RU2504309C2 - Tobacco smoking filter - Google Patents

Abstract

FIELD: tobacco industry.

SUBSTANCE: invention relates to a tobacco smoking filter or filter element that contains a cylindrical core made of essentially homogenous filtering material with the circumference equal to 14.0-23.2 mm, the essentially homogenous filtering material containing a large quantity of staple fibres that are randomly oriented in the three coordinates.

EFFECT: ensuring improved filtration.

17 cl, 3 dwg

Description

The present invention relates to filters and filter elements for smoking products, such as cigarettes, in particular thin cigarettes.

Traditional cigarettes have a circumference of 24.5 mm; thin cigarettes (circumference from 21 to 23.5 mm) and superthin cigarettes (circumference from 16 to 18 mm) are also known. In addition, it is possible to manufacture cigarettes with an even smaller circumference, for example in the range of 14 to 16 mm, although they are not widely distributed commercially. In the context of this document, the term "thin" should be understood as including all cigarettes and / or cigarette filters with a circumference between 14 and 23.2 mm.

Selective filtering occurs when the yield of individual chemicals in cigarette smoke is proportionally reduced to a greater extent than most formulations in smoke (e.g. tar). Phenolic compounds, for example phenol, cresol, catechin and resorcinol, are known constituents of cigarette smoke. They are toxic components, in particular, phenol and catechin are included in the so-called "Hoffman List" containing the most dangerous compounds found in cigarette smoke. Obviously, the desire to possibly selectively reduce the smoker's consumption of these compounds.

Conventional filter media used in cigarette filters are elongated bundles of fibrous cellulose acetate plasticized with triacetin, which are assembled together in the form of a rod to form a filter or filter element. In such an elongated tow (and filters or filter elements formed therefrom), the cellulose acetate tow fibers are predominantly oriented in parallel in the longitudinal direction. It is well known that cellulose acetate exhibits a selective filtering effect on phenolic compounds. The filter for thin cigarettes should naturally contain less cellulose acetate filter material than a standard filter. Any selective filtering effect can be reduced if less material is used to counteract the same amount of smoke. Thus, it is desirable to develop a thin filter, which, if possible, would reduce the amount of phenolic compounds consumed by the smoker of thin cigarettes.

The characteristics of the filter tow are described by the following concepts: denier per thread (dpf); total denier; and cross-sectional shape of the fiber. Denier is defined as the weight in grams of 9,000 meters of a single filament: the total denier is determined by simply multiplying dpf by the number of filaments in the bundle.

That is, for example, a bundle of 5Y30000 means a material with threads with dpf 5 grams per 9000 meters, having the shape of the letter Y, containing 6000 threads, giving a total denier of 30,000 grams per 9000 meters of length. To produce a standard cellulose acetate (“monoacetate”) cigarette filter having a small circumference (for example, a thin monoacetate filter), it is necessary to use a cellulose acetate tow with a small total denier, as there are restrictions on the amount of material that can be placed in a thin product . In the cigarette filter industry, it is well known that a bundle with a small total denier is more expensive (per unit weight) than a bundle with a higher total denier, and the commercial availability of a bundle with a small total denier is also limited. Thus, it is preferable to create a thin filter that can be made from cellulose acetate tows with a wider range of total denier than traditional thin or superthin monoacetate filters.

According to the present invention, there is provided a tobacco smoking filter or a filter element comprising a cylindrical rod of a substantially uniform filter material with a circumference of between 14.0 and 23.2 mm (or, for example, between 16 and 23.2 mm), wherein the substantially uniform filter material contains a large number of randomly oriented staple fibers.

As used herein, the term “substantially uniform filter material” means a material that has substantially the same physical properties in any cross section.

In this document, the term "staple fibers" means single, separate fibers of a certain length. Staple fibers can be randomly oriented relative to each other. A substantially uniform filter material may contain a large number of randomly oriented staple fibers, and some randomly oriented staple fibers are typically located across the longitudinal axis of the cylindrical rod. A substantially uniform filter material may contain a large number of randomly oriented staple fibers of at least 10% by weight (or, for example, 20%, 30%, 40%, 50%, 60%, 70%, 80%, or 90%) which are located across the longitudinal axis of the cylindrical rod.

The term "randomly oriented staple fibers" means that the staple fibers are randomly oriented in three coordinates (in the filter or filter element). The term “randomly oriented staple fibers” is not intended to mean (and does not mean) a continuous cellulose acetate tow, the individual strands of which are mainly oriented in parallel in the longitudinal direction (although it is understood that staple fibers can be formed from such tows as described below) . In this document, the term “randomly oriented staple fibers” is not intended to mean (and does not indicate) a web or sheet of filter material that is first obtained (for example, from pulp or fibers) and then shaped to a core or almost all of the web or sheet (e.g. by folding). The term "randomly oriented staple fibers" does not mean a two-dimensional paper-like product in a wrapped state. In this document, the term "randomly oriented staple fibers" is not intended to mean (and does not indicate) a web or sheet of filter material that is obtained (for example, from pulp or fibers) and then cut and shaped into a rod. Sheets or sheets can be randomly oriented in two coordinates, but (even when cutting) they are subjected to influences (for example, corrugation), so that they retain some integrity when passing through a filter manufacturing machine. Thus, a filter or filter element made of a sheet or web (including a cut sheet or web) is mainly oriented parallel to the longitudinal axis of the filter or filter element and thus contains staple fibers oriented in a nonrandom fashion (in three coordinates) .

A large number of randomly oriented staple fibers can form a porous matrix having a labyrinth of channels that can serve as channels for smoke when using this matrix as a cigarette filter. Applicants have found that the characteristics of a filter or filter element made in accordance with the invention can be compared with existing products (for example, "monoacetate" formed from a continuous strand of longitudinally oriented cellulose acetate fibers, plasticized triacetin and rod-shaped), but Applicants have also found that this requires 20-30% less filter material (e.g. cellulose acetate) when it is used in the form of randomly oriented staple fibers. In addition to the need to use less filter media per filter, there is a promising advantage that cellulose acetate tows with a much larger total denier can be used than in traditional superthin products. Thus, in addition to the cost advantages of the weight savings achieved by the applicant’s invention (since less filter material is required), the unit cost of the harnesses used will also be less, since the (low-cost and less easily accessible) harnesses should no longer be used common denier.

Applicants have unexpectedly discovered that a tobacco smoking filter or filter element in the invention can provide improved removal of phenols from tobacco smoke (in thin cigarettes) compared to, for example, a standard monoacetate filter or filter element (which does not contain randomly oriented staple fibers). The unexpected decrease in the transmission of phenolic compounds by filters and filter elements in the invention is even more significant if we take into account the lower mass of the filter material (cellulose acetate). Applicants have also unexpectedly discovered that a tobacco smoking filter or filter elements made in accordance with the invention more easily and quickly break down under the influence of, for example, environmental conditions, compared to, for example, a standard monoacetate filter or filter element.

Staple fibers can be obtained from fibrous material.

Staple fibers can be crimped, which is well known in the art. Staple fibers can be, for example, acetate cellulosic or polypropylene fibers. Staple fibers can be formed (or formed) from a fiber tow, for example, cellulose acetate tow, polypropylene tow. Staple fibers can be, for example, natural and / or synthetic fibers; fibers obtained from natural plant material, etc. Staple fibers can be pulp fibers (for example, which are fluffed with a hammer mill). Staple fibers may be chopped plants (e.g., cut tobacco leaf), or may be obtained from reconstituted tobacco leaf. Staple fibers can impart flavor and / or filtering properties to the final product. Staple fibers can be essentially the same length (basically the same length). Staple fibers can be of various lengths. Staple fibers can, for example, have a length between 4 mm and 20 mm, for example, between 5 mm and 19 mm, for example, between 6 mm and 18 mm, for example, between 7 mm and 16 mm. Staple fibers can be made or formed from a fiber tow, for example, cellulose acetate tow, with a total denier of 14,000 g to 55,000 g per 9,000 m long, for example, 20,000 g to 50,000 g per 9,000 m long, for example, 23,000 g to 45,000 g per 9,000 m length, for example, from 25,000 g to 40,000 g per 9,000 m length.

The substantially uniform filter material may further comprise other materials, for example, a liquid additive (such as a flavoring agent, for example, a menthol solution). A substantially uniform filter material containing a large number of randomly oriented staple fibers may be formed from a large number of staple fibers, and may further comprise another material, for example, a plasticizer, a binder, or other additive. Staple fibers can be connected to each other (for example, by the action of a plasticizer) in a large number of contact points.

The substantially uniform filter material may further comprise a binder material. The substantially uniform filter material may further comprise a water soluble binder. Examples of water soluble materials include water soluble polymeric materials such as polyvinyl alcohol, polyvinyl pyrrolidone, polyvinyl ether, starches, polyethylene glycols and polypropylene glycols; mixtures of water soluble binders with a plasticizer such as triacetin; and hot-melt, water-soluble binders in solid form. The inclusion of water-soluble binder materials can also increase the ability of a filter or filter element to easily and quickly break down, for example, under the influence of external conditions.

The filter or filter element may contain one or more additives from solid particles, for example, inside the filter body or filter element. This (or each) particulate additive can be powder (for example, particles from 50 to 150 microns in diameter) or granular (for example, particles from 0.15 to 1 mm in diameter). Examples of suitable particulate additives include flavors or sorbents, for example, activated carbon, zeolite, ion exchange resin (e.g. weakly basic anion exchange resin), sepiolite, silicate gel, alumina, molecular sieves, carbonaceous polymer resins and kieselguhr.

A filter or filter element may contain more than one type of staple fiber. For example, staple fibers, which are fibers (e.g., pulp) that are fluff from a hammer mill, can be included in the filter in addition to (or mixed with) staple fibers formed from a fiber tow.

Staple fibers (e.g., fiber tow or cellulose acetate tow) can be plasticized. In other words, the substantially uniform filter material may further comprise a plasticizer. The preparation of a plasticized tow is well known in the art. A plasticizer (which plasticizes staple fibers) can be, for example, triacetin, triethylene glycol diacetate (TEGDA) or polyethylene glycol (PEG). The staple fibers may be plasticized cellulose acetate tow fibers. The staple fibers may be acetate cellulose tow, plasticized, for example, triacetin.

The circumference of a cylindrical rod can be, for example, between 14.0 mm and 23.2 mm, for example, between 16.0 mm and 23.2 mm, for example, between 16.0 mm and 20 mm, for example, between 16.2 mm and 23.2 mm, for example, between 16.0 mm and 17 mm.

A large number of randomly oriented staple fibers can form a porous material having a labyrinth of channels in the filter material. The labyrinth of channels can, when using a cigarette filter, act as channels for smoke.

A tobacco smoking filter or filter element may have substantially the same physical properties in any cross section rather than uneven areas resulting from the formation of filter material from a sheet.

In filters and filter elements, in accordance with aspects of the invention, tobacco smoke filtering material can be wrapped using a wrapping machine or a core wrap, for example, wrapping paper or wrapping airtight paper. Particulate additives, such as those described above, can be applied to wrapping paper or to a core wrap surrounding the filter material, for example, as described in UK Patent No. 2261152.

In accordance with the invention, the next aspect is a composite rod containing a large number of filters or filter elements, as described above and / or connected wholly in a mirror image.

The filter element, in accordance with the invention, can be used as a segment of a multi-segment thin filter, for example, a double, triple or other composite filter. Such filters are well known in the art. If such a filter element is used as or in a segment of a multi-segment filter, it can be used on (or) the oral or intraoral end segment of the filter, and (or) any other segment of this filter. The filter element, in accordance with the invention, can be used independently, for example, in a single-segment thin filter (for example, as well as in a monoacetate filter). Such filters are well known in the art.

In a filter cigarette made in accordance with the invention, a filter in accordance with the invention (or a filter comprising a filter element made in accordance with the invention) is connected to the wrapped tobacco rod at one end of the filter towards the tobacco. The filter can, for example, be connected to the tobacco rod wrapped by a circular mount (which affects only the adjacent ends of the (wrapped) filter and rod, leaving most of the filter wrapper intact) or by a full wrapper mount (which is located around the filter along the entire length and adjacent end of the tobacco rod ) Any filter or filter cigarette made in accordance with the invention may be non-ventilated or ventilated by any methods well known in the art, for example by using a perforated or breathable core wrap and / or laser-perforated core wrap and connecting wraps.

According to the invention, a further aspect is the use of a tobacco smoking filter or filter element comprising a cylindrical rod of substantially uniform filter material containing a large number of randomly oriented staple fibers to selectively reduce the content of one or more phenolic compounds in tobacco smoke. According to the invention, a further aspect is the use of a cylindrical rod made of a substantially uniform filter material containing a large number of randomly oriented staple fibers, as, or in the manufacture of a filter or filter element, for selectively reducing the content of one or more tobacco smoke phenolic compounds.

According to the invention, a further aspect is the use of a cylindrical rod made of a substantially uniform filter material containing a large number of randomly oriented staple fibers, as, or in the manufacture of, a filter or filter element having an increased degradability.

The present invention will now be illustrated with reference to the following examples and the accompanying drawings, among which

Figure 1 is a top view, not to scale, of a separate filter in one embodiment of the invention, and

Figure 2 depicts a cross section of the filter shown in Figure 1.

The filter 1 shown in FIG. 1 contains a porous elongated cylindrical rod 2 with a circumference of 16.9 mm and a length of 27 mm, which contains a large number of randomly oriented individual or staple filamentous fibers 3 formed from cellulose acetate tow of grade 5Y30000, plasticized with triacetin . As shown in FIGS. 1 and 2, the staple fibers 3 are mainly located across the longitudinal axis of the element and are slightly pulled to form a large number of contact points by which the staple fibers 3 are connected to each other. The bonded fibers create a substantially uniform filter material that forms the rod 2. The substantially uniform filter material thus formed can be a porous material which, when using a cigarette filter, provides a labyrinth of smoke ducts. The filter element 1 has substantially the same physical properties in cross section.

The filter can be made by known methods, for example, by the method described in US patent No. 3552400. Thus, the untreated cellulose acetate tow is passed through a conventional fiberising device to separate individual fibers, and another subsequent fiberizing device that can be used to separate the cable into relatively thin fibrous layers. The fiber layer is then passed through a conventional plasticizing device in which a suitable plasticizer (triacetin in this example) is sprayed with suitable jets onto both surfaces of the fiber layer to form a plasticized tow. Conventional feeding means, such as a pair of rollers, are used to deliver a plasticized tow to processing equipment for making staple fibers and forming them into a continuous shaft. Suitable equipment is described in great detail in US Pat. No. 3,555,400 and is shown in FIG. 1 of this patent document.

The plasticized tow is fed through a pipe to the chopper, which cuts the elongated tow into a large number of individual staple fibers, the length of which depends on the ratio of the chopper speed and the feed speed of the oblong tow into the chopper. Staple fibers are made by the chopper and pulled out of the chopper using a turbulent air stream that scatters the staple fibers (and provides or increases the randomness of their orientation) and directs them to a porous lattice having the shape of a truncated cone, smaller or output, the end of which feeds the staple fibers to moving porous tape. Particulate matter additives or other additives (not shown) may, at this stage, if necessary, be fed into the swirling air stream and distributed through the filter material. Porous closure means have a conical shape and reduce the speed of passage of staple fibers, and also lead to the placement of staple fibers so that part of the length of the staple fibers is placed essentially across the longitudinal axis of the manufactured filter rod. Staple fibers are fed onto a porous tape that moves along the arranged fibers to the steam treatment chamber. The hole at the inlet of the steam treatment chamber forms the longitudinal edges of the porous tape relative to the staple fibers when the tape with the fibers is pulled longitudinally through the hole. Pulling the tape around the fibers, thus, completes the formation of staple fibers in a rod surrounded by a porous tape. Steam is applied to the porous surface of the tape, while it passes continuously and directly through it to process the staple fibers located therein. The binders of staple fibers (e.g., triacetin) are thus vaporized when the fibers are shaped like a cylindrical rod wrapped in tape. It should be noted that such processing is well known in the art and is described in the aforementioned US patent. The tape with staple fibers incorporated therein is then passed through a cooling station, which is also well known in the prior art, and thus drying and cooling of the elements (and the introduction of binder constituents) takes place in the cooling station. The cylindrical rod thus formed can be wrapped with a rod wrapper (not shown) and hermetically sealed with liquid glue by methods well known in the art. The obtained dried and cooled elongated cylindrical rod, formed from randomly oriented staple fibers, is separated from the tape at the outlet of the cooling station (the tape is essentially straightened and continuously fed back into place in the lattice area to collect subsequent additional staple fibers from the lattice and supply them to the steam camera). The initial elongated cylindrical rod formed from randomly oriented staple fibers, when it continuously exits the output of the device, cut off the final length for future use. It can be cut by cutting means, for example, to obtain separate filters (like filter 1 in FIG. 1), each of which is then attached to a separate wrapped tobacco rod to form a filter cigarette, or to form separate filter elements. More often, however, the continuously exiting rod is first cut into the rods of filter 1 (or filter elements) of double or greater multiplicity (usually four or six times) length, for subsequent use. The formation of increased length filters (and their further incorporation into filter cigarettes) is well known in the art.

Example 1. Reducing the content of phenol.

The following Table 1 compares Sample A, a filter created in accordance with the method described in US Pat. No. 3,555,400, which contains filter material formed from a large number of randomly oriented staple fibers of plasticized cellulose acetate, with a monoacetate filter of the same size known in the art. . For this sample, stiffness indicators were measured (determined by the percentage of the diameter of the compressed filter rod to the initial diameter of the rod, moreover, the compression of the rod causes a known mass to be applied through the annular tab for a certain period of time) and the pressure drop (PD) (expressed in mm of water column) . The yield of phenolic compounds was measured for all samples smoked under the conditions established by ISO; cresols are formed by the joint output of o-, m- and p-cresols, and phenol dihydroxides are formed by the combined output of hydroquinone, resorcinol and catechin. The tar yield from cigarettes was also measured on the basis that changes in the phenol to tar ratio can be estimated. The parameters for sample A are expressed as a percentage of the corresponding parameters of the monoacetate filter known in the art (i.e., the parameter for the monoacetate filter is set to 100, and the corresponding parameter for sample A is expressed as a percentage of this parameter).

Table 1. Parameter Sample A Monoacetate Harness weight 77.5 one hundred Rod hardness 99.9 one hundred Pressure drop 100.6 one hundred Resin Yield * 103.1 one hundred Nicotine yield * 95 one hundred Carbon Monoxide Output * 103.8 one hundred Phenol yield * 78.1 one hundred Total yield of cresols * 78.5 one hundred Dihydroxyphenol yield * 95.9 one hundred Phenols + Cresols ** 75.7 one hundred Dihydroxyphenols ** (μg per mg resin) 92.9 one hundred Phenol reduction per unit weight of tow 141 one hundred Overall reduction in cresols per unit weight of tow 145 one hundred * based on results expressed in absolute terms (i.e. mass / cigarette)
** based on results expressed in μg per mg resin

As indicated above, it is desirable to reduce the levels of phenolic compounds in cigarette smoke. Cellulose acetate is known to provide a selective filtering effect on phenols, so it can be expected that filters made in accordance with the invention that contain randomly oriented staple fibers of cellulose acetate will be less effective at removing phenols compared to a monoacetate filter with such same pressure drop and rigidity, since the first contains about 20-30% less cellulose acetate than the second. In fact, the results unexpectedly showed that sample A gives a reduced yield of phenolic compounds, expressed both in absolute terms and in mg of resin, compared to a similar monoacetate product. The decrease in the content of phenolic compounds in sample A is even more significant if we take into account the reduced mass of cellulose acetate in sample A (which contains filter material formed from a large number of randomly oriented staple fibers of plasticized cellulose acetate) compared to the monoacetate product taken into account ( sample A contains 77.5% by weight of the monoacetate filter tow).

The results show that filters and filter elements made in accordance with the invention provide an unexpected and significant selective reduction in the content of phenolic compounds.

Example 2. The ability to decompose.

Various types of cigarette filters were placed in wire mesh cages on a roof area, and their mass was periodically checked for 12 months. After 12 months, it was found that the weight of standard monoacetate filters decreased by 23-30%, while the mass of a comparable sized filter that contains filter material formed from a large number of randomly oriented staple fibers of plasticized cellulose acetate decreased by 46%. This was unexpected since a comparable mass loss was expected.

Example 3. The type of harness.

Below are the properties of two super-thin composite filter rods A and B (each containing 4 filters 27 mm long, made in accordance with the invention and having a structure similar to that of the embodiment shown in FIG. 1 and FIG. 2), as well as a similar standard monoacetate superthin product "Control" (see table. 2).

Table 2. BUT AT Control Harness type 5Y30000 4.2Y33000 6Y17000 Stem Length (mm) 108 108 108 Circumference (mm) 16.9 16.9 16.8 Rod Weight (g) 0.291 0.281 0.416 The hardness of the rod (%) 88 89 91 Pressure drop at 27 mm tip (mm) 102 one hundred 115 Tar retention at 27 mm tip (%) 29.4 30.5 33.6 Nicotine retention at 27 mm tip (%) 27.1 29.7 29.3

The harnesses used in samples A and B are the same as those used in any standard (circumference 24.5 mm) round product; meanwhile, the “Control” monoacetate superthin sample described above requires a more expensive tow with low total denier. This example shows that filters made in accordance with the invention provide acceptable performance using cellulose tows with a much higher total denier than in a traditional superthin product.

Claims (17)

1. A tobacco smoking filter or filter element comprising a cylindrical rod made of a substantially uniform filter material with a circumference between 14.0 and 23.2 mm, the substantially uniform filter material containing a large amount of staple fibers, which are randomly oriented in three coordinates. 2. The filter or filter element according to claim 1, wherein the rod of a substantially uniform filter material has a circumference between 16.0 and 23.2 mm. 3. The filter or filter element according to claim 1 or 2, in which the staple fibers are crimped. 4. The filter or filter element according to claim 1 or 2, wherein the staple fibers are natural and / or synthetic fibers formed from naturally grown material (s). 5. The filter or filter element according to claim 1 or 2, in which the staple fibers are acetate cellulose fibers or polypropylene fibers. 6. The filter or filter element according to claim 1 or 2, containing two or more types of staple fibers. 7. The filter or filter element according to claim 1 or 2, additionally containing a liquid additive or additive from solid particles. 8. The filter or filter element according to claim 1 or 2, in which the staple fibers have a length between 4 mm and 20 mm 9. The filter or filter element according to claim 1 or 2, wherein the staple fibers are formed from a tow with a total denier of between 14,000 g and 55,000 g per 9,000 m length. 10. The filter or filter element according to claim 1 or 2, containing staple fibers that are plasticized. 11. The filter or filter element according to claim 1 or 2, containing cellulose acetate staple acetate plasticized with triacetin, triethylene glycol diacetate (TEGDA) or polyethylene glycol (PEG). 12. The filter or filter element according to claim 1 or 2, in which the circumference of the cylindrical rod has a value between 16.2 mm and 23.2 mm 13. The filter or filter element according to claim 1 or 2, additionally containing wrapping paper or a core wrap. 14. The filter or filter element according to claim 1 or 2, containing an additive of solid particles in wrapping paper or core wrap. 15. The filter or filter element according to claim 1 or 2, further comprising a water-soluble binder material. 16. A filter cigarette containing a filter made in accordance with any preceding paragraph, or a filter that contains a filter element made in accordance with any preceding paragraph connected to a wrapped tobacco rod. 17. A composite rod containing a large number of filters or filter elements made in accordance with any one of claims 1 to 15, wholly connected end-to-end to each other.

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