FI68952B - FOER CYLINDER FOER TILLVERKNING AV EN FILTRERANDE STRUCTURE SAERSKILT FOR CIGARETTE FILTER - Google Patents

Description

68952

A method of making a filter structure specifically for cigarette filters

The invention relates to a method by means of which an isotropic filter structure can be produced from a pulp consisting of a homogeneous mixture of different types of fibers, and one of these types of fibers is necessarily heat-meltable synthetic fibers, i. according to the prior art, fibers obtained from thermoplastic polymers, for example polyethylene, one property of which has a relatively low melting point, and the other type of fibers are fibers which are stable at the melting temperature of the heat-meltable fibers.

The pulp can be formed either in the form of a slab to filter solid or liquid particles in an aerosol of smoke or dust suspended in contaminated air, or in the shape of a cylindrical stump from which the cigarette filters are then formed.

A method is already known for preparing filter fillings which can be used, for example, for filtering cigarettes made of fibrous pulps such as bleached chemical wood pulp fibers or pump wadding, which are combined with a bonding liquid impregnating agent or a solid heat-sealing binder either powder or fiber. in a form added to the cellulosic fiber before or after forming into a cylindrical bundle.

In the case where the binder is a heat-sealable solid and is composed in particular of fibers, the filterable mass formed into a cylindrical plug is heated to a temperature corresponding to the softening temperature range of the binder, to its complete melting temperature, so that its adhesion properties can be exploited. and creating multiple connecting regions at the intersections of the cellulosic fibers. These interconnections of the fibers in the heat within the pulp reinforce the filterable structure after cooling so that it is possible to obtain a cigarette filter that is sufficiently dense.

A method is also known for producing a cigarette filter made of very small diameter fibers dispersed among a number of fibers having a much larger diameter and relatively much more. At least one other type of fiber is heat sensitive so that heating is required to activate the binder formed by said fibers, resulting in the adhesion of all the fibers to each other at their intersections.

Although these different methods provide filters that are very tight due to the gluing of the different types of fibers used after the fiber mass has been cooled after heating, it is not possible to make the resulting structure sufficiently permeable to air and smoke because no porous network is formed.

Indeed, these methods provide a tight filter head that is too permeable to air and smoke, making it difficult for a smoker to inhale breaths. In addition, the filtration capacity of the harmful substances in tobacco is insufficient due to the fact that several fibers have adhered to each other, which reduces their contact area with the smoke.

The present invention eliminates these drawbacks and relates to a method for obtaining a filter structure, especially for cigarette filters, which is dense, permeable and absorbent and consists of a homogeneous mixture of fibrous material with at least two different types of fibers, one of which is necessarily heat-meltable. synthetic fibers.

More particularly, the invention relates to a method of making a filter structure, especially for cigarette filters, from a fibrous pulp, comprising forming a homogeneous mixture of different types of fibers, one fiber type being synthetic and low melting point and the other and stable at the melting temperature of the heat-meltable fibers, and said fiber mixture is formed into a cylindrical rod which is not yet in a cohesive state but is in a homogeneous state and includes fiber webs that are tightly overlapping with each other.

The process according to the invention is mainly characterized in that a considerable proportion of heat-meltable fibers are used compared to absorbent fibers, which are elongated in shape, that the rod-shaped mixture is heated to a temperature at which the absorbent fibers remain unchanged but high enough to melt and flow. originally in the form of elongate fibers and to convert it into small droplets dispersed in a network of absorbent fibers so that this change creates, on the one hand, and are formed from void spaces when the fusible fibers are completely melted.

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The fiber mixture is initially distributed evenly in a cylindrical groove.

When formed in this way, it is not yet cohesive and undergoes intensive heat treatment, where it is possible to melt the heat-melting fibers very quickly and completely convert them into small adhesive droplets that weld absorbent fibers that remain intact, adhere to each other and create a network of pores.

The originality of the method according to the invention is mainly in that it is completely destroyed by melting the fibrous form of the network of synthetic fibers. Utilizing the melting and sizing properties of these fibers in heat, the desired filter structure is formed, which is excellent in its cohesiveness, tightness, and permeability.

Once cooled, the structure is cohesive and tight due to the multiple joints formed by the droplets of solidified fusible material located at the intersections of the undamaged absorbable fibers.

Moreover, the structure is permeable due to the formation of a network of pores in contact with each other. These pores are formed in those voids where the fibrous shape of the heat-meltable fibers has disappeared and are evenly distributed in this new structure. This structure is thus created at the expense of the surface area of the heat-meltable material, as a result of which the useful specific surface area of the absorbent fibers is increased and a high filtration efficiency is achieved.

Polyolefin fibers, especially polyethylene fibers having a relative melting point between 115 and 135 ° C, can be preferably selected as heat-meltable fibers.

Of the fibers of this quality, high density fibrillated polyethylene fibers are particularly preferred. These are fibers whose dimensions are very close to the dimension of cellulose. They are formed from well-fibrillated and high-fiber bundles with a very irregular and very fluffy surface and a large specific surface. They have lengths of 1-2 mm and a diameter of 2-25 μm. It is precisely because of this special morphology that excellent mixing with cellulosic fibers takes place; it also results in a fully melted fine pore structure of the polyethylene, i.e. which contains a very large amount of micropores due to the initial abundance of fibrillated fibers. Due to their formation, these fibers do not have a high internal pressure after melting, which is particularly advantageous because the dimensions of the obtained filter cylinder, especially its diameter, are practically the same before and after the heating of the pulp. 'Thin filaments can also be used as heat-meltable fibers, for example polyethylene obtained by conventional spinning 6 68952 and cut into short pieces. However, the physical properties of the obtained fibrous structure are not as good as those obtained with fibrillated fibers.

Of the absorbent fibers which are stable at the melting temperature of the polyethylene heat-meltable fibers, wood cellulose fibers can be used, namely, spruce, pine, and spruce fibers, or hardwoods such as birch, oak, or eucalyptus wood fibers, etc. they are not fibrillated, high absorption capacity of tobacco smoke tar. They are also inexpensive because of their low cost.

Short cotton fibers can also be used.

As absorbent fibers, fibers obtained by cutting artificial or synthetic yarns, for example cellulose acetate yarns, can also be used. Their length and diameter must be of the same order of magnitude as cellulose fibers and their melting point must be considerably higher than that of heat-meltable fibers.

Activated carbon fibers having a length and diameter very close to the corresponding values of the cellulosic fibers can also be used, at least in part, as absorbent fibers. In this way, the well-known ability of activated carbon to absorb the gas phase components and vapors of tobacco smoke can be exploited.

The weight ratio of different types of fibers varies according to the degree of ventilation required of the structure to be filtered, i.e. according to the permeability of the smoke stream. It is essential 68952 that there be a large amount of heat-meltable fibers (at least 25% of the pulp) relative to the absorbent fibers so that the pore network formed by the melting of the heat-meltable fibers contains sufficient air in the filter structure. The proportion of heat-meltable fibers also makes it possible to vary the density of the filter.

The proportion of absorbent fibers and their quality can also be used to determine the degree of efficiency of the structure to be filtered. The use of hardwood fibers in place of spruce fibers means, while other factors remain the same, lower permeability and tightness and greater efficiency. Thus, for example, in a filter of a given density, it can be shown that an increase in the proportion of heat-meltable synthetic fibers means a decrease in the drag resistance of the fumes and an efficiency in the filtration, while an increase in density. On the contrary, increasing the proportion of absorbent fibers means increasing the drag resistance and filtration efficiency of the breath fumes, but in contrast, the density decreases.

In addition, it has been found that an increase in the filling density of a cylindrical log with a fiber composition having a certain composition means that the resistance to drawing smoke, the efficiency of filtration and the tightness are increased.

In the preferred embodiment, when the mixture comprises 50% heat-meltable fibers and 50% cellulose fibers, the filter density ranges from 0.105 to 0.150. This corresponds to the limits of the smoke extraction resistance 50 mm C.E. - 150 mm C.E. For 8 mm x 20 mm filter head.

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In another embodiment, the mixture contains 1/3 cellulose fibers, 1/3 activated carbon fibers, and 1/3 heat-meltable fibers, resulting in a sufficiently dense permeable filter that is very efficient at absorbing both the tars contained in the tobacco smoke and the gas phase and vapor.

Once the fibrous mass has been formed into a cylindrical block, it is heated in any known manner, such as by means of hot air circulation, by means of infrared radiation, by high-frequency heating or by microwaves. The heating method used must in all cases be such that all the heat-meltable fibers in the cylindrical log reach their melting point simultaneously.

The present invention has the following advantages in the filtration of cigarettes: excellent result with a filter material: the density per specific filtration efficiency of the harmful substances of tobacco smoke is considerably lower than in the filters normally used, which are cellulose acetate or paper; the ability to obtain efficient gas phase and vapor filtration of tobacco smoke using activated carbon fibers; - the possibility to easily vary the efficiency and tightness by changing the quality and dimensions of the heat-stable absorbent fibers, the proportion of heat-meltable fibers used and the filling density of the filter tube; - excellent density and excellent elasticity before and after smoking, which two properties are significantly higher than pulp

II

9 68952 with loose acetate filters having the same breathing resistance; the advantageous appearance of the filter part, it has no visible pores, but on the contrary it is as flat as in cellulose acetate filters; low cost compared to cellulose acetate or paper filters due to the relatively low cost of the fibrous material of the blend used.

Claims (10)

10. , 68952 A method of making a filter structure, especially for cigarette filters, from a pulp, the method comprising forming a homogeneous mixture of different types of fibers, one fiber type being synthetic and low melting point and melt-in-melt stable fibers, the other fiber type at the melting point of the fibers, and said fiber mixture is formed into a cylindrical rod which is not yet in a cohesive state but is in a homogeneous state and contains fibrous webs tightly overlapping each other, characterized in that a significant proportion of thermally fusible fibers is used the fibers are elongated in shape, the rod-shaped mixture is heated to a temperature at which the absorbent fibers remain unchanged, but which is high enough to melt; to liquefy all the heat-meltable substance originally present in the form of elongate fibers and to convert it into small droplets dispersed in a network of absorbent fibers, so that this junction creates several joints at the intersections of the absorbent, stable fibers on the one hand and the pores on the other. the pores are in contact with each other in all directions and are formed by the spaces left empty by the heat-melting fibers completely melting. Method according to Claim 1, characterized in that a pulp with a single type of absorbent fiber is used. Method according to Claim 1, characterized in that a pulp is used which has at least two types of absorbent fibers of different qualities. Process according to Claim 1, characterized in that the heat-meltable fibers are polyolefin fibers. Il 11 68952 A method according to claim 4, characterized in that the polyolefin fibers are fibrillated high density polyethylene fibers for paper and joined together into fibrillated fiber-rich bundles with a very irregular and very fluffy surface with a high specific surface area, and the main length of said fibers varies between 1-2 mm and their diameter varies between 2-25. Process according to Claim 1, characterized in that wood cellulose fibers are used as absorbent fibers. A method according to claim 1, characterized in that cotton fibers, activated carbon fibers and / or short pieces of cellulose acetate strands are used as absorbent fibers, and the length and diameter of said fibers and strands are of the same order of magnitude as wood cellulose fibers. Method according to one of Claims 2 to 5, characterized in that short pieces of synthetic material, such as polypropylene, are used as absorbent fibers, the melting point of which is clearly higher than that of heat-meltable fibers. Process according to one of Claims 1 to 3, characterized in that a pulp is used which contains at least 25% of heat-meltable fibers. Process according to any one of Claims 1 to 9, characterized in that a pulp is used which contains 50% of fibrillated fibers, which are high-density polyethylene for use in paper, and 50. pine cellulose fibers derived from bleached chemical pulp, and that these the properties of the fibers, such as shape, fine structure, and external dimension, provide the fiber mass with a low density after it has been shaped. 12 68952