NO126770B - - Google Patents

Description

Smoke mixture.

The invention relates to a smoking mixture which is characterized in that it consists of tobacco and a solid polysiloxane with a molecular weight higher than 100,000 which contains mixed in from 50 to 300 parts of filler per 100 parts polysiloxane, the filler being selected from the group consisting of hydrates and carbonates, including bicarbonates, which are endothermic dissociable to release water or carbon dioxide at a temperature lower than approx. 350°c.

It is generally assumed that the carcinogens in the smoke produced by burning tobacco are primarily found among the polynuclear aromatic hydrocarbons (PAH), of which benz[a]pyrene and benz[a]-anthracene are particularly well-known examples. PAHs are developed by destructive distillation of more complicated chemical compounds in the burning tobacco. The amount of PAH that is formed increases with the tobacco's combustion temperature.

The cigarette filters currently on the market aim to reduce the risk of carcinogenic material from cigarettes. However, due to the material used in these filters, their location in relation to the tobacco and other factors, they serve primarily to condense moisture and some of the water-soluble materials in the smoke, and by compression to deposit a small coat -sion of the colloidal particles that appear when the smoke moves from the combustion zone in the burning tobacco, is cooled by

they are passed through the descending layer of tobacco.

PAH is produced as a molecular dispersion, but on grounds

due to their low vapor pressure, they tend to be adsorbed and condensed on all surfaces with which they come into contact, including unburnt tobacco leaves, cigarette paper or colloidal particles that occur in the smoke. The PAHs that are recondensed on unburned tobacco or paper later will be volatilized again when they are heated and burned, while the PAHs that are captured by adsorption and condensation on colloidal

smoke particles, will be carried with them through the cigarette and follow them to their final destination, whether it concerns

ing by compression on a cigarette filter or the deepest regions of the smoker's lung. Filtering techniques used today are relatively ineffective for removing PAH either in vapor form or by capture using colloidal particles that do not compress the filter.

Carbon black and granulated charcoal in their various forms

have been used in the filter part of cigarettes, but these materials suffer from the disadvantage that they are far more active towards polar materials, e.g. nicotine, than to PAH, and they can therefore, even if PAH is adsorbed on these surfaces, later be developed again in the gas phase by preferential adsorption of nicotine. Furthermore, the effectiveness of any surface in the filter tip of a conventional cigarette is fundamentally limited by the well-known principles of compression of colloidal particles.

It would be highly desirable to provide an aid to remove or substantially reduce the amount of PAH in tobacco smoke, especially in the case of aids that could be incorporated

easily in cigarettes, cigars or pipe tobacco. Furthermore, it would be desirable that the aids for removing PAH were selective, so that

the physiologically satisfactory material is retained in the tobacco smoke. Contrary to what is known from the prior art, the invention enables the capture of PAH after release from burning tobacco in predominantly molecular forms by absorption on materials with high solubility for PAH and with negligible or low solubility for the polar components, e.g. nicotine and other alkaloids.

In the smoke mixture according to the invention, a new method is used for the removal or significant reduction of PAH in tobacco smoke. A particulate polysiloxane absorbent capable of absorbing PAH is mixed with tobacco and/or used in a filter aid. which is located near the burning tobacco. The temperature of the absorbent surface is kept significantly lower

than nearby burning tobacco during the absorption of PAH to prevent desorption of PAH, by effecting an endothermic chemical reaction or desorption of the filler material in the particles to release a physiologically harmless by-product, namely -carbon dioxide or water. <p>olysiloxane itself does not break down at the temperature that occurs when the tobacco is burned. PAHs, e.g. benz [ajpyrene, absorbed,

and when absorbed, they are so greatly diluted by solubilization of the polymer that subsequent reheating while the combustion zone passes the material does not mean appreciable desorption thereof.

When the polysiloxane preparation is incorporated into the tobacco,

it is removed with the ash from the burning tobacco so that the carcino-

genic compounds, instead of progressively accumulating in ever-higher concentrations by condensation on still unburnt tobacco, are mostly removed as the ash is flicked off, leaving behind a smoke mixture which is physiologically satisfactory due to its nicotine content, but which has a significantly reduced concentration of

PAH.

Due to the above factors, it will be understood that while the smoke mixture passes through a conventional cigarette filter, a certain amount of PAH may still be in molecular form and therefore susceptible to capture by absorption, in contrast to colloidal particles which are susceptible to capture primarily by compression. or electrostatic mechanisms rather than diffusion. In order therefore to make the cigarette, cigar or other product of this form even safer, it is preferable to replace the conventional filter with,

or to add to the conventional filter, an extension which

contains PAH-absorbing polymer in finely divided form with a high surface area, e.g. fibrous polysiloxane rubber. In the polysiloxane preparation in the filter, no material capable of undergoing an endothermic reaction needs to be present, since the low surface temperature, which is satisfactory for substantially reducing desorption, is maintained by virtue of its distance from the combustion zone. However, it is preferred that the primary site of capture of PAH and similar carcinogens is the absorbent materials mixed with the tobacco layers.

A more detailed description of the invention is given with reference to the attached drawings and the following discussion: Figure 1 is a cross-sectional view of a cigarette, where the tobacco part contains the polysiloxane preparation used according to the invention.

Figure 2 is a cross-sectional view of the cigarette from Figure 1

which additionally has a filter containing a polysiloxane.

Figure 3 is an axial cross-sectional view of a cigar, and Figure 3a is a transverse cross-section at 3a-3a of Figure 3. Figure 4 is a plan view showing a perforated polysiloxane film and a tobacco leaf being layered together. Figure 5 is a longitudinal and Figure 5a a transverse cross-section of the filter part of a cigarette.

Referring to figure 1, 1 represents the solid residue, or ash, from the combustion of the tobacco 4, 3 is the filter, or the cigarette end held in the smoker's mouth, 4 flake tobacco, stringy leaves or another conventional form of tobacco, and 5 is the absorbent in flake, fiber or other particle form. As the central plane of the combustion zone moves from position mm to position nn in figure 1, the developed PAHs are absorbed by means of immediately nearby absorbing particles 5, while carbon dioxide, water and the more polar material such as e.g. nicotine passes through the cigarette. The ash 1 is snapped off from the cigar or cigarette from time to time and thereby brings with it the polysiloxane that has absorbed the PAH.

With reference to Figure 2, the tobacco/absorbent mixture 2 is followed by a conventional filter 3, which removes the main part of the aqueous condensate, and an extension 7 which comprises finely divided silicone polymer 8, which e.g. in a fibrous configuration, which does not necessarily contain any filler component, which serves to absorb the now very low content of PAH and other lipophilic molecules which may have escaped before absorption in the absorbent/tobacco mixture 2. With reference to Figure 3, a cigar is formed by wrapping spirally alternating layers of tobacco leaf 9 and of sheet-shaped polysiloxane material 10. The sheet-shaped polysiloxane material is produced in thicknesses comparable to the thickness of tobacco leaves that are cut into or perforated to form narrow bands 11 (approximately 6 mm wide) which are held together by a limited number of connection points 12.

When the cigar from Figure 3 is shaped, the polysiloxane material with absorbed PAH 10 becomes part of the non-combustible ash and is removed by knocking the ash off the cigar.

Referring to Figure 4, the main axis of the cigar is

shown in relation to the tobacco leaf and to the perforated or scored polysiloxane sheet material, before spiral wrapping. It will be understood that, depending on the leaf quality, the thickness of the leaf, the thickness of the polysiloxane material, etc., the layered division with one leaf and one polysiloxane sheet shown in Figures 3 and 4 is only one embodiment, and that two or more leaves of tobacco may rolled, together with one sheet of the polysiloxane material.

Referring to Figure 5, which shows the cross-section of a cigarette cut along the main axis, silicone absorbent is in the form of parallel lengths of tube-shaped material, 13, of small diameters assembled as one bundle containing 20 or more individual tubes, of which the end section is shown, corresponding to section 5a-5a from the side section. Conventional stringy cigarette-grade tobacco 14 is packed behind the filter section 15 and is wrapped together with the filter section by means of a regular cigarette paper.

The polysiloxanes used in the smoke mixture according to the invention have satisfactory thermal stability to undergo negligible or no degradation at temperatures encountered in the combustion of tobacco when proper amounts of filler are used, to be specified below. While high molecular weight linear siloxanes can be used without cross-linking, e.g. with rubber raw material, it is generally more satisfactory to cross-link the polymer to make it rubbery and more stable to thermal degradation, as well as non-flow with respect to mixed flake tobacco. Cross-linking actually forms a polymeric network of undetermined molecular weight and 0 vapor pressure which can be destroyed only by cleavage of the silicon-oxygen skeleton and oxidation of the side groups. The conventional low molecular weight silicone diapers are not useful for this invention as they volatilize too easily under the combustion conditions of the tobacco, and furthermore they are not as convenient to mix with the fillers used in the invention as the silicone polymers discussed below, which afterwards can be cross-linked.

Among the polymers that can be used in the absorbent material to be mixed with the tobacco are polydimethylsiloxane, polycophenylmethyldimethylsiloxane, polycovinylmethylphenylmethyldimethylsiloxane and the classes of these polymers which are conventionally terminated with silanol groups or polymers of the RTV class which are produced with acetoxy termination for the purpose of cross-linking by hydrolysis of the acetate groups and subsequent cross-linking of the silanol groups developed by hydrolysis: provided that it is in its final state, the polymer may have a high molecular weight, it may exceed 100,000, or it may preferably be cross-linked .

The surface temperature of the polysiloxane is controlled during combustion by incorporating an endothermic reactive filler into the polysiloxane. The filler is dispersed through the polymer, but the permeability of the polymer to water vapor is such that the reaction products easily diffuse through the absorbent to its surface. The filler absorbs heat from the surface due to the endothermic reaction or endothermic evolution of vaporous material. Furthermore, as the vapors generated from the filler pass through the particle surface, they absorb heat from the surface. In this way, the surface temperature of the absorbent particles is kept sufficiently low to prevent substantial desorption of the PAH. Among the fillers that can be used are those capable of releasing water vapor, carbon dioxide, or both endothermicly, regardless of whether the vapor is evolved or produced by chemical reaction or physical desorption.

The preferred fillers are such as per grams absorb most heat from the surrounding combustion zone while releasing the harmless gaseous product at a temperature low enough to prevent destruction of the polysiloxane absorbent. On

at the same time, the filler must not decompose spontaneously under storage conditions for the tobacco product before use.

Preferred fillers are given in table 1, which also provides information on the type of vapor developed, the endothermic heat in cal/gram of filler and the approximate temperature at which the endothermic heat absorption occurs.

Any of the fillers mentioned above can

milled into polydimethylsiloxane silicone rubber raw material on a cool mill without appreciable loss of water from other gaseous product,

and the silicone rubber can then be cross-linked at essentially room temperature by means of ionizing radiation. The cured material has only the endothermic filler and no toxic components such as are found in products cured with free radical initiators. Alternatively, gypsum or Glauber's salt or porous, water-containing material can be easily mixed with RTV silicone and allowed to cure at room temperature by hydrolysis of terminal acetoxy groups, or otherwise using negligible amounts of water in accordance with the type of RTV silicone used. When sodium bicarbonate is to be used for the evolution of carbon dioxide and water, it is impractical to use the acidic RTV rubbers containing acetoxy end groups, due to partial conversion of the sodium bicarbonate to sodium acetate. On the other hand, it is entirely practical and indeed desirable to mix the bicarbonate with pure silicone rubber raw material, especially pure polydimethylsiloxane and then to effect cross-linking by means of ionizing radiation, such as i eri Van der Graaf generator. It should be understood that mechanical strength is irrelevant to the properties of silicone absorbent material.

the ale that is mixed with the tobacco. Thus, it is not necessary to use "fume" type silica filler or other inert fillers commonly used for reinforcement, but these inert fillers, if present in the silicone rubber raw material, will not interfere with the action of the decomposing fillers which is discussed above.

The filler is used to maintain the temperature of the silicone polymer absorbent below its decomposition point and at the same time to allow more efficient absorption of the PAH molecules released from the tobacco, since PAHs are more soluble in the polymer the lower the temperature.

The temperature of the tobacco in the combustion zone of a cigarette can exceed 800°c, depending on the moisture content, the tightness of the pack, the speed of the smoking, etc. Thus, the quantity is regulated

the and type of filler in each polymer particle and the concentration of polymer particles in the tobacco to achieve the desired results indicated above, in relation to the moisture content of the tobacco and to the density. At least 50 dhg (parts filler per 100 parts rubber)

must be used, while 100 dhg to 150 dhg is preferred. The maximum amount of filler that can be incorporated depends on a wide range of factors,

e.g. the density of the filler, the asymmetry of the particles, the particle size distribution, the particle porosity and other factors, and the practical upper limit can be as high as 300 dhg. This can easily be ensured by carefully calculating these factors for each filler material. Small amounts of a filler can be exposed directly to the particle surface, but it should not be so much that it adversely affects the absorbent capacity of the particles or allows extremely high surface temperatures. At the same time, the filler particles must be satisfactorily close to the surface' (within a distance of less than 10 microns) so that upon cleavage they will maintain the surface at the desired temperature, and due to their distribution through the mass, will at the same time hold the mass essentially isothermal.

The physical form and shape of the silicone absorbent

which is to be mixed with the tobacco, is not critical, provided that the maximum ratio between surface and volume associated with practical mixing with the tobacco is realized. In general, the thickness of the absorbent should be comparable to the thickness of the tobacco flake or leaf used. The absorbent can take shape

of discontinuous flake as in Figures 1 and 2 or as a continuous band as in Figure 5, or in any other form, provided that the ash and spent absorbent after the combustion of the tobacco can be easily snapped off together, and provided that the absorbent material can be disposed of so in relation to the tobacco that local "hot" spots are avoided.

When the silicone polymer is crosslinked by thermal decomposition of a free radical initiator, e.g. dichlorobenzoyl peroxide, it is necessary to remove the potentially harmful by-products which result from the cross-linking step and which can escape upon subsequent heating of the silicone rubber, e.g. phenyl benzoate. This can be implemented e.g. by extraction with acetone and acetone/ether mixtures. For this reason, the RTV-acetoxy terminated siloxanes are preferred

and dimethyl silicone rubber raw materials that have been hardened by ionizing radiation (X-ray, Van der Graaf, cobalt 60, etc), as no molecular fragments remain after the cross-linking that can escape during the subsequent heating in the combustion zone tallow burning cigarette, cigar or pipe tobacco.

When the silicone absorbent is mixed with the tobacco, is

there are no restrictions with regard to the weight ratio between absorbent and tobacco, with the exception that the upper limit cannot exceed 6, as otherwise it would be difficult to propagate the combustion front and thus keep the tobacco on fire. Up to this ratio, increased absorption is achieved with increased concentration of the absorbent. Therefore, for maximum protection, it is preferred to use at least 60 parts absorbent to 40 parts tobacco. The weight of the tobacco is measured after equilibrium has settled below 1 atm. pressure, at 60± 2% relative humidity, at 22<±> 2°c. This can be achieved by placing a mixture containing 74 parts by volume of glycerol and 26 parts by volume of water or other desiccant in a suitably covered desiccator.

It is obvious from what has been mentioned above that the mixture with silicone rubber absorbent will result in a significantly lower average combustion zone temperature than would occur if the same quality tobacco at the same relative humidity was used without mixing the absorbent. The presence of the absorbent reduces the total effective combustion area in the combustion zone in relation to the amount of air drawn through the cigarette, which thus leads to a much higher ratio between oxygen and fuel than is required stoichiometrically. This in itself has the well-known effect of reducing the temperature in the combustion zone in a way that can be calculated, and in addition lowers the low but limited content of carbon monoxide found in the smoke mixture from burning tobacco. It is well known that carbon monoxide represents a particular health hazard. Moreover, for-

reduces the release of water or carbon dioxide or other harmless gaseous element from the filler contained in the silicone absorbent, latent heat of dewatering or heat of vaporization or heat of desorption and thereby reduces the temperature in the combustion

the zone further. Consequently, the production of PAHs is significantly reduced,

and taking into account the extensive absorptive area which is immediately adjacent to the production zone of the total PAHs that pass from the tobacco mixture into the cigarette filter, this production is reduced to a significant extent compared to a cigarette without an absorbent.

As an alternative embodiment in the filter section 3 on

Figure 1 or Figure 2, the cleansing absorbent in section 8 may be of any inert lipophilic polymer, including butyl rubber, butadiene rubber, ethylene-propylene copolymer, etc. Among the various polymers that can be used, the silicone polymers are far preferable, as they have a very high capacity against PAH. However, since the cigarette filter will never have a temperature that exceeds

rises 50°C, the exceptional heat resistance of the silicones is not specifically required in the filter section 8.

From the foregoing description it will be understood that there is no practical limit to the length of the lipophilic filter in section 8. In fact, it could be greater than half the length of the entire cigarette. It will also be understood that a cigarette that be-

consists of a filter composed of silicone polymers extending over 80% of the cigarette, would be of great value for the removal of substantially all PAHs from the small amount of tobacco contained in such a cigarette, which constitutes 20% of its total length. In this case, the length of the tobacco that can be burned is so short and the distance from the combustion zone to the nearest silicone surface so short that most of the effects achieved by the incorporation of silicone absorbent could be achieved in a cigarette with a ratio of 80 to 20 between filter and tobacco section. It will be understood that in such a cigarette, as the combustion zone could approach and come into contact with the filter media, it would be mandatory to have silicone polymers with high heat resistance in the classes specified above, and

which contains some gas-releasing filler to prevent overheating of the end closest to the tobacco.

It will therefore be understood that the invention includes the use of silicone polymers either in admixture with gas-releasing, temperature-moderating fillers, as absorbent for a cigarette, and preferably for maximum removal of PAH from the gas mixture inhaled by the smoker. The cigarette consists of a mixture of tobacco with a silicone absorbent in the combustion section and in addition a filter section containing a lipophilic polymer, preferably silicone, to absorb remaining traces of PAH.

The following examples illustrate the invention and should not limit it.

Example I

The following mixture is prepared in a laboratory type Brabender mixer or on a laboratory rubber mill (cold rolls) until a uniform color is obtained:

This raw material is extruded through a laboratory extruder having a nozzle with 100 holes of diameter 0.5 mm, there being a continuous light dusting of sodium bicarbonate powder on the 100 protruding filaments to prevent blocking. The filaments are easily twisted into a cord. , and the string is coiled loosely in piles of approx. 10 cm height. The coils are then transferred to a Van der Graaf or similar generator with ionizing radiation and exposed to a dose of approx.

10 megarad, whereby the silicone polymer is effectively cross-linked.

The final preparation consists in pulling the hardened

string through a water bath to remove bicarbonate from the surface, after which it is dried in hot air at high speed (maximum 49°c) and passed continuously through a "flying" knife chopper which creates bundles a,v not exceeding 5 mm in length. The bundles are guided between tightly adjusted, knotted rollers, of which the upper one runs 10% faster than the lower one at

approx. 100 rpm, fixed to a clearance of approx. 1.3 mm measured with feeler template.

This causes separation of the individual filaments in the bundles

and randomizes them. The randomized chopped filament is mixed with stringy cigarette tobacco (pre-conditioned at 60%

RF at 22°C over 74% glycerol and 26% water), in a weight ratio of 2 parts filament to 1 part tobacco, and packed in cigarette paper for forming cigarettes.

Example II

100 grams of Dow Corning "Silastic" RTV-732, a semi-

liquid, mixed with 140 grams of finely ground Epsom salt in a Brabender

laboratory-type mixer and 1 gram of red iron oxide (to give a color indication that the mixture is intimate).

The <p>asta is extruded after mixing through the laboratory extruder described in Example 1, and the exiting filaments are showered with a fine mist of water to accelerate surface hydrolysis and gelation. Filaments so moistened are stored in chambers maintained at 95% RH at 25°C for 48 hours, and then air-dried at

41°c for 2 hours.

This filament material is then chopped as in example 1

and mixed with cigarette tobacco, pre-conditioned at 22°c over 74% glycerol, in a weight ratio of 3 to 1.

Example III

Silicone rubber feedstock W 96 from Union Carbide, predominantly polydimethylsiloxane free of any peroxide catalyst, is diluted with diethyl ether to form a solution containing 15% polymer. Finely powdered sodium metasilicate nonahydrate (1.4 gram/gram dry gum), ground activated charcoal (0.02 gram/gram dry gum) and red iron oxide (0.04 gram/gram dry gum) are added to this under effective mixing. When a uniform red-brown color has been obtained, the paste is broken with a knife on a polished stainless steel belt that passes through a solvent recovery chamber, where the ether is developed by infra-red heating to a surface temperature of 49°C. The knife is adjusted so that a sheet is produced which, after ether development, is 0.38 mm thick.

This sheet is due to its high filler content

relatively non-blocking. It is loosely folded in layers, up to 50 in depth. The layered material is transferred to a Van der Graaf generator and irradiated with 10 megarads, whereby it hardens. The

folded, sheet-like material is then unfolded again and passed under a rotating perforator where it is split up into almost non-contiguous strips of width 4.8 mm connected at 12.7 mm intervals at an uncut length of approx. 0.6 mm.

This cleaved sheet material is wrapped together with whole tobacco leaves in a ratio of 1:1 to form cigars, where the nearly separated bands of absorbent lie at right angles to the axis of the cigar.

Example IV

100 grams of Dow Corning "Silastic" of medical grade

and 110 grams of finely ground artinite are mixed together into a base mass on a cold laboratory mill. This is then fed to a miniature tube extruder where it is extruded in the form of a tube with an external diameter of 1.3 mm and an internal diameter of 0.8 mm. Depending on the shape of the die in the extruder, it may be necessary to add up to 10 dhg of a volatile plasticizer, e.g. dimethoxyflurane, to prevent too much heat from building up. Partial curing is carried out by continuous passing through a Van der Graaf generator where it receives a dose of 1.5 megarads. The partially cured hose is then rolled up into coils, which are exposed to a final radiation dose of 10 megarads.

The snake-shaped material collected in round bundles of 36, held in place by bands of cigarette paper, is cut into lengths of 1 cm. 7 of these bundles are placed in a row, but without being aligned one after the other, so that they form an absorbent section with a length of 7 cm, instead of the conventional filter. After the absorbent section comes a tobacco section which is 1.5 cm in length. The tobacco and the silicone absorbent are wrapped in a regular cigarette paper.

From the preceding description, it will be seen that the absorption capacity of polysiloxanes with regard to PAH can be used to remove PAH from tobacco smoke. The polysiloxane can be placed in the tobacco mixture or in the smoke stream, but should be such that it maintains a relatively low maximum temperature in order to reduce the regeneration of PAH vapors to a minimum. Siloxane polymers located close to the burning tobacco in the combustion zone may include endothermic fillers that develop physiologically harmless vapors, e.g. water or carbon dioxide, or they may be present in relatively high proportions to keep the temperature in the combustion zone down and reduce the regeneration of previously absorbed PAH to a minimum.

In particular, the purpose of the prescriptions for tobacco and silicone is to present the silicone in such a form and such a device that it has an absorbing effect on PAH from the smoke and prevents subsequent desorption of PAH. The maintenance of low temperatures in the silicone polymers is important and is provided by incorporating endothermic fillers or by the presence of relatively large proportions of silicone in the combustion zone. In each case, the purpose is to present the siloxane in absorptive affinity to the tobacco smoke and to prevent subsequent overheating which would act to regenerate already absorbed PAH. When the silicone polymer is mixed with the tobacco, low temperatures can be maintained by the presence of relatively large amounts of silicone or by incorporating large amounts of physiologically harmless absorbent fillers into the siloxane polymer. When

the "filler" is located in the downflow at the filler, in the smoke stream, but is not consumed, lipophilic solids other than silicone are also effective in removing PAHs.

Claims (3)

1. Smoking mixture, characterized in that it consists of tobacco and a solid polysiloxane with a molecular weight higher than 100,000 which contains mixed in from 50 to 300 parts of filler per 100 parts polysiloxane, the filler being selected from the group consisting of hydrates and carbonates, including bicarbonates, which are endothermally dissociable to release water or carbon dioxide at a temperature lower than approx. 350°C. 2. Smoking mixture as stated in claim 1, characterized in that the polysiloxane constitutes between 0.5 and 3.0 times the weight of the tobacco. 3. Smoke mixture as stated in claim 1, characterized in that the filler constitutes from 0.5 to 0.8 times the weight of the polysiloxane mixture.