HUP0401565A2 - Cigarette filter - Google Patents

Abstract

The subject of the invention is a cigarette smoke filter, which contains a multi-part filter that reduces the level of predetermined smoke components. Smoke filter (130) consists of a fiber filter insert (132) placed at the mouth end of the cigarette, a selective adsorbent part (136) containing a selective adsorbent material (146) and a general adsorbent part (134) containing a general adsorbent material (144). Selective adsorbent material (146), such as phenol-formaldehyde resin embedding material mainly surface-functionalized with primary and secondary amine functional groups, removes certain smoke components from tobacco smoke. The general adsorbent material (144), such as activated carbon material, removes several compounds without a high degree of selectivity. The fibrous filter insert (132), the selective adsorbent part (136) and the general adsorbent part (134) are placed next to each other, coaxially and in a straight line. HE

Description

_r , _ . _ SBG&K.

U I □ Ö 5 Patent Attorney's Office

IL1062 Budapest, Andrássy út 113. τ _ζ Ά; v ™ ·/Phone: 461-1000, Fax: 461-1099teli

78.354/DO EXAMPLE

Cigarette smoke filter

This application claims priority to U.S. Provisional Application No. 60/309,388, filed August 1, 2001, which is incorporated herein by reference in its entirety, to U.S. Provisional Application No. 60/309,435, filed August 1, 2001, which is incorporated herein by reference in its entirety, and to U.S. Provisional Application No. 10/011,841, filed October 30, 2001.

The invention relates to a cigarette smoke filter. The smoke filter comprises a smoke component adsorbent which, in combination with a carbon-based filter material, produces a synergistic reduction of vaporous components of smoke.

Cigarettes contain tobacco rods or columns that, when burned, produce a particulate phase and a vapor phase. About 70 years ago, smoke filters began to be attached to one end of the tobacco column. The smoke filter removed various smoke components, among other things. Smoke filters made of fibrous or fibrous materials, such as cellulose acetate tow or paper, mechanically remove the particulate phase of tobacco smoke. However, fibrous materials are not effective in removing volatile components in the vapor phase, such as aldehydes, hydrogen cyanide, and sulfides. An adsorbent or absorbent is typically combined with the fibrous material to enhance the removal of vapor phase components. Cigarette smoke filters have included, for example, activated carbon, porous minerals such as pumice, silica gel, cation exchange resins, and anion exchange resins.

Charcoal has a large specific surface area and is a relatively strong adsorbent for tobacco smoke vapor components. Charcoal coated with a mixture of metal oxides is particularly effective in removing acidic gases. Pumice has a large adsorbent area and a strong adsorbent affinity for charged materials, but a relatively low affinity for nonpolar materials. Silica gels are generally considered to be relatively poor adsorbents for tobacco smoke vapor components. Although silica gel effectively adsorbs aldehydes and hydrogen cyanide, these components are also readily desorbed from silica gel. Cation exchange resins have been proposed for nicotine removal. Anion exchange resins have been proposed for smoke acid removal, but strongly basic anion exchangers have no effect on smoke vapor aldehydes. Porous, weakly basic anion exchangers are suitable for removing smoke acids and aldehydes, but their effectiveness, like that of carbon and porous minerals, decreases during smoking.

Two or more adsorbents may be used in combination in cigarette smoke filters. For example, US Patent No. 2,815,760 describes the use of an ion exchange material in combination with materials that "chemically react with the harmful, non-alkaline and non-acidic components of the smoke to form non-volatile compounds and retain them in the smoke filter. However, said additives did not result in a sufficiently selective removal of smoke phase components such as aldehydes in the smoke, especially acetaldehyde and acrolein. US Patent No. 4,300,577 describes the use of a mixture of an absorbent that has a low retention of vapor phase components and a second component consisting mainly of primary amino functional groups to remove vapor phase components, including aldehydes and hydrogen cyanide, from tobacco smoke. However, the smoke filter according to US Patent No. 4,300,577 was not popular with consumers and was not commercially successful.

The object of our invention is to provide a cigarette smoke filter that includes a multi-part filter that reduces the level of predetermined smoke components.

This object is achieved according to the invention in that the filter consists of a fibrous filter insert placed at the mouth end of the cigarette, a part containing a selective adsorbent material and a part containing a general adsorbent material.

The filter pad may be any filter pad known in the art, such as cellulose acetate tow. The general adsorbent material is preferably selected from the group of relatively high surface area materials that are capable of adsorbing a range of compounds without a high degree of selectivity. Such a material is activated charcoal. The selective adsorbent material is selected based on the specific smoke components to be removed. The selective adsorbent material is preferably selected from the group of surface-functionalized resins, each resin comprising a substantially inert support material having a specific surface area greater than about 35 m ² /g. In one embodiment of the invention, the selective adsorbent material comprises a phenol-formaldehyde resin embedding material that is surface-functionalized primarily with primary and secondary amine functional groups.

The selective adsorbent material may be structurally adjacent to the tobacco rod, while the general adsorbent material may be located between the selective adsorbent portion and the filter pad. Alternatively, the general adsorbent material may be located adjacent to the tobacco rod and the selective adsorbent material, between the general adsorbent portion and the filter pad. Preliminary data indicate that the first orientation has a synergistic effect on tobacco component reduction compared to the second orientation. Alternatively, the selective adsorbent and general adsorbent may be incorporated into a conventional filter pad material, such as cellulose acetate, or the adsorbents may be located as beds or thin layered sections within the filter pad material.

Our invention is described in more detail with reference to its exemplary embodiments with the help of our figures, of which:

Figure 1 is an axonometric view of a prior art smoke-filtered cigarette,

Figure 2 is an axonometric view of the cigarette smoke filter according to the invention, where the adsorbents are dispersed throughout the material of the filter cartridge, and the general adsorbent part is placed between the filter cartridge and the selective adsorbent part,

Figure 3 is an axonometric view of the cigarette smoke filter according to the invention, where the adsorbents are dispersed throughout the material of the filter cartridge, and the selective adsorbent part is placed between the filter cartridge and the general adsorbent part,

Figure 4 is an axonometric view of the cigarette smoke filter according to the invention, where the adsorbents are packed as beds in a segment of the filter pad material, the

Figure 5 is a cross-section of an embodiment of the invention, where the filter cartridge is positioned between the general adsorbent portion and the selective adsorbent portion, the

Figure 6 is a cross-sectional view of an embodiment of the invention, where the filter insert is adjacent to one end of a tobacco rod, the

Figure 7 is a cross-sectional view of an embodiment of the invention where the adsorbents are divided into sections in a single length of fibrous filter material, the

Figure 8 is an embodiment of the invention without a filter cartridge part.

The cigarette smoke filter of the invention comprises a multi-part filter for reducing the levels of predetermined smoke components. The filter consists of a fibrous filter insert placed at the mouth end of the cigarette, a section containing a selective adsorbent material and a section containing a general adsorbent material.

As shown in Figure 1 and known in the art, in a typical smoke filter cigarette 10, a tobacco rod 20 is connected to a smoke filter 30. The tobacco rod 20 consists of a loose tobacco mixture 22 packed in cigarette paper 24, and the smoke filter 30 consists of a filter cartridge 32 wrapped in a cartridge wrapper 34. The smoke filter 30 is connected to the tobacco rod 20 by a piece of wrapping paper 36.

In accordance with the invention, as shown in FIG. 2 , a multi-part smoke filter 130 is attached to a tobacco rod 20 in a cigarette 110. The smoke filter 130 comprises a filter element 132, a general adsorbent-containing element or general adsorbent element 134, and a selective adsorbent-containing element or selective adsorbent element 136. The filter element 132 is adjacent to a first end 131 or mouth end of the smoke filter 130. The selective adsorbent bed 136 is adjacent to a second end 137 or tobacco rod end of the smoke filter 130. The general adsorbent bed 134 is disposed between the filter element 132 and the selective adsorbent bed 136.

The filter insert 132 is made of a fibrous or filamentary material and provides a neat, neat appearance to the mouthpiece 131 of the cigarette. The filter insert 132 also maintains the strength of the mouthpiece 131 during smoking of the cigarette 110. As is known in the art, the filter insert 132 can be made of a variety of materials. The most common of these are cellulose, cellulose acetate tow, paper, cotton, polypropylene web, polypropylene tow, polyester web, polyester tow, or combinations thereof. It can optionally contain a plasticizer.

The general adsorbent portion 134 comprises a general adsorbent material 144 dispersed in a filter pad material 142, such as a “dual dalmatian” filter known in the art. The general adsorbent material 144 is preferably selected from materials with relatively high surface areas that adsorb smoke components without a high degree of selectivity. The general adsorbent material 144 includes, for example, activated charcoal, activated coconut charcoal, activated carbon-based elemental carbon, zeolite, silica gel, pumice, alumina, or combinations thereof, and in the case of coconut charcoal, about 100% of the total carbon content of the adsorbent material is present. It is selected from the group consisting of 50% denser, lean coal-based mineral charcoal (available from Calgon Carbon, Pittsburgh, Pennsylvania, USA), Ambersorb 572 or Ambersorb 563 (carbon-containing resin derived from the pyrolysis of sulfonated styrene-divinylbenzene; available from Rohm and Hass, 5000 Richmond Street, Philadelphia, Pennsylvania 19137, USA), and materials of similar particle size, surface area, and binding affinity, or combinations thereof. To further enhance the effectiveness of the general adsorbent, the general adsorbent 134 may also include metal oxides or other metal-based complexes.

The selective adsorbent portion 136 preferably comprises a selective adsorbent material 146 dispersed in a filter pad material 142, such as a “dual dalmatian” filter as known in the art. The selective adsorbent material 146 is preferably selected for its selectivity for a predetermined class of compounds. The selective adsorbent material 146 may be, for example, an ion exchange resin such as Duolite A7 (available from Rohm and Hass, 5000 Richmond Street, Philadelphia, Pennsylvania 19137, USA), or a material having similar functional groups and similar binding affinity. Duolite A7 contains a phenol-formaldehyde resin encapsulant, the surface of which is functionalized with primary and secondary amines, which enhances the selectivity of the resin for aldehydes and hydrogen cyanide present in tobacco smoke.

When selecting the selective adsorbent material 146, it should also be considered that the contact conditions between the tobacco smoke and the selective adsorbent material 146 depend on several variables, including how strongly the smoker inhales the smoke when smoking a cigarette, and how much tobacco has been consumed before a given puff. Thus, it is advantageous if the specific surface area of the selective adsorbent material 146 is greater than 35 m ² /g, so that diffusion resistance is minimal, and the functional sites on the surface are easily accessible. In addition, if a portion of the surface is coated with a plasticizer - which may occur if the selective adsorbent material 146 is dispersed in the filter pad material 142 - then the filtration capacity of materials with a higher specific surface area is less reduced.

When a smoker smokes a cigarette, tobacco smoke is drawn through the filter 130. The smoke first passes through the selective adsorbent section 136, where the targeted smoke components are adsorbed onto the surface of the selective adsorbent material 146, and the particulate matter is retained by the filter pad material 142. The remaining smoke then passes through the general adsorbent section 134, where the general adsorbent material 144 may retain other components, and the filter pad material 142 may retain additional particulate matter. The remaining smoke finally passes through the filter pad 132, where additional particulate matter may be removed. The filtered smoke is then delivered to the smoker.

In the exemplary embodiment of the invention shown in Figure 2, the multi-part filter 130 consists of a filter element 132, a general adsorbent element 134, and a selective adsorbent element 136. The filter element 132 is made of cellulose acetate tow and is about 7 mm long. The general adsorbent element 134 contains 40 mg of a general adsorbent material 144, here activated coconut charcoal, dispersed in the filter element material 142, here cellulose acetate tow. The cellulose acetate tow is cut so that the general adsorbent element 134 is about 10 mm long. The cellulose acetate tow is treated with a plasticizer. The selective adsorbent portion 136 consists of 40 mg of Duolite A7 dispersed in the filter pad material 142, here cellulose acetate tow. The cellulose acetate tow is cut so that the selective adsorbent portion 136 is approximately 10 mm long. The cellulose acetate tow is treated with a plasticizer. Analysis of the smoke vapor exiting the mouth end 131 of the cigarette 110 during normal puff/pause cycle of the tobacco rod showed statistically significant reductions in the levels of hydrogen cyanide, furan, propionaldehyde, acetone, methyl ethyl ketone/butaryl aldehyde, hydrogen sulfide, 1,3-butadiene, 2-methylpropanal, isoprene, styrene, styrene, pyridine, toluene and benzene compared to a similar filter containing only synthetic resin. Analysis of the smoke vapor exiting the mouthpiece of the 110 cigarette 131 during normal puff/pause cycle of the tobacco rod showed statistically significant reductions in the levels of pyridine, hydrogen cyanide, hydrogen sulfide, styrene, 2-methylpropanal, benzene, propionaldehyde, furan, isoprene, 1,3-butadiene, crotonaldehyde, acetone, acrylonitrile, acetaldehyde, toluene, carbon disulfide, methyl ethyl ketone/butaryl aldehyde, propionaldehyde, acetonitrile and methanol compared to a similar filter containing only activated carbon.

In the multi-piece smoke filter 130, as shown in Figure 2, the filter element 132 is located adjacent to the mouth end 131, the selective adsorbent element 136 is located adjacent to the tobacco rod end 137, and the general adsorbent element 134 is located between the filter element 132 and the selective adsorbent element 136.

In another embodiment, shown in Figure 3, the cigarette 210 is provided with a multi-part smoke filter 230. The filter element 132 is located at the mouth end 131, the general adsorbent element 134 is located at the tobacco rod end 137, and the selective adsorbent element 136 is sandwiched between the filter element 132 and the general adsorbent element 134. In this embodiment, during a normal puff, the smoke first passes through the general adsorbent element 134, then through the selective adsorbent element 136, and finally through the filter element 132. The multi-piece smoke filter 230 is substantially identical to the smoke filter 130 of the first exemplary embodiment of FIG. 2 , except that the general adsorbent portion 134 is adjacent to the tobacco rod 20 and the selective adsorbent portion 136 is sandwiched between the filter insert 132 and the general adsorbent portion 134. Analysis of the smoke vapor exiting the mouth end 131 of the cigarette 210 ( FIG. 3 ) during normal puff/pause cycle combustion of the tobacco rod showed statistically significant reductions in the levels of propionaldehyde, acetone, methyl ethyl ketone/butaryl aldehyde, crotonaldehyde, hydrogen sulfide, 2-methylpropanal, pyridine, acrolein, toluene, acetaldehyde, acrylonitrile, methanol, and benzene compared to a similar resin-only filter. Analysis of the smoke vapor exiting the mouthpiece 131 of the 210 cigarette during normal puff/pause cycle of the tobacco rod showed statistically significant reductions in the levels of pyridine, hydrogen cyanide, benzene, propionitrile, crotonaldehyde, acetone, acrylonitrile, acetaldehyde, toluene, carbon disulfide, methyl ethyl ketone/butaryl aldehyde, propionaldehyde, acetonitrile and methanol compared to a similar filter containing only activated charcoal.

As shown in FIG. 4, in the multi-part smoke filter 330 of the cigarette 310, the general adsorbent material 144 and the selective adsorbent material 146 are packed as thin layers of general adsorbent material 344 and selective adsorbent material 346 in the filter pad material. In this embodiment, the adsorbents packed in the layer are exposed to less plasticizer than adsorbents dispersed in the tow and have a larger surface area to interact with the smoke components. In the multi-part smoke filter 630 of the cigarette 610, as shown in FIG. 7, the general adsorbent material 344 and the selective adsorbent material 346 are dispersed in separate portions within a single length of fibrous filter pad material 342.

The cigarette 110 of FIG. 2 has the advantage that the smoke passes through the selective adsorbent material 146 before passing through the general adsorbent material 144. This allows the selective adsorbent material 146 to remove certain smoke constituents before the smoke reaches the general adsorbent material 144. As a result, the general adsorbent material 144 is more effective in removing the remaining smoke constituents. Thus, a synergistic effect is observed for the CA/GA/SA (cellulose acetate, general adsorbent, and selective adsorbent) structure compared to the CA/SA/GA (cellulose acetate, selective adsorbent, and general adsorbent) structure.

As shown in Figures 5 and 6, in the multi-part filter 430 of the cigarette 410 and the filter 530 of the cigarette 510, the filter element 132 is positioned between the general adsorbent portion 134 and the selective adsorbent portion 136 in Figure 5, and adjacent one end of the tobacco rod 20 in Figure 6. In Figure 5, the selective adsorbent portion 136 is at the mouth end of the filter 430, and in Figure 6, the general adsorbent portion 134 is at the mouth end of the filter 530. However, the filter 730 of the cigarette 710 includes only one general adsorbent portion 134 and one selective adsorbent portion 136, as shown in Figure 8.

The following examples illustrate embodiments that can be made according to the invention and provide an indication of the smoke component removal capabilities of these embodiments. The embodiments described are exemplary only and do not limit the scope of the invention.

Example 1: A cigarette 110 with a multi-piece smoke filter 130 was prepared as shown in Figure 2. The smoke filter 130 consisted of a filter pad 132, a general adsorbent portion 134, and a selective adsorbent portion 136. The filter pad 132 was made of cellulose acetate tow and was about 7 mm long. The general adsorbent portion 134 was made of 40 mg of activated coconut charcoal as the general adsorbent material 144. This was dispersed in the plasticizer-treated cellulose acetate tow serving as the filter pad material 142 and was cut into general adsorbent portions 134 of about 10 mm long. The selective adsorbent portion 136 was about 10 mm long. It consisted of 40 mg of Duolite A7 dispersed in 142 plasticizer-treated cellulose acetate tow serving as filter material and cut into 136 selective adsorbent sections of approximately 10 mm in length. The filter was attached to a tobacco rod of approximately 56.5 mm in length, which contained approximately 617 mg of a typical non-menthol cigarette tobacco blend wrapped in 50 Coresta cigarette papers containing approximately 1.8% citrate. Approximately 10.3 mg of tar was produced per cigarette.

Example 2: A cigarette 210 with a multi-piece smoke filter 230 was prepared using the structure shown in Figure 3. The filter element 132, the general adsorbent element 134, and the selective adsorbent element 136 were substantially identical to the filter element 132, the general adsorbent element 134, and the selective adsorbent element 136 of Example 1, respectively. The filter was attached to a tobacco rod about 56.5 mm long, which contained about 617 mg of a typical non-menthol cigarette tobacco blend wrapped in about 1.8% citrate 50 Coresta cigarette paper. About 10.0 mg of tar was produced per cigarette.

Example 3: Cigarettes were prepared as in Example 1 except that 20 mg of Duolite A7 was used instead of 40 mg in the 136 selective adsorbent portion. Approximately 10.2 mg of tar was produced per cigarette.

Example 4: Cigarettes were prepared as in Example 2 except that 20 mg of Duolite A7 was used instead of 40 mg in the 136 selective adsorbent portion. Approximately 10.9 mg of tar was produced per cigarette.

Example 5: Cigarettes were prepared as in Example 1 except that 60 mg of Duolite A7 was used instead of 40 mg in the 136 selective adsorbent portion. Approximately 10.0 mg of tar was produced per cigarette.

Example 6: Cigarettes were prepared as in Example 2 except that 60 mg of Duolite A7 was used instead of 40 mg in the 136 selective adsorbent portion. Approximately 10.3 mg of tar was produced per cigarette.

Example 7: Cigarettes were prepared as in Example 1 except that in the 134 selective adsorbent portion, instead of 40 mg of activated coconut charcoal, about 60 mg of lean coal-based mineral-based carbon material was used. About 10.1 mg of tar was produced per cigarette.

Example 8: Cigarettes were prepared as in Example 2 except that in the 134 selective adsorbent portion, instead of 40 mg of activated coconut charcoal, approximately 60 mg of lean coal-based mineral-based carbon material was used. Approximately 10.2 mg of tar was produced per cigarette.

Example 9: The cigarettes of Examples 1-6 were smoked using a Borgwalt RM-20 smoking machine such that the remaining cigarette end length measured from the mouthpiece was approximately 4 mm. According to procedures prescribed by the FTC [Federal Trade Commission], the smoke components emerging from the filter end of the cigarettes were passed through a Cambridge filter sheet, the vapor phase was collected in a bag, and analyzed by gas chromatography/mass spectrometry. The data were normalized to approximately 10 mg tar/cigarette.

·..· “Γ *- .^·

Table 1: Average values of vapor phase components (pg/cigarette)

Cigarette Making Example Number 1 2 3 4 5 6 Duolite mg/cigarette 40 40 20 20 60 60 Filtering section arrangement CA/GA/SA CA/SA/GA CA/GA/SA CA/SA/GA CA/GA/SA CA/SA/GA Acetaldehyde 330.9 333.7 380.7 346.2 320.3 310.9 Isoprene 231.4 240.4 252.1 246.1 227.4 227.2 Acetone 144.1 163.5 156.0 160.5 148.0 151.4 Methanol 104.9 127.6 114.5 142.8 111.7 98.5 Acetonitrile 59.8 72.0 67.0 77.4 62.8 57.3 Acrolein 29.6 31.4 33.6 32.2 28.5 29.9 Methyl ethyl ketone 29.3 35.9 30.9 38.5 30.1 31.6 Formaldehyde 23.5 25.8 25.5 25.0 22.1 24.5 Propionaldehyde 25.7 27.4 29.3 28.5 25.3 25.0 1,2-butadiene 25.5 25.9 27.5 25.5 25.8 25.0 Toluene 22.5 25.3 22.0 27.5 23.9 22.5 Benzene 20.6 23.6 21.6 24.1 24.1 21.4 acrylonitrile 16.8 17.7 18.0 18.0 17.0 16.5 Furan 16.2 17.0 17.3 16.4 16.4 16.2 Hydrogen cyanide 15.1 16.4 20.7 19.6 13.6 14.8 Hydrogen sulfide 12.9 13.0 14.0 12.9 13.1 12.7 Propionitrile 12.9 15.0 13.5 15.9 13.6 12.8 2-methylpropanal 6.4 6.7 7.0 7.0 6.6 6.4 Crotonaldehyde 5.1 5.9 5.5 6.3 5.3 5.0 Carbon disulfide 2.5 2.6 2.7 2.6 2.6 2.5 Styrol 2.0 1.8 2.2 1.9 2.1 1.7 Pyridin 1.9 1.9 1.9 1.8 1.9 1.8

CA = cellulose acetate filter cartridge, GA = general adsorbent part, SA = selective adsorbent part

Example 10: The cigarettes of Examples 7 and 8 were smoked using a Borgwalt RM-20 smoking machine such that the remaining cigarette end length measured from the mouthpiece was approximately 4 mm. According to procedures prescribed by the FTC [Federal Trade Commission], the smoke components emerging from the filter end of the cigarettes were passed through a Cambridge filter sheet, the vapor phase was collected in a bag, and analyzed by gas chromatography/mass spectrometry. The data were normalized to approximately 10 mg tar/cigarette.

Table 2: Average values of vapor phase components (pg/cigarette)

Cigarette Making Example Number 7 8 Duolite mg/cigarette 40 40 Filtering section arrangement CA/GA/SA CA/SA/GA acetaldehyde 343.4 364.2 isoprene 225.0 268.9 acetone 138.6 162.3 methanol 95.1 134.7 acetonitrile 61.4 84.6 acrolein 9.8 35.3 methyl ethyl ketone 28.3 39.8 propionaldehyde 26.4 30.2 1,3-butadiene 25.4 27.7 toluene 18.7 24.2 benzene 21.3 27.3 acrylonitrile 7.5 9.0 furan 17.0 18.4 hydrogen cyanide 16.7 19.5 hydrogen sulfide 14.7 14.1 propionitrile 15.7 20.3 2-methylpropanal 13.0 14.8 crotonaldehyde 3.3 5.1 carbon disulfide 2.8 2.8 styrene 1.8 2.1 pyridine 1.3 1.4

CA = cellulose acetate filter cartridge, GA = general adsorbent part, SA = selective adsorbent part

There are certain manufacturing advantages to having the selective adsorbent material 146 and the general adsorbent material 144 dispersed throughout the filter pad material 142, here a cellulose acetate tow. If the general adsorbent material 144 and the selective adsorbent material 146 are dispersed throughout the tow, the adsorbents can be handled more easily than if they were in loose particle form. However, if the general adsorbent material 144 and the selective adsorbent material 146 are dispersed throughout the tow, there is a risk that any plasticizer used on the tow will affect the surface of the general adsorbent material 144 and the selective adsorbent material 146, thereby reducing the adsorbent's ability to adsorb. Thus, as shown in Figure 4, the general adsorbent material 144 and the selective adsorbent material 146 can be packed as a thin layer of general adsorbent material 344 and selective adsorbent material 346 in the filter pad material 142. Since the adsorbents packed in the layer are not affected by the plasticizer to the same extent as the adsorbents dispersed in the tow, the adsorbents have a larger surface area available to interact with the smoke components.

A person skilled in the art will be able to vary the features of the invention based on the above. For example, the length and diameter of the filter pad, the general adsorbent portion, and the selective adsorbent portion may differ from the dimensions described herein, and their relative proportions may also be different. In addition, the dimensions of the various portions may be optimized for a given tobacco blend or given dimensions of the tobacco rod. It is believed that these and other variations fall within the spirit and scope of the appended claims.

Claims (31)

r *.r PATENT CLAIMS 1. A multi-part cigarette smoke filter, characterized in that it comprises a) a selective adsorbent portion (136) comprising a selective adsorbent material (146) dispersed in a fibrous material and having an affinity for a predetermined group of compounds, and b) a general adsorbent portion (134) comprising a general adsorbent material (144) having a high specific surface area and adsorbing smoke components without a high degree of selectivity, the selective adsorbent portion (136) and the general adsorbent portion (134) being axially juxtaposed. 2. A cigarette smoke filter according to claim 1, characterized in that the selective adsorbent material (146) is an ion exchange resin. 3. A cigarette smoke filter according to claim 2, wherein the surface area of the selective adsorbent material (146) is sufficient to allow smoke components to readily access functional sites on the surface. 4. A cigarette smoke filter according to claim 2, characterized in that the ion exchange resin comprises a phenol-formaldehyde resin embedding material which is surface functionalized mainly with primary and secondary amine functional groups. 5. A cigarette smoke filter according to claim 2, characterized in that the selective adsorbent portion (136) comprises a selective adsorbent material (146) dispersed in a fibrous material. 6. A cigarette smoke filter according to claim 2, wherein the selective adsorbent portion (136) comprises a bed of closely packed selective adsorbent material (346). 7. The cigarette smoke filter of claim 1, wherein the general adsorbent material (144) is selected from the group consisting of activated charcoal, activated coconut charcoal, activated carbon-based elemental carbon, zeolite, silica gel, pumice, alumina, carbon-based carbon material made from lean coal, carbon-containing resin derived from the pyrolysis of sulfonated styrene-divinylbenzene, or combinations thereof. 8. A cigarette smoke filter according to claim 8, characterized in that the general adsorbent portion (134) comprises a general adsorbent material (144) dispersed in a fibrous material. 9. A cigarette smoke filter according to claim 7, wherein the general adsorbent portion (134) comprises a bed of closely packed general adsorbent material (344). 10. The cigarette smoke filter of claim 7, wherein the general adsorbent portion (134) further comprises a metal oxide or other metal-based complex. 11. The cigarette smoke filter of claim 1, characterized in that it comprises a fibrous filter pad (132) made of cellulose, cellulose acetate tow, paper, cotton, polypropylene web, polypropylene tow, polyester web, polyester tow, or combinations thereof, and the filter pad (132) is coaxially disposed in line with the selective adsorbent portion (136) and the general adsorbent portion (134). 12. The cigarette smoke filter of claim 11, wherein the filter insert (132) further comprises a plasticizer, a liquid additive, a flavoring agent, or combinations thereof. 13. A cigarette smoke filter according to claim 11, characterized in that the general adsorbent portion (134) is disposed between the fibrous filter pad (132) and the selective adsorbent portion (136). 14. A cigarette smoke filter according to claim 11, characterized in that the selective adsorbent portion (136) is disposed between the fibrous filter pad (132) and the general adsorbent portion (134). 15. A cigarette smoke filter according to claim 11, characterized in that the fibrous filter insert (132) is disposed between the selective adsorbent portion (136) and the general adsorbent portion (134). 16. The cigarette smoke filter of claim 1, further comprising a liner surrounding the general adsorbent portion (134) and the selective adsorbent portion (136). 17. The cigarette smoke filter of claim 1, wherein the selective adsorbent material (146) has a specific surface area greater than about 35 m ² /g. 18. A multi-part cigarette smoke filter, characterized in that it comprises: a) a fibrous filter pad (132) selected from the group consisting of cellulose, cellulose acetate tow, paper, cotton, polypropylene web, polypropylene tow, polyester web, polyester tow, or combinations thereof; b) a selective adsorbent portion (136) formed of an ion exchange resin having a surface area sufficient to allow smoke components to readily access the functional sites on the surface; c) a general adsorbent portion (134) selected from the group consisting of activated charcoal, activated coconut charcoal, activated carbon-based elemental carbon, zeolite, silica gel, pumice, alumina, carbon-based carbon material made from lean coal, carbon-containing resin derived from the pyrolysis of sulfonated styrene-divinylbenzene, or combinations thereof; and the filter cartridge (132), the selective adsorbent portion (136), and the general adsorbent portion (134) are arranged coaxially with each other in a line. 19. A cigarette smoke filter according to claim 18, characterized in that the ion exchange resin comprises a phenol-formaldehyde resin embedding agent which is surface functionalized mainly with primary and secondary amine functional groups. 20. A cigarette smoke filter according to claim 18, characterized in that the selective adsorbent portion (136) is formed of an ion exchange resin dispersed in a fibrous material. 21. A cigarette smoke filter according to claim 18, wherein the selective adsorbent portion (136) comprises a bed of closely packed ion exchange resin. 22. A cigarette smoke filter according to claim 18, wherein the general adsorbent portion (134) comprises a general adsorbent material (144) dispersed in a fibrous material. 23. A cigarette smoke filter according to claim 22, wherein the general adsorbent portion (134) further comprises an additive formed of a metal oxide or other metal-based complex. 24. A cigarette smoke filter according to claim 18, wherein the general adsorbent portion (134) comprises a bed of closely packed general adsorbent material (144). 25. A cigarette smoke filter according to claim 24, wherein the general adsorbent portion (134) further comprises an additive formed of a metal oxide or other metal-based complex. 26. A cigarette smoke filter according to claim 18, characterized in that the filter insert (132) is made of cellulose acetate tow. 27. The cigarette smoke filter of claim 18, wherein the filter insert (132) further comprises a plasticizer, a liquid additive, a flavoring agent, or combinations thereof. 28. A cigarette smoke filter according to claim 18, characterized in that the general adsorbent portion (134) is disposed between the fibrous filter pad (132) and the selective adsorbent portion (136). 29. A cigarette smoke filter according to claim 18, characterized in that the selective adsorbent portion (136) is disposed between the fibrous filter pad (132) and the general adsorbent portion (134). 30. A cigarette smoke filter according to claim 18, characterized in that the fibrous filter insert (132) is disposed between the selective adsorbent portion (136) and the general adsorbent portion (134). 31. The cigarette smoke filter of claim 18, wherein the selective adsorbent material (146) has a specific surface area greater than about 35 m ² /g. (The authorized representative) Katalin Dónusz is a patent attorney at the S.B.G. &JK—S?gtadalmi Attorneys Office. H-1062 road 113. TelefoxMáMÖOO Fax: 461-1099 ..............ΐ