The present invention relates to filters for cigarettes and other smoking articles.
A cigarette typically includes a tobacco rod and a filter connected to the tobacco rod. The filter is commonly made of cellulose acetate tow. A smoker ignites one end of the tobacco rod and draws smoke in through the filter. The filter traps some of the smoke products produced by the burning tobacco rod. In some cases, the filter can be arranged to impart additional characteristics to the cigarette such as flavour.
U.S. patent application US-A-2003/0224918 describes a device for applying a flavourant bearing element along the central axis of a cigarette filter during the filter manufacturing process. The preferred flavoured element is cotton yarn, but other suggested materials for the flavoured element are cellulose acetate, rayon, or some other textile or non-textile materials capable of absorbing a liquid flavourant. UK patent application GB-B-2020158 describes a similar filter to that disclosed in US-A-2003/0224918. A thread or tape, for example cotton sewing thread or rayon, extends along a filter rod. A flavourant is incorporated into the filter rod.
Although a cotton thread absorbs flavour during manufacturing and then imparts flavour during smoking, it does have certain drawbacks as a flavourant. For example, the cotton thread may become discoloured as a result of smoke passing through the filter. One option to avoid such discolouration is to apply a dye to the cotton thread (where the colour of the dye would mask any discolouration). However, standard vat dyes for cotton are primarily intended for use with clothing; they generally do not have regulatory approval for food products (or for cigarettes, which are inserted into the mouth). In addition, the dye applied to cotton material may not be entirely colour-fast, and may therefore leach into the surrounding filter material. This is especially a problem if the cotton thread is exposed to a substance which may act as a solvent.
One embodiment of the invention provides a filter for a cigarette or other smoking article. The filter comprises a porous filter rod having a substantially cylindrical shape, and a cellulose acetate thread formed from substantially uncrimped cellulose acetate filaments. The cellulose acetate thread extends along the filter substantially parallel to the central cylindrical axis of the filter rod.
The use of cellulose acetate filaments for the central thread has been found to unexpectedly reduce or eliminate staining of the filter by smoke (compared to the use of a central thread made of cotton, for example). Having the filter made of uncrimped filaments is believed to assist with this, since it allows a tighter and more compact thread to be produced. Consequently, it is more difficult for the smoke to penetrate and stain the thread.
In general, the cellulose acetate thread extends along substantially the whole length of the filter rod. However, in other embodiments, the cellulose acetate thread may only extend partway along the length of the filter rod (especially for example if a multi-segmented filter is being used).
In one embodiment, the porous filter rod comprises cellulose acetate tow (although any other suitable filter material, e.g. paper, could be used instead). The cellulose acetate tow comprises a disordered overlapping arrangement of cellulose acetate filaments. In contrast, the cellulose acetate thread comprises an ordered arrangement of cellulose acetate filaments arranged substantially parallel to the central cylindrical axis of the filter rod. The cellulose acetate thread is therefore structurally distinct from the cellulose acetate tow, and the filaments of the cellulose acetate thread do not generally intermingle with those of the cellulose acetate tow.
The porous filter rod generally has a bulk density in the range 50-150 kg/m3, while the cellulose acetate thread has a bulk density in the range 400-800 kg/m3. The higher bulk density of the cellulose acetate thread can help to prevent staining and discolouration. In one particular embodiment, the cellulose acetate filaments in the thread are twisted about an axis aligned with the central cylindrical axis of the filter rod. The thread has a twist rate in the range 100-200 turns per metre.
The cellulose acetate thread generally incorporates a flavourant, such as menthol, or any other desired additive. In one particular embodiment, the filter comprises multiple cellulose acetate threads extending substantially parallel with the central cylindrical axis of the filter rod. These different threads may be separate from one another or twisted together into a single fibre. The different threads can be used to incorporate different flavourants.
In one embodiment, the cellulose acetate thread includes a pigment to impart colour to the thread. The pigment is incorporated directly into the material of the thread filaments at manufacture. This avoids the danger of colour leaching (in contrast to the situation with a cotton thread, where a dye can only be applied to the surface of the cotton, and is therefore susceptible to leaching).
In some embodiments, the cellulose acetate thread has a different colour from the porous filter rod. This colour contrast makes it easier for a machine control system to ensure that the thread is correctly placed within the filter rod, and may also be used for aesthetic and/or branding purposes. One possibility is that the particular pigment or colour used for a given thread may be used to indicate the flavour incorporated into the thread. For example, a green thread might be used to indicate a menthol flavourant.
In one embodiment, the cellulose acetate thread incorporates a plasticiser such as triacetin. The plasticiser can help the cellulose acetate filaments of the main filter rod to bond with the cellulose acetate filaments of the cellulose acetate thread (exploiting the fact that both the main filter rod and the cellulose acetate thread are formed from a synthetic material). This helps to retain the cellulose acetate thread in the correct position in relation to the filter rod.
In one embodiment, the cellulose acetate thread extends along the central cylindrical axis of the filter rod. This arrangement helps to provide a uniform distribution/dispersion of any flavourant incorporated into the filter. In another embodiment, there are multiple cellulose acetate threads extending along the filter substantially parallel to the central cylindrical axis of the filter rod. These multiple cellulose acetate threads may be arranged in a symmetric pattern about the central cylindrical axis of the filter rod, again to provide a substantially uniform dispersion of flavourant through the filter. Note that providing multiple threads in the filter can be used to increase total loading of flavourant within the filter, or to reduce the loading of flavourant per filter (which may assist with manufacturing, product storage, etc).
Another embodiment of the invention provides a filter for a cigarette or other smoking article. The filter comprises a porous filter rod having a substantially cylindrical shape, and a cellulose acetate thread formed from cellulose acetate filaments that include a pigment. The cellulose acetate thread extends along the filter substantially parallel to the cylindrical axis of the filter rod. The pigment can be used to impart a colour to the cellulose acetate thread, for example to assist with checking the positioning of the thread within the filter during manufacture.
This embodiment may benefit from the same features as described above in relation to the previous embodiments.
Another embodiment of the invention provides a filter for a cigarette or other smoking article. The filter comprises a porous filter rod having a substantially cylindrical shape, and a cellulose acetate thread formed from cellulose acetate filaments. The cellulose acetate thread incorporates a plasticiser and extends along the filter substantially parallel to the central cylindrical axis of the filter rod.
This embodiment may benefit from the same features as described above in relation to the previous embodiments.
Another embodiment of the invention provides a filter for a cigarette or other smoking article. The filter comprises a porous filter rod formed from cellulose acetate filaments and having a substantially cylindrical shape. The filter further comprises a cellulose acetate thread formed from cellulose acetate filaments that extend along the filter substantially parallel to the central cylindrical axis of the filter rod. The porous filter rod has a bulk density in the range 50-150 kg/m3, while the cellulose acetate thread has a bulk density in the range 400-800 kg/m3. The higher bulk density of the cellulose acetate thread can help to prevent staining and discolouration.
This embodiment may benefit from the same features as described above in relation to the previous embodiments.
Another embodiment of the invention provides a method of making a filter for a cigarette or other smoking article. The method comprises forming a cellulose acetate thread from substantially uncrimped cellulose acetate filaments. The method further comprises inserting the cellulose acetate thread into a porous filter rod having a substantially cylindrical shape, such that the cellulose acetate thread extends along the filter substantially parallel to the central cylindrical axis of the filter rod.
Another embodiment of the invention provides a method of making a filter for a cigarette or other smoking article. The method comprises forming a cellulose acetate thread from cellulose acetate filaments together with a pigment. The method further comprises inserting the cellulose acetate thread into a porous filter rod having a substantially cylindrical shape, such that the cellulose acetate thread extends along the filter substantially parallel to the central cylindrical axis of the filter rod.
Another embodiment of the invention provides a method for making a filter for a cigarette or other smoking article. The method comprises applying plasticiser to a cellulose acetate thread formed from cellulose acetate filaments. The method further comprises inserting the cellulose acetate thread into a porous filter rod having a substantially cylindrical shape, such that the cellulose acetate thread extends along the filter substantially parallel to the central cylindrical axis of the filter rod. The plasticiser may migrate from the thread to the porous filter rod, thereby helping to bind the two together.
These method embodiments may benefit from the same features as described above in relation to the other embodiments.
Embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings where like parts are provided with corresponding reference numerals and in which:
The filter rod 3 is formed from cellulose acetate filaments that are crimped, stretched and then assembled to form a porous matrix having a chaotic, amorphous structure (see
The crimp ratio (CR) of a fibre is a measure of the amount of crimping in a fibre and is defined as the ratio of the length (L1) of the uncrimped fibre to the length (L2) of the crimped fibre (the former being measured by extending the fibre under load). The higher the crimp ratio, the greater the amount of crimping, and hence the greater the reduction in length of the crimped fibre from its original (uncrimped) length. The crimp ratio can also be expressed as a percentage, known as the crimp index (CI), defined as 100*((L1-L2)/L2) (so that CI=100*(CR-1)).
The cellulose acetate filaments used in filter rod 3 are generally initially prepared with a high crimp ratio of perhaps 3-4. These filaments are then stretched during the filter manufacture, so that the crimp ratio of the filaments in the cellulose acetate tow within the filter itself is typically 1.25-1.4. The crimping helps to bulk out the tow material, as well as giving it the desired disordered structure shown in
The cellulose acetate filaments used in filter rod 3 generally have a denier of approximately 1-8, with 2-3 being most common (1 denier represents a mass of 1 g/9000 m). The total denier of the filter rod 3 is given by the denier of the individual filaments multiplied by the number of filaments included within the rod, and is generally within the range 15,000-50,000 for cigarette filters; most commonly about 32,000. This corresponds to a typical density of about 50-150 kg/m3 for a standard sized filter for a cigarette.
As shown in
The CA thread 4 is formed from substantially continuous cellulose acetate filaments, as for the cellulose acetate tow, but the processing is different. The filaments forming the CA thread do not undergo crimping. In addition, the filaments of the CA thread are wound or twisted in a regular pattern to produce an ordered structure (see
A comparison of the tow material of
The filaments in the CA thread 4 may have a higher denier value compared with the material of the main filter rod. For example, in one embodiment, the filaments in CA thread 4 have a denier value of approximately 4,while in another embodiment the filaments in CA thread 4 have a denier value of approximately 7. A higher denier results in a thicker filament.
The total denier of the thread 4 is generally in the range 1000-5000, for example, 3000. Bearing in mind the relatively small size of the CA thread 4 compared to the filter rod 3, this implies a higher density for the CA thread of approximately 400-800 kg/m3. This higher density is in part due to the higher denier per filament, and also due to the tighter packing of the uncrimped, ordered filaments within the CA thread 4 (compared to the looser and disordered packing of the crimped filaments within the tow material). The higher density of the CA thread 4 compared to the tow material of the main filter body 3 may assist the CA thread 4 in resisting staining by smoke.
Note that after assembly of the filter 1, the thread 4 and the main filter body 3 remain structurally distinct from one another within the filter 1. Thus
Thus it can be imagined that there is a boundary between the central thread 4 and the main filter rod 3. The cellulose acetate filaments in the central thread 4 and the main filter rod 3 generally do not cross this boundary, although they may contact one another at the boundary.
In the embodiment of
It has been found that the CA thread 4 in filter 1 does not generally suffer from discolouration when a cigarette is smoked. This unexpected result is believed to be due to the increased density and ordered structure of the CA thread, which may prevent the smoke particles from penetrating (and hence staining) the CA thread 4. It will be appreciated that the absence (or reduced level) of discoloration is visible to a consumer, and may be perceived as a mark of improved quality (where the CA thread 4 extends to the mouth end of the filter 1, as shown in
In one embodiment, the CA thread 4 is coloured. As cellulose acetate is formed using a synthetic process (albeit from natural products), one or more pigments can be incorporated into the cellulose acetate filaments as they are produced. Such pigments in effect become part of the substrate of the material, in contrast to dyes, which are applied to the surface of a material. Consequently, the pigments incorporated into the CA thread 4 cannot leach (they are colour-fast), unlike those applied to a cotton yarn.
Some of the pigments that may be used to colour the CA thread are already approved for use in food products (such as tartrazine yellow or E102). This makes it much easier from a regulatory perspective to use such pigments in cigarette filters. In addition, having a wider range of available pigments provides a greater choice (and control) of the colour applied to the CA thread 4.
In most filters, the cellulose acetate tow of the main filter rod 3 incorporates a white pigment (e.g. titanium dioxide). The CA thread 4 may also be coloured white to match the rest of the filter rod, or alternatively the CA thread 4 may have a different colour from the main filter rod. There are potential benefits in having contrasting colour for the CA thread 4 compared to the main filter rod. For example, different colours for the CA thread 4 may be used to indicate different flavourants in the cigarette, e.g. green for menthol, etc.
In addition, the ready visibility of the CA thread 4 serves as a deterrent to potential counterfeiters. Thus any counterfeit cigarettes must also include the central thread (otherwise they would be readily detected by consumers). However, this raises the manufacturing complexity and costs for the potential counterfeiters compared to making a filter just out of conventional cellulose acetate tow.
Furthermore, in a current implementation, the difference in colour between the filter rod 3 and the CA thread 4 allows a machine vision system to confirm automatically that the CA thread 4 is present and correctly positioned along the central axis of the filter 1. This is an important quality control parameter for the manufacturing process—if the CA thread is off-centre in the filter 1, this might impact the flavour-dispersal properties.
A further benefit of using cellulose acetate rather than cotton for the central thread is that a CA thread is less susceptible than cotton or many other materials to changes in length. For example, cotton is relatively elastic. If cotton yarn is used as a central element in a filter rod, the cotton may be held under tension during the manufacturing process. When the filter rod is cut into segments and the tension therefore released, the cotton may return to its original length, and so retract into the body of the filter rod. In this case, the cotton may no longer be visible at the ends of the filter, and hence cannot be used by a machine vision system to confirm the positioning of the central element. Forming the central thread out of cellulose acetate, which is less elastic than cotton, helps to avoid such problems by reducing any change in length of the central thread during manufacture.
In known filters (with or without a central thread), it is common to use a plasticiser, such as triacetin (1,2,3-triacetoxypropane), to bind the cellulose acetate filaments in the filter material via cross-linkage. This results in a more robust filter material that can be cut more cleanly. Such a plasticiser however has little or no effect on cotton (which is a natural fibre). As a result, there is little if any binding or cross-linkage between a central thread made of cotton yarn and the surrounding cellulose acetate tow of the main filter rod. This leads to the risk that if the central thread is made of cotton, it may become displaced or separated from the filter, for example during the manufacturing process, or as the result of manipulation by the consumer. This in turn will generally degrade delivery of the flavourant (as well as being perceived by consumers as a potential quality defect).
In contrast, any triacetin or other plasticiser applied to the filter can help to bind the CA thread 4 to the cellulose acetate tow of the main filter rod 3. In particular, the triacetin interacts with the filaments of cellulose acetate in the CA thread 4 in substantially the same manner that it interacts with the filaments of cellulose acetate in the tow material of the main filter rod 3. This can then lead to improved binding between the CA thread 4 and the cellulose acetate tow of the main filter rod 3, thereby helping to retain the CA thread 4 at its proper central position within the filter 1.
In one embodiment, triacetin is applied to just the cellulose acetate tow of the main filter rod 3 (as for a conventional filter), and this triacetin is then allowed to migrate into the CA thread 4. However, it is believed that a stronger binding can be obtained by applying the triacetin directly to the CA thread 4 itself (with or without also applying the triacetin to the tow material as well). In one embodiment, triacetin is used as a solvent for the flavourant that is applied to the CA thread 4, from where the triacetin can migrate to the tow material.
In some embodiments, more than one thread (e.g. 2, 3, 4 or 5 threads) may be used to provide the central flavour element. The multiple threads may all be same as one another (e.g. have a common thickness) or may be different from one another. The threads may be wound together to create a larger fibre or yarn, or alternatively the different threads may be kept separate (whether adjacent to one another or separated from one another). Providing multiple threads within the filter may be used to reduce the loading of flavourant per thread (which may assist with manufacturing, product storage, etc). Alternatively, having multiple threads in the filter can be used to increase the total loading of flavourant within the filter. A further possibility is that different threads may be provided with different flavourants or other additives (the different threads may be coloured differently to indicate this fact).
In some embodiments, the different threads may be located in positions so as to provide a configuration within the filter that is symmetric about the central longitudinal axis of the filter. This can help to produce a uniform dispersal or distribution of flavourant within the filter.
Various modifications may be made to the embodiments herein before described without departing from the scope of the invention. For example, different filaments of the same thread may have different colouring or thickness. Accordingly, the scope of the invention is defined by the appended claims.
Number | Date | Country | Kind |
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0713905.8 | Jul 2007 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP08/58332 | 6/27/2008 | WO | 00 | 6/21/2010 |