EP0213081B1 - Cigarette filter unit - Google Patents

Abstract

In order to obtain, during the smoking of a cigarette, each time the smoker draws, an amount of condensate which is more constant or is even less than heretofore, there is provided a cigarette filter unit having at least one membrane in the form of a screen positioned across the smoke-gas flow paths, the unit acting, while the cigarette is being smoked, as an internal bypass element. To this end, the spatial distribution of the openings in the membrane, and the cross sectional areas thereof, are accurately determined as to the size and shape. The thickness of the membrane is between 10 and 150 mu m, the number of openings therein is between 500 and 25,000, and the cross sectional area of the openings is between 80 and 3,000 mu m2. Furthermore, an additional element providing at least one flow aperture whose cross section is at least 10 times larger than that of the largest opening in the membrane and/or the ventilating openings, is provided after the membrane, as seen in the direction of flow, extending between the interior and the exterior of the filter unit.

Description

The invention relates to a cigarette filter unit with at least one switching element arranged in the flue gas flow cross-section for gradually switching automatically when smoking from an initial flue gas path to at least one further flue gas path within the filter unit.

When smoking a cigarette without a cigarette filter, with or without ventilation, and / or with a conventional cigarette filter, the condensate content during the smoking thereof increases relatively strongly in the smoke flowing into the mouth of the smoker through the suction-side cigarette end, which is undesirable.

From DE-A-2 243 349 it is known to use a tobacco smoke filter consisting of a disc of a densely packed layer of small fibrous or spherical particles of a smoke filter material. However, such a disk material has the disadvantage that the pore size and pore distribution vary too much locally in order to be able to produce filter elements with sufficiently precise and identical filter values in large-scale production of filter disks made from such a material.

A filter cigarette is known from DE-A-2 209 763, in which a stopper provided with openings is arranged between the tobacco section and a ventilation area. These openings can be obtained either by mechanically perforating the plug material or by using a paper material which is inherently porous. If the openings are achieved by mechanical perforation of a stopper, the opening cross section and the thickness of the stopper are too large, since too much tar is then required when smoking in order to achieve a usable switching effect. If an inherently porous paper material is used, then in the case of large-scale production in the manufacture of the individual stoppers from a large-area, highly porous paper material, due to the irregular paper fiber structure in such paper for such purposes, a pore size and pore distribution that is identically reproducible for all stoppers cannot be achieved for the cigarette industry .

The object of the present invention is, in particular, to create a cigarette filter unit which, even in the case of large series production, makes it possible to adhere to precisely defined switchover conditions and thus to precisely defined pollutant values when used in filter cigarettes, while limiting the maximum possible suction resistance in use to a relatively precisely predetermined value.

This object is achieved according to the invention in the case of a cigarette filter unit of the type mentioned at the outset.

It may be desirable that ventilation openings (4) extending between the inside and the outside of the filter unit are provided downstream of the membrane (3).

It is expedient if the thickness of the membrane in the range of 30 microns to 100 and the cross-sectional area of the individual, sieve-like openings provided in the membrane in a range from 100 to 2500 pm ^2, preferably in a range from 100 to 1800 _Jl m ^2, is .

Since the materials from which the membrane can be produced must comply with the laws applicable to the tobacco industry, it is advantageous if the membrane consists of natural textile and / or synthetic fibers, preferably in the form of a fabric or a perforated film .

To achieve the highest possible amount of condensate per train of the smoker, it is expedient if a ventilation air path, if provided, has ventilation openings in such a number and with such a cross section that an initial dilution with ventilation air in a range of 30 to 70%, preferably in a range of 45 to 55%.

In order to achieve smoking properties that are pleasant for the smoker of a cigarette provided with the cigarette filter unit according to the invention, it is also advantageous if the number of membrane openings provided in the membrane and their cross-sectional areas are matched to one another in such a way that when an air quantity of 17.5 ml / s is extracted from the suction-side end of the filter unit, the latter causing a pressure drop in the range from 25 to 150 mm WS.

In order to avoid excessive variations in the filtering characteristic values, it is expedient if the distance between individual openings of the membrane and the size of the cross-sectional areas of these openings deviate less than 10% from the specified value.

In order to achieve special filter characteristics, it can be advantageous if the membrane has openings of different cross-sectional areas with a precisely defined size after a precisely predetermined distribution.

It may be expedient that the inner cross section of the filter unit is provided at the location of the membrane with the exception of the latter with a partition and carrier intermediate wall connected to the latter and consisting of at least approximately gas-impermeable material.

To achieve a bypass flow, it is expedient if the partition and support wall and / or the membrane are provided with one or more flow openings, the individual cross-sectional areas of which are larger than 10 ⁴ p _M ² .

It can also be advantageous if the membrane is arranged in the flow cross-section of a tube consisting of at least approximately gas-impermeable material and the remaining cross-section is between the outside of the tube and the outside of the filter unit is filled with tobacco smoke filtering material over at least part of the tube length. It is expedient for the tube serving to form two separate flow channels to be filled with granular and / or fibrous filter material at least over part of its length.

It can also be expedient if, viewed in the flow direction, a filter element which changes the composition of the tobacco smoke is arranged in the flow cross-section of the filter unit before and / or after the membrane.

• Fig. 1 schematisch im Längsschnitt eine erste beispielsweise Ausführungsform einer erfindungsgemässen, an einem Tabakteil befestigten Zigarettenfiltereinheit;
• Fig. 2 schematisch im Längsschnitt eine zweite beispielsweise Ausführungsform einer erfindungsgemässen, an einem Tabakteil befestigten Zigarettenfiltereinheit;
• Fig. 3 schematisch im Längsschnitt eine dritte beispielsweise Ausführungsform einer erfindungsgemässen, an einem Tabakteil befestigten Zigarettenfiltereinheit;
• Fig. 4 schematisch im Längsschnitt eine vierte beispielsweise Ausführungsform einer erfindungsgemässen, an einem Tabakteil befestigten Zigarettenfiltereinheit;
• Fig. 5 schematisch im Längsschnitt eine weitere beispielsweise Ausführungsform einer erfindungsgemässen, an einem Tabakteil befestigten Zigarettenfiltereinheit;
• Fig. 6 und 7 mögliche Verläufe der Kondensatmenge C pro Zug B bei Verwendung von weiteren möglichen Ausführungsformen von erfindungsgemässen Zigarettenfiltereinheiten; und
• Fig. 8, 9 und 10 verschiedene mögliche Membranstrukturen.

The invention is explained below using the drawing, for example. It shows

• 1 schematically shows in longitudinal section a first exemplary embodiment of an inventive cigarette filter unit fastened to a tobacco part;
• 2 shows schematically in longitudinal section a second exemplary embodiment of an inventive cigarette filter unit fastened to a tobacco part;
• 3 schematically, in longitudinal section, a third exemplary embodiment of an inventive cigarette filter unit fastened to a tobacco part;
• 4 schematically shows in longitudinal section a fourth exemplary embodiment of an inventive cigarette filter unit attached to a tobacco part;
• 5 schematically shows in longitudinal section a further exemplary embodiment of an inventive cigarette filter unit attached to a tobacco part;
• 6 and 7 possible courses of the amount of condensate C per train B when using further possible embodiments of cigarette filter units according to the invention; and
• 8, 9 and 10 different possible membrane structures.

In all of the exemplary embodiments described below, parts that are analogous to one another are provided with the same reference symbols, so that a repeated description of the same parts is unnecessary.

As can be seen from FIG. 1, the cigarette filter unit 2 ′, which is shown very schematically there and is fastened to a tobacco part 1 in the usual way by means of so-called tipping paper, has a sieve-shaped membrane 3 arranged in its flue gas flow cross section. With this membrane 3, the spatial distribution of the membrane openings over the entire membrane surface and the cross-sectional areas of the membrane openings in size and shape are precisely known in order to achieve precisely reproducible application behavior, and it consists of a synthetic fiber, e.g. Polymer fibers, manufactured fabrics.

The membrane 3 arranged in the filter unit 2 'is not intended to filter aerosols out of a flue gas stream flowing through them. The filtering capacity of the membrane 3 for the particular phase of the flue gas stream flowing through is measurable, but in practice it is very small and negligible.

The membrane 3 is therefore not intended to serve as a filter element, but rather as a switching element. For this purpose, the thickness of the membrane 3 must be very small, so that the latter causes a relatively small initial flow resistance. The effect of the membrane 3 in the filter unit 2 'is such that when a flue gas aerosol flows through the membrane 3, a very small proportion of the aerosol particles adhere to the membrane 3, but this proportion is large enough to cause a noticeable reduction of the free cross sections of the membrane openings and thereby to cause a sharp increase in the flow resistance caused by the membrane 3 thus loaded. For this purpose, the thickness of the membrane 3 is in a range from 30 to 100 μm, the number of membrane openings in a range from 500 to 25,000, and the cross section of the individual membrane openings in a range from 100 to 2500 μm ² .

In order to be sure that in the large-scale production of such cigarette filter units 2 ', exactly reproducible characteristic values of the latter are achieved, the membrane 3 must not consist of a material in which the spatial distribution of the flue gas through openings as well as their cross sections and cross-sectional shapes is random, as is the case e.g. the use of a thin, highly porous paper membrane would be the case where the loose paper fiber arrangement and thus the distribution and size of the passage openings formed in this way are very different locally.

For this purpose, it has proven expedient if the distance between the individual openings of the membrane 3 and the size of the cross-sectional areas of these openings deviate less than 10% from the specified value.

As can also be seen from FIG. 1, ventilation openings 4 extending between the inside and the outside of the filter unit 2 'are provided after the membrane 3, as seen in the flow direction through the filter unit 2'. The latter are provided in such a number and with such cross sections that, for example, an initial dilution of the tobacco smoke extracted from the tobacco part 1 of 50% is achieved.

The inner cross section of the filter unit 2 'is provided at the location of the membrane 3 except for the latter with a partition and support intermediate wall 5 connected to it and made of at least approximately gas-impermeable material.

In this embodiment, the partition and support partition 5 is provided with a plurality of flow openings 6 to achieve a flue gas diversion, the cross sections of which are, however, much larger than those of the membrane openings, for example at least ten times are bigger. Such a design allows a flue gas flow to be maintained even when the membrane 3 is almost or completely blocked, and limits the maximum possible suction resistance in use to a relatively precisely predetermined value.

If a cigarette provided with such a cigarette end piece 2 'as shown in FIG. 1 is smoked, then the tobacco smoke flow flows through the ignited cigarette when the smoker first pulls it, with a relatively small initial pressure drop of, for example, 30 mm WS caused by the membrane 3 the latter, whereby aerosol particles in the tobacco smoke adhere to the membrane 3 and increasingly reduce the free cross-section of the individual membrane openings with every train on the suction side of the filter unit 2 'and thus increase the pressure drop caused by the membrane 3, so that over the period of smoking of the tobacco part 1 seen with increasing blockage of the membrane 3 by smoke aerosol particles, the smoke sucked in by the smoker is increasingly mixed with air via the ventilation openings 4. It is thereby achieved that the increasing concentration of the tobacco smoke flowing into the filter unit 2 'increases with the shortening of the tobacco part 1, and after the membrane 3 in the filter unit 2' is again increasingly diluted with air, and thus the concentration during the consecutive puffs of the smoker In contrast to the past, the smoke that is sucked in can be kept constant within relatively narrow limits, and the aroma of the tobacco smoke soaked in by the smoker remains practically unchanged over the entire smoking time of the tobacco part 1.

In the exemplary embodiment shown in FIG. 2, in contrast to the example shown in FIG. 1, the through-flow openings are provided in the latter instead of in the partition and support wall 5 holding the membrane 3 by additional perforation 6 'of the latter.

In the embodiment shown in FIG. 3, to achieve two separate internal flow channels 10 and 11, the membrane 3 is arranged in the flow cross-section of a tube 7 made of practically gas-impermeable material and the remaining cross-section forming the second flow channel 11 between the outside of the tube 7 and the inside of the outer casing of the filter unit (2 '' ') is filled with filter material 9 which filters through tobacco smoke and which is provided with at least one through-opening whose cross-section is at least ten times larger than the cross-section of the largest membrane opening.

In this embodiment, the tobacco smoke initially passes unfiltered through the first flow channel 10 and through the membrane 3 into the smoker's mouth.

With increasing smoke time, the flow resistance of the membrane 3 increases, as already described above, and the increasingly concentrated tobacco smoke flowing out of the tobacco part 1 is thereby increasingly conducted via the second flow channel 11 through the filter material 9 filtering through the tobacco smoke, so that also by means of a such design of the filter unit 2 ″, the concentration of the various smoke gas components and thus the smell felt by the smoker can be kept relatively constant over the entire smoking period of the tobacco part 1 without the suction resistance determined by the smoker during smoking changing significantly or in an unpleasant manner.

In the exemplary embodiment shown in FIG. 4, in contrast to the example shown in FIG. 3, the interior of the tube 7 forming the first flow channel 10 is filled with a granular filter material 12, which can also be loaded with an aroma, and on the outside of the tube 7, a chamber filter 9 'is arranged in the second flow channel 11, in which an annular chamber 16 for receiving a free-flowing filter and / or aromatic carrier material is formed between an annular cellulose and an annular acetate plug.

The increasing flow diversion through the second flow channel 11, which is caused by the diaphragm 3 as the tobacco part 1 becomes more and more worn, is analogous to the exemplary embodiment shown in FIG.

With such a filter unit, it is possible to filter the tobacco smoke flowing through in a very differentiated manner over the entire smoking period and / or to enrich it with aroma, since tobacco smoke flows through practically only the first flow channel 10 and then increasingly the second flow channel 11.

In the exemplary embodiment shown in FIG. 5, in contrast to the example shown in FIG. 1, a cellulose or an acetate filter plug 13 or 14 is arranged in front of and behind the membrane 3 in the flow cross-section of the filter unit 2 "" analogously to a conventional dual filter, as seen in the flow direction.

The increasing smoking of the tobacco part 1 and increasing increasing the flow resistance caused by the increasingly clogging membrane 3 is increasingly sucked through the ventilation openings 4 by the smoker, the diluted tobacco smoke ventilation air, which passes through channels 15 in the mouth of the smoker.

As can be seen from FIGS. 6 and 7, in complete contrast to the cigarettes previously on the market, it is possible to produce such a cigarette end piece according to the invention, with the aid of which a smoking characteristic can be achieved, according to which after an initial increase in the condensate stop / train the same decreases with increasing smoking of the cigarette (FIG. 6) or decreases and thereafter remains approximately constant (FIG. 7).

In principle, different membrane sieves are shown in FIGS. 8, 9 and 10.

In the membrane screen shown in FIG. 8, the geometric distribution of the membrane openings and their cross sections are completely uniform.

In the membrane sieves shown in FIGS. 9 and 10, the geometric distribution of the membrane openings and their cross sections varies, but not randomly, but according to a precisely predetermined distribution arrangement.

Of course, other designs of mesh screens are also conceivable.

Claims (13)

1. Cigarette filter unit with at least one change-over member disposed in the smoke throughflow cross section for the automatic gradual change-over from an initial smoke path to at least a further smoke path within the filter unit, at the time of smoking, the change-over member covering part of the cross section of the latter being constructed as a screen-like membrane (3), in which the spatial distribution of the membrane openings and of their cross sectional areas in size and shape corresponds to a predetermined distribution, that the thickness of this membrane (3) lies within a range of 10 to 150 pm, the number of openings provided in the membrane (3) lies within a range of 500 to 25000 and the cross sectional area of these openings lies within a range of 80 to 3000 µm² respectively, and that at least one throughflow opening (6,6',11), whereof the cross section is at least ten times larger than the cross section of the largest membrane opening, is located in the region of the membrane (3) in the remaining part of the cross section of the filter unit.

2. Filter unit according to Claim 1, characterized in that seen in the flow direction, ventilation openings (4) extending between the inside and outside of the filter unit are provided after the membrane (3).

3. Filter unit according to one of the preceding claims, characterized in that the thickness of the membrane (3) lies within the range of 30 to 100 um and the cross sectional area of the individual openings in the membrane, which are provided in the manner of a screen, lies in a range of 100 to 2500 µm², preferably in a range of 100 to 1800 µm².

4. Filter unit according to one of the preceding claims, characterized in that the membrane (3) consists of natural textile and/or of synthetic fibres, preferably in the form of a woven material, or of a perforated foil.

5. Filter unit according to one of the preceding claims, characterized in that the ventilation air path comprises ventilation openings (4) in such a number and with such a cross section that an initial dilution with ventilation air is achieved in a range of 30 to 70%, preferably in a range of 45 to 55%.

6. Filter unit according to one of the preceding claims, characterized in that the number of openings provided in the membrane (3) and their cross sectional areas are coordinated with respect to each other so that when sucking a quantity of air of 17.5 mls/sec from the suction end of the filter unit, a pressure drop in the range of 25 to 150 mm WS is brought about by the latter.

7. Filter unit according to one of the preceding claims, characterized in that the spacing between individual openings of the membrane (3) and the size of the cross sectional areas of these openings varies by less than 10% from the predetermined value.

8. Filter unit according to one of the preceding claims, characterized in that according to an exactly predetermined distribution, the membrane (3) comprises openings of different cross sectional area determined exactly in their size.

9. Filter unit according to one of the preceding claims, characterized in that its internal cross section at the point of the membrane (3), apart from on the latter, is provided with a separating and supporting intermediate wall (5) connected to the membrane and consisting of a material which is at least approximately impermeable to gas.

10. Filter unit according to one of the preceding claims, characterized in that the separating and supporting intermediate wall (5) and/or the membrane (3) is provided with one or more through- holes (6, 6', 11), whereof the individual cross sectional areas are greater than 10⁴ p_m ².

11. Filter unit according to one of the preceding claims, characterized in that the membrane (3) is located in the flow cross section of a small tube (7) consisting of material which is at least approximately impermeable to gas and the remaining cross section between the outer side of the small tube (7) and the outer side (8) of the filter unit (2"') is filled at least over part of the length of the small tube with material (9) filtering tobacco smoke.

12. Filter unit according to Claim 11, characterized in that the small tube (7) serving for the formation of two separate flow passages (10, 11) is filled in its inside with granular and/or fibrous filter material (12), at least over part of its length.

13. Filter unit according to one of the preceding claims, characterized in that seen in the flow direction, in front of and/or behind the membrane (3), a filter member (13, 14) altering the composition of the tobacco smoke is disposed in the flow cross section of the filter unit (2"").

Images