DK141984B - Filter element for a tobacco product, especially for cigarettes. - Google Patents

Description

(11) PUBLICATION 14198 * + nÉn \ pa / DENMARK (6,) lntc | 3 A 24 D 3/04 § (21) Application No. 6598/73 (22) Filed on 27 · n0V. 1973 (23) Race day 27. nov. 1973 (44) The application presented and the petition published on 4 August. 1 98Ο

DIRECTORATE OF

PATENT AND TRADE MARKET (3 °) Priorit ^ 8 den

27. bold. 1973, 336277, US

(71) BRITISH-AMERICAN TOBACCO COMPANY LIMITED, Westminster House 7, Mill- "Hank, London, S.W.1, GB.

(72) Inventor: James Rodney Hammersmith, 1225 Reeds Lane, Jeffersonville,

Indiana, US: Philip Hancock Clogbill II, 846 Rivercrest Court, Apt. 3 ^ · »Louisville, Kentucky, US.

(74) Plenipotentiary in the proceedings:

The company Chas. Hude.

(54) Filter element for a tobacco product, especially for cigarettes.

The invention relates to a filter element for a tobacco product, in particular to cigarettes and of the kind consisting of a relatively rigid tubular casing for tobacco smoke impermeable material, in which is disposed a tobacco pervious filter material and wherein there is at least one axial smoke channel, the walls of which are of impermeable tobacco smoke and whose end, upon application of the filter element to a tobacco strand, will communicate directly with the tobacco therein, while the other end of the channel is spaced from the end surface of the filter material from the tobacco string.

Filter element consisting of a casing containing a filter material is increasingly used for cigarettes, and the efficiency of such filter elements is greater the greater the amount of particulate matter in the tobacco smoke which the filter stops and thereby removes from the smoke. , sucked in by the smoker. It is inevitable that this removal of particles from the tobacco smoke will also reduce its taste, and the more effective a filter is, the more the taste will be reduced.

In addition to the filter element disposed at one end of the cigarette, the tobacco strand itself in the cigarette acts as a filter, as the tobacco smoke also emits some particles when passing through the tobacco string, so that the tobacco smoke is firstly avoided and secondarily reduced in taste. The greatest reduction in the taste of tobacco smoke occurs in the first stages of the cigarette, where the tobacco smoke passes a long length of tobacco plus the filter element, and as the glow approaches this, the filter effect of the tobacco string decreases, while the taste of the tobacco becomes stronger.

Using a very effective filter, the first features of the cigarette will be so slightly tasting that it is said to be a deficiency of the cigarette, and measures have therefore been proposed to remedy this deficiency so that the taste of a cigarette does not vary greatly. too much during smoking.

In Danish Patent Specification No. 128,342, the said defect is remedied by the fact that one or more axial pipes forming smoke channels through which the smoke can pass unobstructed are arranged in the tobacco string.

At the beginning of the cigarette smoking, a large portion of the smoke passes through these channels, thus partially eliminating the filtering effect of the tobacco string, thereby achieving a stronger flavor effect of the first moves. If the glow reaches the mouth of the longest channel, the smoke will generally pass the tobacco strand so that its filtering effect becomes effective. During the further smoking, the wall of the duct is burnt, which e.g. may be of paper.

Since the flue ducts have to be inserted into the tobacco string in the cigarette, it cannot be manufactured in a conventional manner, but special measures must be taken to insert the flue pipes. When burning the smoke ducts, the resulting flavors are mixed with the flavors of the tobacco.

3 141984

From German Patent Specification No. 1,298,029, a filter element is known for cigarettes, in which the filter element contains one or more axial smoke ducts extending from the tobacco string to a location remote from the free end surface of the filter. The purpose of these channels is to produce a variation in the tobacco taste, with a portion of the smoke passing through the filter material and a portion of the smoke passing through the smoke channels simultaneously.

The filter element according to the invention is characterized in that the farthest end of the tobacco strand is closed except for a nozzle-like opening which is substantially smaller than the channel's illumination.

In this embodiment of the filter element, a special and novel effect is obtained, namely that the tobacco smoke immediately after ignition of the cigarette passes the entire tobacco string and then the flue or channels, and finally a limited area of the filter material, so that at the beginning of the smoke the smoke has the same tobacco taste as a cigarette without a filter. However, due to the narrow nozzle-like opening, the filter material immediately around the outlet of the duct will be clogged by particles in the tobacco smoke rather quickly, so that this area provides the tobacco smoke with greater resistance than the rest of the filter material, so the tobacco smoke will then bypass the duct or ducts and become sucked through the filter material.

By appropriate sizing and placement of the flue or flue channels, the ratio can be adjusted such that the tobacco smoke is forced through the filter relatively quickly after the first draws, thereby providing effective protection for the smoker, while also providing the first draws of the cigarette. satisfying taste power.

A filter element according to the invention does not require any particular design of the tobacco string or the part of the cigarette with which the filter is to be connected so that the cigarette can be manufactured in a conventional manner.

Conveniently, the channel may be formed by an axial groove on the surface of the filter casing, which results in a simple manufacturing process.

Variations of the effect of the smoke ducts can be provided by means of several ducts of different lengths, as set forth in claims

According to claim 4, the channel may have diminishing cross-section towards the closed end, thereby also providing a variation option.

In the following, the invention is explained with reference to the drawing, in which 1 is a perspective view of a preferred embodiment of a filter element according to the invention, with a single channel in the periphery; FIG. 2 is a section through a filter element according to FIG. 1, introducing into a smokeless tobacco product; 3 is a section through a filter element according to the invention inserted into a smokeless two-channel tobacco product in the filter, the channels being oddly long; FIG. Fig. 4 is a section through a filter element according to the invention, introduced into a smokeless tobacco product, the channels formed in the filter element having the same length; 5 is a section through a filter element according to the invention introduced into a smokeless tobacco product, the channel formed on the periphery of the filter element being tapered; FIG. 6 is a section through a filter element according to the invention, embedded in a smoking product, wherein the channel is formed within the body of the filter element instead of along the periphery; FIG. 7 is a sectional view taken along line 8-8 of FIG. 6, FIG. Fig. 8 is a diagram showing the milligram amount of the entire particulate substance delivered at each suction by a filter according to the invention and by another filter; 9 is a diagram showing the efficiency of each suction of a cigarette filter according to the invention and another filter; and FIG. 10 is a diagram of the entire amount of particulate matter delivered on the basis of each suction to illustrate the effect of varying aperture size.

The FIG. 1, the filter element 1 shown consists of a high-efficiency filter material 2, which is housed in a rigid plastic casing 3, in which a channel or groove 4 is formed. At the end of this channel or groove 4, an opening 5 is formed. 2 is the filter element 1 shown in FIG. 1, wrapped in a cigarette consisting of a tobacco section 6 and a wrapper 7 which encloses both the tobacco section 6 and the filter element 1. It is noted that in FIG. 2, the open end 8 of the channel 4 abuts the tobacco section, while there is no groove at the end 9 of the nozzle of the smoking tobacco product.

In FIG. 3, a filter element 11 is housed in a smoking tobacco product consisting of a tobacco section 16. Both the filter element 11 and the tobacco section 16 are enclosed by a wrapper 17. The filter element 11 shown in FIG. 3, has a longer channel 12, the open end 13 of which abuts the tobacco section 16, while an opening 14 is found at the opposite end of the channel. A shorter channel 18 is also formed in the filter element. The open end of this channel also abuts the tobacco section while an opening 20 is formed at the opposite end of the channel. Here too, the channel ends shortly before the end of the cigarette mouthpiece.

In FIG. 4, a filter element 21 corresponding to the filter element 11 is shown. The filter element 21 is also inserted together with a tobacco section 26 in a wrapper 27. The two channels 22 and 22 'in the filter element 21 have the open portions 23 and 23' of the channels adjacent. up to the tobacco section 26, while the closed portions of the channels are provided with openings 24, 24 '.

In FIG. 5, the filter element is again connected to a tobacco section 36, 6 U198Å, the two parts being wrapped in a wrapper 37. The filter element 31 has a single channel 32. This channel differs from the channels described with reference to the preceding figures in that it is thus tapered that the largest cross-section of the channel is at the open end 33 adjacent to the tobacco section 36.

The channel is gradually narrowed to the opening 34 located at the closed end of the channel. Here too, the channel ends shortly before the cigarette mouthpiece.

Fig. 6 shows a filter element 51 in combination with a tobacco section 56, the two sections being enclosed in a common wrapper 57. In this filter element 51, a channel 52 is provided within the high-efficiency filter material 53, instead of at the periphery of this material. . The open end of the channel 54 is also adjacent to the tobacco section 56, and an opening 55 is formed at the closed end of the channel.

The filter elements shown on each of the figures are not necessarily drawn to a certain scale, but various possible embodiments of the invention are shown. Generally, the channels are shown with a length that is approximately 80% of the entire filter element length. Generally, the duct or ducts should have a length of 50-85% of the length of the filter element. In each case, the sizes of the channels and openings for clarity are shown to be larger than they really are. The parameters for the different lengths and sizes should be given in more detail below.

In the design of a suitable filter of the type described herein, several factors are of particular importance. The overall efficiency of this filter type is determined for a large part of the particular filter element type selected for the main body of the filter.

Thus, the usually important parameters are the bladder type, the weight of the string, the circumference and the fiber distribution.

In the filter according to the invention, further important factors are: the size of the opening at the end of the channel, the non-porous walls which conduct the channel, and the initial relationship between the resistance of the flow of smoke through the channel and the opening in comparison with the original resistance through the main body of the filter element.

U1984 7

Also important is the shape and placement of the opening, the compression of the tow, the dimensions of the channel and the orientation of the fibers in the main filter element, in particular the portion adjacent to the opening.

The initial resistance ratio of the filter according to the invention is defined as the pressure loss of the main filter section divided by the pressure loss through the shortened flow path, which consists of the channel, opening and short section of the filter element. These values are obtained independently at an air flow of 17.5 cm / sec. The percentages of the initial suction flowing through the duct or groove and aperture compared to the flow through the main filter section at varying resistance conditions are given in Table 1.

Table 1

Initial resistance ratio compared to pipe flow% suction volume through

Ratio groove opening Main filter element 0.1 10 90 0.5 33 67 1.0 50 50 3.0 75 25 5.0 83 17 In general, the filter according to the invention, regardless of the main filter element used, with the greatest resistance ratio will give the lowest initial efficiency and the greatest increase. of the efficiency of subsequent suction. The initial resistance ratios desired in the filters of the invention are from 0.5 to 5.0, preferably 1.0-3.0. When the initial resistance ratio is below 0.5, the desired power cannot be obtained. At a resistance ratio greater than 5.0, there are problems with the opening, which is too large to be effectively blocked by the initial suction, or problems with blockages which are interrupted by the subsequent suction. At the preferred size of 1-3, the initial resistance through the groove opening in a short filter section is evidently equal to or less than the resistance through the main filter element. Accordingly, from 50 to 75% of the smoke during the first suction will pass through the groove opening with the lower efficiency. As this road is gradually blocked, more and more of the smoke will pass through the main filter section. In general, the resistance through the groove opening at the fourth or fifth suction is greater than the resistance through the main filter element, so that most of the smoke passes through the main filter element. Usually, the opening at the last suction is almost completely blocked, and in essence the entire amount of smoke will pass through the main filter element.

The effect of these conditions can be seen in FIG. 8 and 9. In FIG. 8 is the entire delivery of the particulate matter per minute. suction shown, both for a standard cellulose acetate filter and for a filter according to the invention. It is seen that the milligrams delivered per suction, in fact, is the same for the first and ninth suction of the filter according to the invention, while the delivery of the particulate substance by the normal cellulose acetate filter per suction has more than doubled within this range of suction. The reason why there is an equalization of the delivered amount of tar per tonne. suction, shown in fig. 9, showing the efficiency of the filter for each suction. As can be seen, the efficiency of the standard cellulose acetate filter changes very little between the first and the ninth suction, while the efficiency of the filter of the invention grows from approx. 40 to 60% during the same smoking period.

The optimum size for the formed opening at the end of the channel, when using a single channel and opening, is from 12 to 30 Birmingham or Stubs measuring units. Preferably, the size of the aperture in such a filter element is from 12 to 21 Birmingham or Stubs measuring units. The size of the channel leading to the hole should be from approx. 1 to 3 mm in diameter, although the channel size is expressed at a diameter, it is the critical cross-sectional area and not its configuration or diameter.

The area of the duct should not be too large, as otherwise the area of the main body of the filter material may be too small.

The length of the channel is not critical. It is chosen so that the relative resistance between the main body of the filter material and the channel, aperture and the short section of the filter material is within the size ranges specified above.

U1984 9

Some compression is necessary to ensure an accumulation of the particulate material in the portion of the filter material adjacent to the opening at the end of the channel. The particular speed required for this is obtained precisely by dimensioning the duct and opening as indicated above.

When more than one δη channel with one aperture is used, e.g. shown in FIG. 3 and 4, the total area of the apertures should conveniently be slightly larger than the area of the aperture at only one channel to achieve the same result. Since the accumulation of the particulate material around the aperture of the filter material generally assumes a substantially hemispherical configuration, more particulate matter is required to block one aperture than of several apertures of the same area. Therefore, the overall size of multiple apertures is increased compared to the individual aperture, so that substantially the same amount of particulate matter is required to block multiple apertures required by a single aperture and the same programming type is obtained. With a plurality of openings, e.g. shown in FIG. 3, where the channels are of unequal length, one channel, e.g. channel 12, be the channel through which the smoke flows during the first few sucks of the cigarette, after which the flow of smoke can change to the second channel, such as channel 18, and finally through the main body of the filter material. Of course, even if only two channels are shown in FIG.

3, also apply a different number.

The effect of varying aperture sizes within the specified range is shown in FIG. 10. With the same filter element material used in each case, the total delivery of particulate matter in milligrams per minute. suction depicted as a function of the number of suction from 1 to 9. It is seen that as the aperture size becomes smaller, there is a greater smoothing of the delivery of the particulate matter per minute. suck while other factors are unchanged. Again, the smoothing of the delivery of the particulate substance is clearly seen in comparison with a control filter.

If desired, in most of the embodiments shown, each channel or one or more of the channels shown in FIG. 3 and 4 are filled or partially filled with a substance to obtain a particular result. Eg. For example, a flavoring agent may be placed in the channel to flavor the first suction of the smoke. When such a substance is contained in the duct, it must be of such a type and in such quantity that the effect of the filter in question is not lost.

The main filter element, such as that shown by reference numeral 2 in FIG. 1, can be formed from various filter materials. P.eks. it can be formed from paper or cellulose acetate. It is generally chosen because of its filtration efficiency, and with a filter element according to the invention, the filtration efficiency of the particulate matter should be at least approx. 50%.

As shown in FIG. 1, the main body of the filter material is surrounded by a plastic sleeve in which the duct is formed. The opening is formed at the end of the duct and extends through the sleeve. The plastic sleeve has a dual function: 1. It prevents crushing of the filter which would damage the duct.

2. It makes the walls of the channel impermeable so that the filtering does not occur through these walls.

The plastic sleeve does not constitute a critical feature of the invention as long as it is capable of performing said two functions. Thus, e.g. after forming the channel in the filter material, the periphery of this material is provided with such coating to ensure the necessary closure and increase the mechanical strength.

Depending on the particular filter material used, heat sealing can also be used.

Table 2 shows the effects of the various parameters discussed above when using the filter of the invention.

The various parameters are indicated and the effect of increasing each of these parameters is indicated in terms of the initial filter pressure loss, the initial filter efficiency, the amount of initial flow through the channel and the opening, the final filter pressure loss and the final filter efficiency. An increase in each of these measured effects is shown as "+", a decrease as and no change as "0".

11 141S δ Λ

In order that the person skilled in the art can better practice the invention, the following examples are given.

Examples 1-3 In these examples, the filter element was formed from cellulose acetate fibers having a denier of 1.6 per cent. fiber and 24,000 denier per filter and with an injected secondary shrinkage. Three filter elements were made with aperture sizes of 19, 17 and 15 Stubs units or diameters of 1.1, 1.5 and 1.8 mm, respectively. The total deliveries of the particulate matter in mg per ml. cigarette, the initial pressure drop in mm of water column, the initial resistance and the filter efficiency are shown in Table 3. It is seen that with each of these filters there is a marked increase in the filter's efficiency from the first suction to the last suction.

Example 4 In this example, the cellulose acetate filter element had 1.6 denier per fiber and 48,000 denier in total. The aperture diameter was 1.8 mm or 15 Stubs measuring units. The total delivery of particulate matter was 12.2 mg per day. cigarette, and the original pressure loss in mm of water column was 94. The initial resistance ratio was 23 mm. The cigarette showed a filter efficiency of 50% overall with an initial efficiency of 34% and a final efficiency of 65%.

Example 5 In this example, a 2.5 denier cellulose acetate filter element was used. fiber and a total denier of 44,000. The diameter of the opening was 1.8 mm or 15 Stubs units of measurement. The total delivery of the particulate material for the cigarettes was 17.6 mg. The initial pressure drop was 56 mm water column and the initial resistance ratio was 35 mm. The cigarette showed a total efficiency of 31% consisting of an initial efficiency of 16% and a final efficiency of 47%.

12 141984

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