiently. The sequence of technological operations for collecting oil remains unchanged, and the sorbent does not work by feeding it to the hydrocarbon spill site outside the engineering device, but by sucking the oil and water into the separation unit, where all sorption processes occur. In this case, the bulk of the oil is separated and separated from the water before contact with the sorbent. It is also used at the final stage - after separation. Preliminary separation is especially necessary when oil is collected from the soil and its additional separation from the soil and other impurities is necessary.

 To ensure the continuity of the operation of engineering equipment, the design solutions also provide for the treatment of the sorbent with hot steam, drying in the air stream and a compensatory supply of the active substance and hydrophobic components.

 It is also effective to use sorbent blocks folded in the form of sheets and mounted on movable belt conveyors to clean the water surface.

 A vessel equipped with such a conveyor feeds pillow blocks of the sorbent into the water with oil spilled along the lower branch of the feeder for the required contact time. Further, in the process of movement, the pillow blocks pass to the upper branch of the feeder and fall on board the collecting vessel. Continuing to move backward with the collected oil, the feeder sequentially passes through the technological chambers of squeezing / rolling or other /, washing and drying, a dosed additive of the active substance to reproduce sorbing ability. Passing to the lower branch of the feeder, the updated sorbent block is transported overboard to repeat the collection cycle. The conveyor may contain several tens of sorbent blocks, combined on the feeder tape in the form of framing reinforcement, which allows for quick change of the block as necessary, without stopping the general movement of the conveyor. For changing the operation of the pick-up vessel, the number of cycles can be measured in several thousand.

Claims (3)

1. Sorbent for cleaning surfaces from oil and oil products, containing an alternating layer of a fibrous base, impregnated with an active substance from the class of alkyl carboxylic acids and a water repellent from the class of aliphatic esters of alkyl carboxylic acids, elements from water-shrink fibrous material, a layer of reinforcing elements, characterized in that side sorbent further comprises termoparoustoychivye elements formed as bundles or ribbons from the basalt fabric with a specific surface area of 200-700 m ² / kg, a basis vypol ene of basalt fibers having a diameter of 0.2-2.0 microns with a specific surface of 700-1400 m ² / kg, and antisettling reinforcing elements made of basalt fabric, wherein the sorbent contains components wt. %:
Active substance - 1.0 - 5.0
Water repellent - 1.0 - 5.0
Basalt fiber base with V _beats 700-1400, m ² / kg - 70.0 - 93.0
Reinforcing elements - 1.0 - 5.0
Anti-shrink elements - 3.0 - 5.0
Heat resistant elements - 1.0 - 10.0
2. A method of cleaning surfaces from oil and oil products, including contacting the medium to be cleaned with a sorbent and its regeneration, characterized in that the sorbent according to claim 1 is used, the regeneration is carried out with direct steam, after which the sorbent is dried and an active substance and a hydrophobic component are additionally introduced into it .  3. The method according to p. 2, characterized in that it further introduces the active substance and water repellent in an amount of 0.7-1.4 wt. % per cycle sorption-regeneration.  4. The method according to p. 2 or 3, characterized in that the contacting of the cleaned medium with the sorbent is carried out in a separator.