JPH08322538A - Filter for cigarette - Google Patents

Abstract

PURPOSE: To obtain a filter for cigarette capable of filtering a smoked amount on smoking with reduction of a used amount of a filter material without clogging by specifying an air-flow resistance, a rate of filtration, a porosity and a thickness of the filter material respectively. CONSTITUTION: This filter for cigarette consists of a hollow mouthpiece to be connected to the cigarette 2, a plate filter material 8 for filtering inhaled smoke from the cigarette and arranged at the mouthpiece and a space divided by the filter material 8 in the mouthpiece. In the filter material 8, each fiber is transversely arranged against a stream direction of the inhaled smoke. The filter material is made to have <=5mm thickness to specify to have 10-90mm H2 O air-flow resistance, 5-70% filtration rate of fine particles included in the inhaled smoke, <=20μm fiber diameter and 80-95% porosity in the filter material 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cigarette filter for filtering inhaled smoke from a cigarette during smoking.

[0002]

2. Description of the Related Art In a filter of a filter cigarette, the filter material is an acetate fiber bundle, and individual fibers of the acetate fiber bundle extend in the axial direction of the cigarette. The quality of the filter material for cigarettes depends on the particulate matter (T
In addition to filtering PM (Total Particular Matter) appropriately, it is required to have appropriate ventilation resistance in order to obtain a feeling of inhaling smoke flow, and normally, each of these TPM filtration rate and ventilation resistance is , The filter cigarette is contained in an appropriate range according to the brand.

In order to meet the above requirements regarding the TPM filtration rate and the ventilation resistance, in the case of the conventional filter, it is necessary to secure a sufficient length in the acetate fiber bundle. Therefore, in the conventional filter, not only the acetate fiber bundle itself is bulky but also its weight is relatively large, which is not preferable from the viewpoint of resource saving.

For this reason, various attempts have been made in the past to use a disk-shaped filter material instead of the acetate fiber bundle, one example of which is, for example, Jitsuko Sho-45-503.
No. 9 and JP-A-49-41599, respectively.

[0005]

The filter disclosed in the former publication is provided with a plurality of filter bodies as filter materials, that is, filter papers in its mouthpiece, and these filter papers are arranged in the axial direction of the mouthpieces. Are arranged at predetermined intervals. Although the use amount of filter paper as the filter material can be reduced, the filter paper itself has a problem that it is easily clogged with the condensate of the collected fine particle components because its filtering and dust removing method is surface filtration. .

On the other hand, in the filter disc disclosed in the latter publication, the filter material is a polymer fiber cloth. The individual fibers of the fiber cloth have a diameter of 5 μm or less, and most of them extend across the flow of the inhaled smoke. Such a filter material has a sufficiently high TPM filtration rate as compared with the above-mentioned filter material composed of an acetate fiber bundle, and if the filter disk is used alone as suggested in the publication, the filter material is It is thought that the amount used can be reduced significantly.

However, when a filter material having a high TPM filtration rate is used, not only is it easily clogged by the condensate of the collected fine particle components, but also because the condensate is thin, the condensate is also from the back surface of the filter material. There is a risk of leakage. Therefore, in the preferred embodiment disclosed in the latter publication, the filter disk described above is sandwiched between conventional filters made of acetate fiber bundles, and the amount of filter material used as a whole is reduced. It has not been.

Further, in any case, the filter disclosed in the above publication is developed after the quality of the filter material, that is, the TPM filtration rate and the ventilation resistance thereof are set within the allowable range required as the filter material for cigarette. Therefore, even if the filter material is used in place of the usual acetate fiber bundle, the taste of the cigarette is changed, and the suction is uncomfortable.

The present invention has been made based on the above-mentioned circumstances, and its purpose is to ensure the same quality as an ordinary filter without causing the filter material to be clogged. An object of the present invention is to provide a cigarette filter capable of reducing the usage amount.

[0010]

The above-mentioned object is achieved by a cigarette filter according to the present invention, in which the individual fibers are arranged in a direction transverse to the flow direction of the smoke inhaled from the cigarette. Equipped with an array of filter materials, this filter material has a ventilation diameter and a filtration rate of fine particle components in inhaled smoke of 10 to 90 mmH ₂ O and 5 to 70%, respectively, and a fiber diameter of 20 μm or less. In addition, the thickness is set within 5 mm in order to secure the porosity of the filter material to 80 to 95%.

According to the filter of claim 2, the filter material is composed of a non-woven fabric, and according to the filter of claim 3, the filter material has a multilayer structure, and at least one of the layers has an additive. Are included in a distributed state. According to the filter of claim 4, the mouthpiece portion includes a hollow cylindrical body, and the additive is attached to the inner peripheral surface of the hollow cylinder body. The aroma generator is stored in the space.

Further, according to the filter of the sixth aspect, the suction port portion is provided with an air port.

[0013]

According to the filter of claim 1, even if the individual fibers of the filter material are arranged in a direction transverse to the flow direction of the smoke, the ventilation resistance of the filter material and its filtration rate (TPM filtration). The rate is 10 to obtain the same taste and inhalation feeling as when using a normal filter material when smoking.
90mmH are housed respectively ₂ O and 5% to 70% range.

Even if the filter material is a thin plate having a thickness of 5 mm or less, its fiber diameter is 20 μm or less in order to sufficiently retain the collected fine particle components.
It has a porosity of 80 to 95%. According to the filter of claim 2, the filter material is obtained by cutting out a nonwoven fabric.

According to the filters of claims 3 and 4, at least one layer in the filter material having a multilayer structure, or
The additive provided on the inner peripheral surface of the hollow cylindrical body at the mouth portion acts on the inhaled smoke and exerts its function. According to the filter of claim 5, when the aroma is generated from the aroma generator, the aroma is added to the taste of the cigarette.

According to the filter of claim 6, at the time of smoking, by the air introduced from the air vent opening of the suction port,
Inhaled smoke is diluted and the cigarette taste becomes lighter.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to FIGS. 1 and 2, there is shown a filter cigarette having a filter according to an embodiment, which has a cigarette 2. The cigarette 2 is obtained by wrapping a chopped tobacco T in a rod shape with a wrapping paper 4, and the chopped tobacco T is inside the base end portion.
Is not filled and is empty. That is, the portion of the wrapping paper 4 that forms the void forms the outer cover 6f of the filter 6 itself.

A filter material 8 is arranged in the outer cover 6f of the filter 6, and the filter material 8 has a disk shape and is in close contact with the cut tobacco T in the cigarette 2. Further, a sleeve 10 having a hollow cylindrical shape is inserted into the outer cover 6f, and the filter material 8 is held in a state of being sandwiched between the cut tobacco T and the sleeve 10. Here, the sleeve 10 can be obtained by forming a paper thicker than the wrapping paper 4 into a cylindrical shape or by using a synthetic resin tube.

Therefore, a space 12 defined by the filter material 8 and the sleeve 10 is secured in the filter 6, and the other end of this space 12 is opened at the suction end of the filter 6. The filter material 8 is made of a polymer fiber cloth, and the fibers are in a direction transverse to the flow direction of the smoke inhaled from the cigarette 2, that is, the cigarette 2
Are arranged in a direction intersecting the axis line of.

Specifically, the filter material 8 can be obtained by punching a non-woven fabric, and the non-woven fabric can be manufactured by various methods such as a melt blow method.
The filter material applied to cigarettes has the same ventilation resistance during smoking and the filtration rate (TPM filtration rate) of the fine particle components contained in the inhaled smoke, as is the case with ordinary filter materials made of fiber bundles such as acetate and pulp. You can secure the level,
Moreover, it should not cause clogging during smoking.

Therefore, various filter materials were attached to the holder 14 for measuring filtration characteristics shown in FIG. 3 and a smoking test was conducted to examine the TPM filtration rate and the presence or absence of clogging.
First, the measurement holder 14 will be briefly described. The measurement holder 14 is roughly classified into a smoking holder 16 and a smoking holder 16.
And a Cambridge filter holder 18. The smoking holder 16 has a cigarette holder 20 into which a cigarette S for measurement is inserted, and a clamp tube 22 that is screwed into the cigarette holder 20 coaxially with the cigarette S. The filter material to be measured is detachably sandwiched between the one end and the cigarette holder 20.

On the other hand, the Cambridge filter holder 18 has a built-in Cambridge filter 24, one end of which is separably and airtightly connected to the smoking holder 16 and the other end of which is not shown in the drawings. (Made by the company). Smoking of the cigarette S for measurement by an automatic smoking device, that is, its burning is carried out under standard smoking conditions according to the TIOJ (Japan Tobacco Association) method, and each filter material to be measured has a diameter of 10 mm. Needless to say, the cigarette S and the individual filter materials F used for the measurement are harmonized under the same condition in order to obtain an accurate measurement result.

The results of the smoking test using the above-mentioned measuring holder 14 are shown in Table 1 below.

[0024]

[Table 1]

In Table 1, sample A of filter material
.About.J are made of the following materials, and all the samples other than J have their fibers arranged in a direction transverse to the smoke inhaled from the cigarette S. A: Neo sheet made of pulp fiber B: Non-woven fabric made of thermoplastic polymer fiber (BTS1075) C: Non-woven fabric made of thermoplastic polymer fiber (PC1150) D: Non-woven fabric made of thermoplastic polymer fiber (XG-70) E: Nonwoven fabric made of pulp fiber F: Nonwoven fabric made of thermoplastic polymer fiber (DF-1-70) G: Nonwoven fabric made of ultrafine fiber H: Air cleaning filter I: Nonwoven fabric made of glass fiber J: Ceramic filter Sample B, C, and D are products of the same manufacturing company, and have different fiber diameters. Further, Table 1 also shows the physical properties, clogging property and TPM filtration rate of a filter material composed of an ordinary acetate fiber bundle or pulp fiber bundle, that is, an acetate plug or a neo plug.

The ventilation resistance of each sample is a value obtained from the results of the following measurement tests. In this measurement test, the sample and the U-shaped water column meter were connected in parallel to the vacuum pump,
The vacuum pump draws gas through the sample. And the flow rate of gas passing through the sample is 17.5 ml / s
The scale of the water column meter is read when the temperature reaches, and the value is measured as the ventilation resistance of the sample.

The porosity of the sample is a value calculated from the following formula. Porosity (%) = (1-W / (t × ρ × 1000)) × 100 W is the weight per 1 m ² of the sample (g / m ² ), t is the thickness of the sample (mm), ρ is the sample The specific gravity (g / cc) of each is shown. Further, the TPM filtration rate of the sample is a value calculated by the following formula from the amount of trapped (the condensate of fine particle component) trapped by the sample itself and the Cambridge filter in the smoking test described above.

TPM filtration rate = Sample collection amount / (Sample collection amount + Cambridge filter collection amount) As is clear from Table 1, all of samples A to F in samples AJ are clogged. However, among these samples A to F, samples B to F are suitable for the filter material of the filter cigarette because of both the ventilation resistance and the TPM filtration rate.

Here, as shown in FIG. 4, when the ventilation resistance is plotted on the horizontal axis and the porosity is plotted on the vertical axis, it is divided into regions 1-7. J
Will be included. The sample A contained in the region 1 has a very small air flow resistance and a large porosity, and has a rough internal structure. Therefore, the fine particle component in the inhaled smoke passes through the sample A as it is, and the TPM filtration rate cannot be measured substantially. Therefore, the value of the TPM filtration rate is not shown in Table 1. Sample A like this does not clog, but when smoking
I can't get that feeling. Even if a filter material having a thickness of 5 mm or less is formed by stacking a plurality of Samples A, the airflow resistance of each Sample A is extremely small. Therefore, the airflow resistance as a whole cannot be sufficiently secured. No, it is completely unsuitable as a filter material for cigarettes.

On the other hand, the samples G, H, and
Since I has a very large ventilation resistance, it gives a great resistance to inhalation of inhaled smoke during smoking, making it difficult to smoke, and, as shown in Table 1, its porosity is small. All of them are clogged, which is not suitable as a filter material for cigarettes. Also,
Since the sample J included in the region 7 has a large air flow resistance, it not only has the same problems as those of the samples G, H, and I, but is not flammable because the material is a composite material containing ceramics. It is not suitable as a filter material for cigarettes.

Although the sample B contained in the region 2 has a small air flow resistance, it does not cause clogging because its porosity is at the same level as that of a normal acetate plug or neo plug, and therefore the cigarette is It is suitable as a filter material. In order to obtain the same air flow resistance and TPM filtration rate as those of ordinary acetate plugs and neo plugs, it is sufficient to make the total thickness within 5 mm and use a sample B in which a plurality of samples B are stacked.

Since the sample F contained in the region 4 is obtained by thermoforming (embossing), it has a structure in which the difference in the internal and external structures is large and the openings are partially present. are doing. Therefore, although the sample F has smaller airflow resistance and porosity than those of ordinary acetate plugs and neo plugs, it does not cause clogging, so this sample F is also suitable as a filter material for cigarettes. Becomes Also in the case of sample F, as in the case of sample B, by stacking a plurality of sheets with the total thickness within 5 mm, the air flow resistance and TPM filtration rate of the filter material can be adjusted by using a normal acetate plug or neo plug. It can be set to the same level as.

The samples C and E contained in the region 3 have slightly lower airflow resistance than ordinary acetate plugs and neo plugs, but their porosity is at the same level and no clogging occurs. Therefore, these samples C and E can be sufficiently used as a filter material for cigarettes. Although the sample D contained in the region 5 has both smaller air flow resistance and porosity than those of ordinary acetate plugs and neo plugs, this sample D is not clogged, so this sample D is also for cigarette. Suitable as a filter material.
Also in the case of this sample D, the air flow resistance and the TPM filtration rate of the filter material can be set to the same level as those of a normal acetate plug or neo plug by increasing the thickness or stacking a plurality of sheets.

As described above, since samples BF can be used as the filter material for the cigarette, samples BF can be used when selecting the filter material.
Considering the ventilation resistance, TPM filtration rate and porosity, the filter material has a ventilation resistance in the range of 10 to 90 mmH ₂ O, a filtration rate in the range of 5 to 70%, and a porosity of 80 to 95. It turns out that it is good if it is in the range of%.

When Samples B to F are used as the filter material, the thickness is kept within 5 mm without causing clogging, so that a normal acetate plug or neo plug requiring a length of 25 mm is used. Compared with (see Table 1), the material of the filter material can be significantly reduced. It is considered that the reason why the thin filter materials obtained by using Samples B to F are not clogged is that their porosity is sufficiently secured.
That is, if the porosity is sufficiently large, the fine particle component collected from the inhaled smoke can be sufficiently retained therein, and as a result, clogging by the condensate of the fine particle component can be prevented.

In addition, the reason why the TPM filtration rate can be sufficiently ensured in spite of the fact that the filter materials using the samples B to F are very thin is that the fibers are in the direction transverse to the flow direction of the inhaled smoke. Because it is arranged. That is,
Fig. 5 shows the models of the internal structure of the filter material. In the case of the model (a) in which the fibers are arranged in parallel with the flow direction of the inhaled smoke, such as a normal acetate plug or neo plug, The flow rate of the inhaled smoke that simply passes through the gaps between the fibers is large, and it is considered that the effect of collecting the fine particle components in the inhaled smoke is small.

On the other hand, in the case of the model (b) in which the fibers are arranged transversely to the flow direction of the inhaled smoke as in the samples B to F, the inhaled smoke is evenly distributed with respect to the fibers. Since the particles flow while colliding, it is considered that the particulate component in the inhaled smoke is effectively captured and the collection efficiency thereof is increased. Therefore, in FIG. 6, as compared with the filter material of the model (a), the filter material of the model (b) can efficiently collect a relatively large particle component contained in the inhaled smoke.

As a result, a filter material suitable for cigarettes can be obtained if the filter material has a ventilation resistance and a TPM filtration rate within the above-mentioned allowable range and a porosity of 80 to 95% is secured. be able to. On the other hand, considering that the ventilation resistance and the porosity of the filter material depend on the thickness and the fiber diameter, Samples B to F
As is clear from the above, the fiber diameter is, for example, 0.5 to 20.
If the thickness is 5 mm or less and the ventilation resistance and the porosity are set to appropriate values within the above range, the TPM filtration rate can be set within the allowable range. It is possible to obtain a thin-layer filter material that has a value and that reliably prevents clogging.

The present invention is not limited to the above-mentioned embodiment. For example, the filter material 8 has its ventilation resistance and TPM filtration rate within the permissible range and is free from clogging.
In addition, flammable fiber materials other than the samples B to F can be used as long as the thickness can be made smaller than the length of a normal acetate plug or neo plug. Further, in the above-mentioned embodiment, the filter material is obtained from a single material, but the filter material may be any combination of materials such as samples B to F.

Referring to FIGS. 7 and 8, a modification of the filter 6 is shown. The filter 6 of this modified example has an outer cover made of a tip paper piece 26, not a part 6f of the wrapping paper 4 of the cigarette 2. The tip paper piece 26 is wound around the filter material 8 and the sleeve 10 from the outside, and connects the filter 6 to the cigarette 2.

Referring to FIG. 9, a modification of the filter material 8 is shown. In the case of this modification, the filter material 8
Is a filter element 2 similar to the sample C described above.
It has a double structure in which two sheets of 8 and 30 are stuck together. Then, in one of the filter elements 30, an additive 3 consisting of charcoal particles or a granular complex containing a desired flavorant is added.
2 are evenly distributed. Needless to say, even if the filter material 8 has a double structure, its ventilation resistance, TPM filtration rate and porosity are within the permissible ranges and no clogging occurs.

Referring to FIG. 10, the granular additive 32 is uniformly attached to the inner peripheral surface of the sleeve 10 in the filter 6. If the above-mentioned additive 32 is charcoal particles, the filter 6 can exhibit the same function as a so-called dual filter, and if the additive 32 is a complex, the filter 6 is desirable for inhaled smoke. A flavor can be added.

Referring to FIG. 11, the aroma generating body 36 made of beads or capsules is housed in the space 12 of the filter 6, that is, in the sleeve 10. The fragrance generator 36 has a fragrance such as menthol enclosed therein, and the enclosed fragrance can be generated when the fragrance generator 36 is crushed by an external force. Therefore, the smoker can add the aroma to the inhaled smoke by crushing the aroma generating body 36 with the finger through the filter 6 according to the mood at that time. Further, in the sleeve 10, a net 38 having a mesh structure is arranged so as to sandwich the aroma generating body 36 between the sleeve 10 and the filter material 8. Further, the net 38 has an inner sleeve 40 and an inner sleeve 40. Held in. As the net 38, for example, a sheet such as Sample A having a small air flow resistance can be used, and the net 38 can be attached to the inner open end of the inner sleeve 40 in advance.

The fragrance generator 36 shown in FIG.
Referring to FIG. 12, the capsule 6 has a smaller particle size than the aroma generating body 36 in the space 12 of the filter 6 and a larger particle size than the microcapsules encapsulating the aroma or the aforementioned complex. Packing 3 composed of complex
4 is filled. Even in these cases, a desired aroma can be added to the inhaled smoke during smoking.

Further, referring to FIGS. 13 and 14, air holes 42 are formed on the outer peripheral surface of the filter 6, respectively. These air ports 42 are arranged at intervals in the circumferential direction of the filter 6 and communicate with each other in the space 12, but their communicating positions are different from each other. That is, FIG.
In the case of the filter 6 of FIG. 4, the air port 42 is positioned outside the filter material 8, whereas in the case of the filter 6 of FIG. 14, the air port 42 is positioned between the cigarette 2 and the filter material 8. Has been. These FIG. 13,
According to the filter 6 of 14, when smoking, the smoke sucked from the cigarette 2 is diluted by the air flowing in from the air port 42, so that a light taste can be enjoyed.

[0046]

As described above, according to the cigarette filter of claim 1 of the present invention, the ventilation resistance and the filtration rate of the filter material can be set in the same range as in the case of a normal filter. Moreover, since the fiber diameter is within 20 μm and the thickness is 5 mm or less in order to secure a porosity of 80 to 95%, it does not cause clogging and is similar to a normal filter plug. It is possible to obtain excellent filter performance. In addition, since the filter material can be made very thin compared to ordinary acetate plugs and neo plugs, not only can the amount of material used be greatly reduced, but the thin filter material is useful in the filter. There is an advantage that a large space can be secured.

According to the filter of claim 2, the filter material can be easily obtained by punching out a non-woven fabric. According to the filter of claims 3 and 4, since the additive is incorporated, the addition of the additive is possible. The function of the object can be added to the inhaled smoke, and in the filter of the fourth aspect, the space in the filter can be effectively used. Further, according to the filter of claim 5, since the aroma generator is contained as an effective use of the space, it is possible to selectively add the aroma from the aroma generator to the taste of the cigarette itself. According to the filter of the sixth aspect, the inhaled smoke is diluted by the air introduced through the air port, and a light smoking can be enjoyed.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of a filter cigarette including a filter according to an embodiment, with a part thereof broken away.

FIG. 2 is a vertical sectional view of the filter cigarette shown in FIG.

FIG. 3 is a longitudinal sectional view showing a smoking holder used in a smoking test.

FIG. 4 is a diagram showing characteristics of samples used in a smoking test, which are classified according to porosity and ventilation resistance.

FIG. 5 is a diagram schematically showing the difference in fiber arrangement between a conventional acetate or neo plug and the filter material of the embodiment.

FIG. 6 is a schematic diagram showing a difference in filter function between a conventional acetate or neo plug and a filter material.

FIG. 7 is an exploded perspective view of a filter cigarette including a filter according to a modified example.

8 is a vertical cross-sectional view of the filter cigarette of FIG.

FIG. 9 is a cross-sectional view showing a modified example of the filter material.

FIG. 10 is a cross-sectional view showing another modified filter.

FIG. 11 is a sectional view showing a filter of another modification.

FIG. 12 is a cross-sectional view showing a filter of another modified example.

FIG. 13 is a cross-sectional view showing a filter of another modified example.

FIG. 14 is a sectional view showing a filter of another modification.

[Explanation of symbols]

 2 Cigarette 4 Wrapping paper 6 Filter 8 Filter material 10 Sleeve 12 Space 26 Tip paper piece 28,30 Filter element 32 Additive 34 Filler 36 Aroma generator 42 Air port

Claims (6)

[Claims] 1. A hollow mouthpiece to be connected to a cigarette, a plate-shaped filter material which is disposed in the mouthpiece, and filters the smoke sucked from the cigarette, and the filter material in the mouthpiece. The filter material is obtained by arranging individual fibers in a direction transverse to the flow direction of the inhaled smoke, and is included in the inhalation smoke and the inhaled smoke in the filter material. The filtration rate of fine particle components is 10 to 90 mmH ₂ O
And 5 to 70%, and the fiber diameter is 20
Within the range of μm, the porosity of the filter material is 80-95%
The filter material for cigarette is characterized in that the thickness of the filter material is set within 5 mm in order to ensure the above. 2. The filter for cigarette according to claim 1, wherein the filter material is made of non-woven fabric. 3. The cigarette filter according to claim 1, wherein the filter material has a multi-layer structure, and at least one layer contains an additive in a distributed state. . 4. The mouthpiece that defines the space includes a hollow cylindrical body, and an additive is attached to the inner peripheral surface of the hollow cylindrical body. Filter for cigarette. 5. The cigarette filter according to claim 1, wherein an aroma generating body capable of generating an aroma is contained in the space. 6. The filter for cigarette according to claim 1, wherein the suction port has an air port, and air can be introduced into the space through the air port.