EA011784B1 - Surface-modified activated carbon in smoking articles - Google Patents

Abstract

A surface-modified activated carbon is provided to reduce the amount of free fine carbon particles among the activated carbon. By surface-modifying the activated carbon with a layer, the activated carbon can have increased mechanical strength and the fine carbon particles among the activated carbon can be fastened to the layer. Therefore, the layer allows for the level of free fine carbon particles among the activated carbon to be reduced. Surface-modified activated carbon can be used in smoking articles so as to allow for adsorption by the activated carbon with reduced free fine carbon particles in the smoking article and the smoke produced.

Description

The present invention relates to activated carbon treated to reduce the content of fine particles in smoking articles.

In the first embodiment of the present invention, activated carbon is treated to reduce the formation and presence of fine particles in smoking articles. The surface of the activated carbon is modified in order to improve the mechanical integrity of the activated carbon and, thus, reduces the susceptibility of activated carbon to form fine particles. The surface of the activated carbon is also modified to attach or bind existing fine particles to the activated carbon to reduce the presence of fine particles. The surface of the activated carbon can be modified by forming a layer of hydrocarbon compound, a polymer layer or a layer of carbon on the outer and inner surfaces of the activated carbon.

In another embodiment of the present invention, a cigarette comprises a tobacco rod comprising tobacco and a filter, in which the above filter includes surface-modified activated carbon containing activated carbon; fine particles of coal on the surfaces of activated carbon and a layer on the inner surface and on the outer surface of activated carbon in which the layer contains a hydrocarbon compound, an additional layer of carbon or polymer on activated carbon, in which if the layer is a polymer, the amount of polymer is about 9-20 wt.% of the total weight of surface-modified activated carbon.

In yet another embodiment of the present invention, the cigarette filter comprises an empty cavity filter in which the above cavity is filled with surface modified activated carbon containing activated carbon; fine particles of coal on the surface of activated carbon and a layer on the inner surface and outer surface of activated carbon, in which the layer contains a hydrocarbon compound, an additional layer of carbon or polymer on activated carbon, in which if the layer is a polymer, the polymer is about 9-20 wt. % of the total weight of surface-modified activated carbon.

In yet another embodiment of the present invention, a method of producing cigarettes involves forming a surface-modified activated carbon by providing activated carbon having fine particles of coal on its surface, and forming a layer on the inner and outer surfaces of the activated carbon, in which the layer contains a hydrocarbon compound, an additional layer of carbon or a polymer on activated carbon, in which if the layer is a polymer, then the polymer is about 9-20 wt.% of the total weight of erhnostno-it modified activated carbon; introducing the surface-modified activated carbon into the cigarette filter and attaching the cigarette filter to the tobacco rod to form a cigarette.

In yet another embodiment, a method for treating mainstream tobacco smoke comprises passing mainstream tobacco smoke through a filter comprising surface-modified activated carbon, comprising: activated carbon; fine particles of coal on the surfaces of activated carbon and a layer on the inner and outer surfaces of activated carbon in which the layer contains a hydrocarbon compound, an additional layer of coal or a polymer on activated carbon, in which if the layer is a polymer, the polymer is about 9-20 wt.% of the total weight of surface-modified activated carbon.

Activated carbon is a generic term used to describe a group of carbon-containing adsorbents with an extensively developed internal pore structure.

Activated carbon can be obtained by activating amorphous (not containing graphite) carbon, in which amorphous (not containing graphite) carbon can be obtained by carbonizing starting material such as wood, lignite, coal, coconut shell, peat, resin, polymers, cellulose fibers or polymer fibers, etc., with the formation of char. Preferably, the carbonization is performed at high temperatures, i.e. 300-1000 ° C, preferably above 600 ° C in an inert atmosphere. After carbonization, activation can be accomplished by heating amorphous carbon or semi-coke with an oxidizing reagent, such as carbon dioxide or steam. During activation, a certain amount of amorphous carbon or semi-coke interacts with an oxidizing reagent, and pores of various sizes of different order, for example, from angstroms to microns, form in activated carbon.

Activated carbon can be in the form of granules, balls, monoliths, beads, powder or fibers. In embodiments of the present invention, the activated carbon may have an average particle size of from 6 to 300 mesh.

Activated carbon may include micropores, mesopores and macropores. The term "microporous" generally refers to such materials whose pore size is about 20 A or less, while the term "mesoporous" generally refers to such materials that have a pore size of about 20-500 A. The term " macroporous "generally refers to materials whose pore size is approximately 500 A. The relative amount of micropores, mesopores, and macropores can be pre-selected, depending on the target components of the mainstream tobacco smoke to be removed. Thus, the pore size and pore distribution can be regulated.

- 1,011,784 in accordance with the objectives of a particular use.

Activated carbon can be injected into one or more places in smoking articles. Activated carbon is preferably placed in a filter to reduce its interaction with tobacco, such as tobacco in a tobacco rod. For example, activated carbon can be placed in a through-hole of a hollow filter with free circulation, in a filter with free circulation, mixed with fiber and / or in an empty space.

Highly activated carbon, by its nature, contains dust due to its inherent porous structure resulting from rigid carbonization and activation.

Fine particles of coal or coal “dust” with a particle size of less than 10 microns are often formed during either one or both of the carbonization and activation processes, due to the rigidity of the processes affecting the mechanical integrity of the activated carbon. Moreover, during the production of cigarettes, in which particles of coal are added to the cavity of a cigarette filter, mechanical control of the particles of coal can lead to the additional formation of fine (fine) particles.

During smoking, it is advisable to avoid such fine particles in the stream of smoke passing through a cigarette.

Traditionally, these fine particles have been removed by washing the activated carbon with water with stirring. However, additional fine particles may be formed after washing, since activated carbon to some extent has a brittle structure.

The amount of fine particles and the mechanical strength of the activated carbon vary depending on the source of the source material and activation. For example, activated carbon derived from low density starting materials, such as coconut shells, tends to have low density and low mechanical strength, rather than activated carbon obtained from high density starting materials, such as resin. However, the treated resin is a more expensive product and may not be available in some forms, such as particles, for example. Thus, inexpensive activated carbon may have a lower mechanical strength and, thus, may also lead to an increase in the number of fine particles.

Additionally, after the activation process, fine particles can also be formed due to the fragile, to some extent, structure of activated carbon, which was mentioned above in the text of the patent application. For example, when activated carbon is provided in smoking articles, fine particles may form in smoking products as a result of friction, rubbing between particles of activated carbon and compaction of activated carbon during packaging, transportation and / or other processing of activated carbon. Therefore, the embodiments provided for in this patent application increase the mechanical strength of the activated carbon and, in turn, reduce the amount of fine particles present.

As used in this patent application, the term “surface-modified activated carbon” includes mechanically reinforced activated carbon coated with a layer or activated carbon that has undergone surface modification by forming a layer on it, followed by processing a layer in order to transform the layer into a surface of a more durable modification .

A preferred embodiment includes a method for reducing the amount of fine particles by forming surface-modified activated carbon, in order to reduce the presence and formation of fine particles in smoking articles. By obtaining a surface-modified activated carbon, activated carbon may have increased mechanical strength, preventing breakage, and the formation of fine particles will be reduced. Additionally, through the use of surface-modified activated carbon, any fine particles present can be attached to the surface of the surface-modified activated carbon, thereby reducing contamination by fine particles of smoking articles.

As used herein, the term "hydrocarbon compound" includes low molecular weight hydrocarbons, while the term "polymer" includes high molecular weight hydrocarbons, as well as other polymer compositions. For example, typical hydrocarbon compounds include waxes, paraffins, etc., while typical polymers include polypropylene, pectin, etc.

It is envisaged that the activated carbon may be surface-modified by forming a layer of a hydrocarbon compound, such as wax, on the activated carbon, in which the hydrocarbon compound can be attached to the outer and inner surfaces of the activated carbon. By this attachment, the hydrocarbon compound can strengthen the activated carbon by increasing the mechanical integrity of the activated carbon, as well as binding the fine particles by coating the fine particles in the bed.

Alternatively, the surface of the activated carbon is modified by forming a layer of a polymer, such as propylene or pectin, on activated carbon, in which a polymer similar to wax,

- 2 011784 can be attached to the external and internal surfaces of activated carbon. In addition, by this attachment, the polymer can strengthen the activated carbon by increasing the mechanical integrity of the activated carbon, as well as bonding the fine particles by coating the fine particles in the layer.

Or, as another alternative, surface-modified activated carbon can be formed by applying an aromatic compound, such as a resin, to the outer and inner surfaces of the activated carbon before heat treating the aromatic compound and the activated carbon to form a carbon layer on the activated carbon. By forming this carbon layer on the porous frame of the activated carbon, some pores can be filled, thus changing the pore distribution of the activated carbon. Also, the addition of a carbon layer allows you to increase the density of activated carbon, which, in turn, can cause an increase in the strength of activated carbon. Also, the addition of a carbon layer allows the fine particles to be bonded by means of the carbon layer. As a result, the carbon layer can be formed when using the source material with a higher density, rather than the source material used to produce activated carbon. When using, for example, a resin as a starting material for producing a carbon layer and, at the same time, using coconut shell as a starting material for producing activated carbon, activated carbon containing a carbon layer can be formed with increased mechanical strength due to the carbon layer obtained from the starting resin , with reduced cost, thanks to the provision of a base of activated carbon obtained from a less expensive coconut shell starting material.

As mentioned above, surface-modified activated carbon improves mechanical strength and reduces the amount of fine particles of activated carbon. It is desirable that the surface modification can be used to reduce the fragility of activated carbon and to reduce the number of broken segments of activated carbon that can be released in the smoking article during storage.

If a hydrocarbon compound is used to modify the surface of an activated carbon, then a hydrocarbon compound may form on the inner and outer surfaces of the activated carbon. First of all, a liquid solution is obtained, preferably a homogeneous liquid solution, by melting or dissolving the hydrocarbon compound in a solvent or mixture of solvents. The activated carbon can then be suspended in a liquid solution to impregnate the activated carbon with a hydrocarbon compound, thus covering the inner and outer surfaces of the activated carbon with a hydrocarbon compound. Further, the solvent can be removed by evaporation or extraction of the solvent from activated carbon to obtain a layer of a hydrocarbon compound, preferably a thin, uniform layer on the inner and outer surfaces of the activated carbon.

When a hydrocarbon compound layer is formed on activated carbon, fine particles present on the inner or outer surfaces of the activated carbon can be trapped inside the hydrocarbon compound layer or can be coated or bonded on the inner or outer surface of the activated carbon by means of the layer, thus reducing the number of free fine particles. In addition, a layer of hydrocarbon compound on the activated carbon can increase the mechanical integrity of the activated carbon in such a way that if the activated carbon with the applied layer is subjected to vibration or other mechanical action, a smaller amount of fine particles is formed and / or released, which in turn reduces content of fine particles. In other words, for example, a viscous wax layer may form on activated carbon, in which a viscous wax layer adheres to both activated carbon and fine particles, and the viscous wax layer also increases the mechanical strength of the activated carbon due to its viscosity.

Preferably, the hydrocarbon compound is either non-polar or weakly polar to minimize surface tension between the hydrocarbon-compound layer and activated carbon, which is often weakly polar. By using non-polar or weakly polar hydrocarbon compounds, improved polarity-based layer homogeneity can be achieved. In addition, non-polar or weakly polar hydrocarbon compounds may alter the selectivity of activated carbon relative to the target non-polar or weakly polar smoke components.

The hydrocarbon compound is preferably a low volatility material, with a boiling point above about 150 ° C with approximately one atmosphere with low vapor pressure under normal conditions to ensure the stability of the hydrocarbon compound on activated carbon. Thus, it may be that the hydrocarbon compound does not evaporate while smoking a cigarette with activated carbon coated with a hydrocarbon compound. Non-limiting examples of hydrocarbon compounds that can be used to coat activated carbon include waxes, normal and branched paraffins, or polymeric hydrocarbons, and hydrocarbon compounds can be used in solid and liquid form. However preferred

- 3 011784 that such hydrocarbon compounds have a high viscosity on activated carbon to prevent migration. Typical solvents include, but are not limited to, organic solvents such as ethers, acetone, MEK (methyl ethyl ketone), hexane, toluene, and xylene.

As an alternative to hydrocarbon compounds, as mentioned above, polymers can also be used to coat activated carbon. If the polymer is used to modify the surface of the activated carbon, then the polymer may form on the inner and outer surfaces of the activated carbon. First of all, it is preferable to obtain a liquid solution, preferably a homogeneous liquid solution, by melting or dissolving the hydrocarbon compound in a solvent or mixture of solvents. The polymer can then be loaded into the activated carbon, allowing the liquid solution to impregnate the activated carbon, thereby saturating the activated carbon with the polymer. The impregnating polymer can then form a polymer layer, preferably a thin, uniform throughout the thickness, layer on the inner and outer surfaces of the activated carbon. For example, a layer of activated carbon can be applied to the activated carbon by impregnating with a liquid solution at the initial stage, by passing a stream through an activated carbon layer or by soaking the coal in a liquid solution and then removing the excess solution. Further, a gradual heat treatment can be performed to release the solvent and open the porous structure of the activated carbon without adversely affecting the internal, porous structure of the activated carbon. For example, to release a solvent, such as hexane, a gradual heat treatment may be used in the temperature range from 100 to 300 ° C.

Preferably, the amount of polymer deposited on the activated carbon is about 920% by weight of the total weight of the polymer covering the activated carbon in order to provide mechanical strength, while ensuring the availability of pores and, consequently, the properties of the activated carbon to adsorb smoke. Alternatively, the polymer is preferably used in an amount of about

10-18, 11-17, 12-16, 10-12, 12-14, 14-16, 16-18 or 18-20 wt.% To balance the mechanical strength of activated carbon with the adsorption properties of activated carbon.

In addition to the advantages mentioned above, another advantage of using a polymer layer is that the polymer layer can have electrical charges capable of trapping fine particles with electrical forces, such as static electricity.

Additionally, the permeability of the polymer layer can be configured in such a way as to make possible the selective adsorption of certain components using activated carbon with a coated layer. For example, activated carbon with a polymer layer in a cigarette filter may include a polymer specifically selected, which allows activated carbon to selectively adsorb carbon monoxide or other specific gaseous constituents of cigarette smoke when a cigarette is smoked.

Typical polymers are non-toxic and are preferably decomposed by the action of a biological factor and / or are permeable to smoke so that cigarette smoke can penetrate the polymer to access activated carbon. In addition, it is preferable that typical polymers are approved by the Food and Drug Administration (ΕΌΑ) and have a long shelf life. Examples of such polymers include, but are not limited to, synthetic polymers such as polypropylene, polyethylene, polysiloxane, polyethylene oxide, polyethylene glycol, polyacrylic acid, polyvinyl acetate, polyvinyl alcohol, various polyethylene oxide-polypropylene oxide block copolymers, other copolymers, or other block copolymers, or derivatives thereof, and / or natural polymers, such as pectin, alginate or starch.

Preferably, typical solvents or cosolvents have relatively low boiling points and can dissolve the typical polymers listed above, typical solvents include, but are not limited to the following examples: water, an alcohol such as methanol or ethanol, or hexane.

If a carbon layer of an aromatic compound, rather than hydrocarbon compounds or polymers, is used to modify the surface of the activated carbon, an aromatic compound may form on the inner and outer surfaces of the activated carbon. First of all, a liquid solution is obtained, preferably a homogeneous liquid solution, by melting or dissolving the aromatic compound in a solvent or mixture of solvents. Then it is possible to obtain a suspension of activated carbon in a liquid solution to saturate the activated carbon with an aromatic compound, respectively covering the inner and outer surfaces of the activated carbon. Further, the solvent can be removed by filtration, evaporation or extraction of the remaining solvent.

After removal of the solvent, the coated activated carbon can be stabilized by heating in accordance with a predetermined heating plan, such that aromatics can be converted to a stabilized, refractory form before carbonization. Further, aromatic compounds in stabilized, refractory form can be carbonized by heat treatment of aromatic compounds in stabilized, refractory

- 4 011784 form of activated carbon in an inert atmosphere.

By carbonizing aromatics in a stabilized, refractory form, a new carbon layer can form on the surfaces of activated carbon.

Preferably, the carbon layer on the activated carbon is not activated by itself, since the activation of the carbon layer may cause the loss of at least part of the carbon layer and reduce its mechanical strength. Thus, although it is possible to perform the activation of the carbon layer, such activation is not preferable due to possible loss problems.

Examples of aromatics that may be used include, but are not limited to, oil pitches, coal tar and pine tar tar, other natural or synthetic aromatics, and mixtures thereof. These aromatic compounds are preferred due to their high density, which, in turn, after carbonization leads to a higher mechanical strength of coal compared to what can be achieved by carbonizing carbon-containing low-density starting materials. Thus, by applying and carbonizing the starting material, which is a resin, to activated carbon from a starting material with a low density, it is possible to obtain high mechanical strength of the carbonized resin on activated carbon from a starting material of low density and low cost.

Examples of solvents that can be used to melt or dissolve aromatics may include, but are not limited to, N-methyl-2-pyrrolidinone (ΝΜΡ), quinoline, trichlorobenzene, toluene, xylene, other solvents used to dissolve aromatics or mixtures thereof .

Smoking products

Preferably, types of surface-modified activated carbon are used in smoking articles, especially in the field of filter smoking products. Smoking articles according to the invention include cigarettes, such as traditional and non-traditional cigarettes, cigars and other smoking devices. Non-traditional cigarettes include, for example, cigarettes for electric smoking systems, as described in US Patents 6,206,620, 5,988,176, 5,915,387, 5,692,526, 5,692,525, 5,666,976 and 5,499,636 (all of this Applicant), the description of which is incorporated into this description by reference.

Cigarettes usually contain two parts: a part containing tobacco, which is often called a tobacco or cigarette rod, and a filter, which can be called a filter mouthpiece. The tipping paper overlaps the end of the tobacco rod to hold the tobacco rod and filter together.

The tobacco rod or cigarette element containing tobacco typically includes cigarette paper in which the rifled tobacco is wrapped, using an adhesive substance that holds together the seams of the paper.

When a tobacco rod is ignited or heated to smoke, the main stream of tobacco smoke passes from the burning or heated end in a downward direction to the end of the tobacco rod filter and then downward through the filter.

The term “mainstream smoke” includes gases and / or aerosols passing through a tobacco product, such as a tobacco rod, and exiting an end, such as the end of a filter, i.e. the amount of smoke emitted or released from the cigarette mouthpiece when smoking a cigarette. The mainstream smoke contains air that is drawn in through the hot area of the cigarette and through cigarette paper.

“Smoking” a cigarette (or a smoking article) usually involves igniting one end of a cigarette and drawing in a downward flow of smoke through the cigarette mouth, while the tobacco contained there is subjected to a burning or heating reaction. However, cigarettes can also be smoked in other ways. For example, cigarettes can be smoked by heating a cigarette with an electric heating element, as described, for example, in US Pat. Nos. 6,053,176, 5,934,289, 5,591,368 or 5,322,075 (all of this applicant), each of which is incorporated into this description by reference.

Examples of suitable types of tobacco materials that can be used include, but are not limited to, thermally dried tobacco, Burley tobacco, Maryland tobacco, Oriental tobacco, raw tobacco, special tobacco, homogenized tobacco, their bags, and the like. Tobacco material may be provided in any suitable form, including, but not limited to, tobacco lamina, recycled tobacco materials, such as blasted tobacco or blown up tobacco, recycled tobacco veins, such as cut and rolled veins and blasted veins, recycled tobacco material waste, their bags, etc. Can also be used tobacco substitutes.

In the production of cigarettes, tobacco is usually used in the form of cut filler, that is, in the form of cut strips or veins, with a thickness in the range from 1/10 to about 1/20 inch or even 1/40 inch. The length of the strips is in the range of 0.25 to about 3.0 inches. In addition, cigarettes may contain one or more flavors, as described above in the patent application, or other additives (for example, substances that promote combustion, substances that modify the burning, coloring agents, binders, etc.).

The filter material can be any of a variety of fibers for use in elements.

- 5 011784 filter of smoking articles. Typical materials include cellulose acetate, polypropylene or paper. Preferably the filter material will be cellulose acetate.

A variety of cigarette filter designs can be used in which typical filter structures that can be used include, but are not limited to, the following examples: monofilter, double filter, triple filter, filter with one or more cavities (cavities), indented filter, filter with free circulation, their combination, etc.

Monofilters usually contain cellulose acetate fiber or pulp and paper materials. Pure cellulose monofilters or paper filters ensure good tar and nicotine retention and easily decompose. Double filters usually contain a cellulose acetate in the mouthpiece and a clean cellulose or cellulose acetate segment. The length and resistance to broaching of the segments in the double filter can be adjusted to ensure optimal sorption, while maintaining acceptable resistance to broaching. Triple filters can include a mouthpiece and smoking material or tobacco-side segments and a middle segment containing paper. Filters with voids include two segments, for example acetate-acetate, acetate-paper or paper-paper, separated by at least one cavity. Indented filters include an open cavity on the mouthpiece.

Preferably, the surface-modified activated carbon is provided in the filters of smoking articles, as mentioned above in the text of the patent application. Filters may also be ventilated and / or may additionally include surface modified activated carbon, other sorbents, catalysts, or other additives suitable for use in filters of smoking articles.

The above changes and modifications will be apparent to a person skilled in the art. Such changes and modifications are within the scope of the appended claims.

Claims (29)

1. A cigarette comprising a tobacco rod comprising tobacco and a filter, said filter comprising a surface-modified activated carbon containing activated carbon, fine particles of carbon on the surface of the activated carbon, and an additional layer of coal on the surface of the activated carbon. 2. The cigarette according to claim 1, wherein said coal layer contains non-activated carbon, which at least partially fills the pores in the surface-modified activated carbon. 3. The cigarette according to claim 1, wherein said carbon layer has a different density than activated carbon and modifies the pore size distribution of the activated carbon. 4. The cigarette according to claim 1, in which the specified layer of coal has a higher density than activated carbon. 5. The cigarette according to claim 1, in which the activated carbon contains granules, beads, monoliths, beads, powder or activated carbon fibers. 6. The cigarette according to claim 1, in which the specified layer of coal captures the fine particles of coal in the mass of this layer, attaches the fine particles of carbon to the surfaces of the activated carbon layer or increases the mechanical strength of the surface-modified activated carbon to a higher mechanical strength than activated carbon without the specified layer. 7. The cigarette according to claim 1, in which the specified layer of coal has a thickness sufficient to at least partially cover the activated carbon and fine particles of coal. 8. The cigarette according to claim 1, in which the specified layer of coal is effective for adsorption of the target component of the gas phase when smoking a cigarette. 9. The cigarette according to claim 1, in which the specified layer of coal is electrically charged, to attach the fine particles of coal to the surface of the layer with a force greater than the force of the stream of smoke generated when smoking cigarettes. 10. The cigarette according to claim 1, in which the surface-modified activated carbon is located in the filter cavity. 11. The cigarette according to claim 1, in which the diameter of the fine particles of coal is less than 10 microns. 12. A cigarette filter containing a filter with a cavity containing surface-modified activated carbon, including activated carbon, fine particles of carbon on the surface of activated carbon and an additional layer of carbon on the surface of activated carbon. 13. The cigarette filter of claim 12, wherein said coal layer contains non-activated carbon, which at least partially fills the pores in the surface-modified activated carbon. 14. The cigarette filter of claim 12, wherein said coal layer has a higher density, - 6 011784 than activated carbon, and modifies the pore size distribution of activated carbon. 15. The cigarette filter of claim 12, wherein the activated carbon comprises granules, beads, monoliths, beads, powder or activated carbon fibers. 16. The cigarette filter of claim 12, wherein said coal layer captures finely dispersed carbon particles in the mass of this layer, attaches the finely dispersed carbon particles to the surfaces of the activated carbon layer, or increases the mechanical strength of the surface-modified activated carbon to a higher mechanical strength than that of activated carbon coal without the specified layer of coal. 17. The cigarette filter of claim 12, wherein said carbon layer has a thickness sufficient to at least partially coat activated carbon and fine particles of coal. 18. A method of producing cigarettes, comprising the formation of a surface-modified activated carbon by producing activated carbon having fine particles of carbon on its surface, and forming a layer of coal on the surface of the activated carbon, incorporating a surface-modified activated carbon into a cigarette filter and attaching the cigarette filter to the tobacco the core for the formation of a cigarette. 19. The method according to p. 18, in which the formation of the specified coal layer on the surfaces of activated carbon includes melting or dissolving the layer-forming material in a solvent or mixture of solvents to obtain a liquid solution, suspending the activated carbon in said liquid solution to soak the activated carbon layer-forming material and removal of a solvent or mixture of solvents. 20. The method according to claim 19, in which the melting or dissolving the layer-forming material in a solvent or mixture of solvents comprises mixing or dissolving the oil pitch, coal tar pitch, coniferous pitch or synthetic aromatic polymer in a solvent or solvent mixture. 21. The method according to claim 19, in which the melting or dissolving the layer-forming material in a solvent or mixture of solvents comprises mixing or dissolving the aromatic compound in 1-methyl-2-pyrrolidinone (ΝΜΡ), quinoline, trichlorobenzene, toluene, xylene or a mixture thereof . 22. The method according to claim 19, in which activated carbon suspended in a liquid solution for impregnation with a layer forming material comprises granules, spheres, monoliths, beads, powder or activated carbon fibers in the form of a suspension. 23. The method according to claim 19, in which the activated carbon suspended in a liquid solution for impregnation with a layer-forming material comprises suspended activated carbon and fine particles of carbon in a liquid solution for impregnating activated carbon with a layer-forming material that traps the fine particles of coal in this layer. 24. The method according to claim 19, in which activated carbon suspended in a liquid solution for impregnating it with a layer-forming material comprises activated carbon in the form of a suspension and fine particles of coal with a diameter of less than 10 μm in a liquid solution to impregnate activated carbon with a layer-forming material and attach fine particles of carbon to the surfaces of activated carbon. 25. The method according to claim 19, in which the step of forming the layer further comprises carbonizing the layer forming material by heating the layer forming material after removing the solvent or mixture of solvents, wherein carbonizing the layer forming material produces a carbon layer with a density different from activated carbon. 26. The method according A.25, in which the carbonization of the layer-forming material includes heating the layer-forming material in an environment with a temperature of from about 300 to 1000 ° C. 27. The method according to claim 19, in which the suspension of activated carbon in a liquid solution for impregnating activated carbon with a layer-forming material comprises wetting the activated carbon with a layer-forming material, passing the layer-forming material through an activated carbon layer, or soaking the activated carbon in the layer-forming material. 28. A method of treating a main stream of tobacco smoke, comprising drawing in smoke from a smoking article, wherein the smoke passes through a filter containing surface-modified activated carbon, including activated carbon and an additional layer of carbon on the inner surface and the outer surface of the activated carbon. 29. The method according to p, in which the specified layer of coal provides a decrease in the number of free fine particles in the smoking product when passing the retractable smoke through a filter containing surface-modified activated carbon.