EP3775374A1

EP3775374A1 - Sheathing paper with use indicator for aerosol-generating articles

Info

Publication number: EP3775374A1
Application number: EP20715803.1A
Authority: EP
Inventors: Roland Zitturi
Original assignee: Delfortgroup AG
Current assignee: Delfortgroup AG
Priority date: 2019-05-15
Filing date: 2020-03-26
Publication date: 2021-02-17
Anticipated expiration: 2040-03-26
Also published as: JP2022533327A; PL3775374T3; CN113795629A; CN113795629B; ES2939937T3; KR20220009378A; EP3775374B1; WO2020229037A1; DE102019112777B3; US20220256913A1

Abstract

The invention relates to a sheathing paper for aerosol-generating articles, which paper comprises cellulose fibres and onto which paper a composition is applied, which comprises a substance that accelerates the thermal breakdown of cellulose and a binder. Should the mean air permeability of the sheathing paper be 10cm³/(cm²·min·kPa) or more, said composition is merely applied in some regions, which cover at least 0.5% and at most 70% of the area of the sheathing paper.

Description

WRAPPING PAPER MGG USAGE INDICATOR

FOR AEROSOL GENERATING ARTICLES

FIELD OF THE INVENTION

The invention relates to an aerosol-generating article in which the aerosol-generating material is heated and thus an aerosol is released, but the aerosol-generating material is not burned. The aerosol-generating article comprises a wrapping paper to which a substance is applied over the entire surface or in partial areas which causes a change in the optical properties of the wrapping material and thus indicates that the aerosol-generating article has been used. In particular, the wrapping paper of the aerosol-generating article according to the invention is designed in such a way that its color changes irreversibly at least in partial areas when heated, with particular consideration being given to the fact that the air permeability of the wrapping material is little affected. The invention also relates to a method for producing such a wrapping paper.

BACKGROUND AND PRIOR ART

In the prior art, aerosol generating articles are known which comprise an aerosol generating material, as well as a paper which wraps the aerosol generating material to form a typically cylindrical rod. The aerosol-generating material is a material that releases an aerosol when exposed to heat, the aerosol-generating material only being heated but not burned. In many cases, the aerosol-generating de article also comprises a filter which can filter components of the aerosol and which is wrapped by a filter wrapping paper, as well as by a further wrapping paper which connects the filter and the wrapped rod with aerosol-generating material.

When an aerosol-generating article is used as intended, it is common for the aerosol-generating material to be heated but not incinerated. This heating can be done, for example, by an external device into which the aerosol-generating article is inserted, or by a heat source attached to one end of the aerosol-generating article, which is put into operation for use of the article, for example by lighting it up. In many cases there are several aerosol-generating articles in one package and often, after use, the used aerosol-generating article is returned in the package with the still unused aerosol-generating articles. Since the aerosol-generating material is only heated and not burned, the used aerosol-generating article differs from the unused aerosol-generating article optically not or only very little. In any case, the consumer cannot quickly decide which of the aerosol-generating articles are used and which are not yet used.

SUMMARY OF THE INVENTION

The invention is based on the object of providing a wrapping paper for an aerosol-generating article that changes its appearance irreversibly during or shortly after use of the aerosol-generating article, so that the aerosol-generating article can easily be recognized as used. For the purposes of this invention, aerosol-generating articles are rod-shaped articles which comprise an aerosol-generating material and a wrapping paper that wraps the aerosol-generating material, with the aerosol-generating material only being heated and not burned when used as intended. Typical aerosol-generating materials are heated without combustion if the aerosol-generating material is heated to a temperature of at most 400 ° C.

This object is achieved by a wrapping paper for an aerosol-generating article according to claim 1, an aerosol-generating article comprising this wrapping paper according to claim 19 and a method for producing a wrapping paper according to the invention according to claim 21. Advantageous developments are given in the dependent claims.

The inventors have found that this problem can be solved by a wrapping paper to which a certain composition is applied over the entire surface or in partial areas, which causes an irreversible color change of the wrapping paper when heated by accelerating the thermal degradation of the cellulose in the wrapping paper. On the basis of this color change, a used aerosol-generating article can be distinguished from an unused one with the naked eye.

It should be noted that thermochromic inks are already known in the prior art which show a color change when heated above a certain temperature, but which are deliberately not used in the present invention. One reason for this is that the color change of thermochromic colors is often reversible, so that it disappears again when the aerosol-generating article cools down. In contrast to this, the degradation of the cellulose in the wrapping paper according to the invention is actually irreversible and thus allows the used aerosol-generating article to be reliably identified, even if it has been used for a long time. In addition, the temperature at which the color change occurs in known thermochromic colors is comparatively low, so that the storage of the unused aerosol-generating article at a higher temperature, for example in a parked vehicle in the summer, can cause a color change so that an unused article could be mistakenly mistaken for a used one. In addition, when the aerosol-generating article is heated up, temperatures of up to 400 ° C are reached for several minutes, and at such temperatures thermochromic inks can partially be thermally degraded so that they lose their function.

Furthermore, depending on the construction of the aerosol generating article, air should flow through the wrapping paper into the aerosol generating material when it is used. However, a thermochromic paint applied to the wrapping paper can considerably reduce the air permeability of the wrapping paper, which is why it is often not possible to apply a sufficient amount of such colors to the wrapping paper without impairing the function of the article.

Finally, the substances that may be used for wrapping papers for aerosol-generating articles are considerably restricted by legal regulations in many countries, so that thermochromic inks, even if they could be used from a technical point of view, are often not allowed to be used. A special inventive effect in the invention therefore, deviating from the behavior known from thermochromic inks, among other things, is that the substance applied does not change its color itself, but causes a change in the color of the cellulose in the wrapping paper. The wrapping paper must comprise cellulose fibers, the cellulose fibers in the wrapping paper in an amount of at least 50% of the weight of the wrapping paper. This amount of cellulose fibers is at least necessary to make the color change clearly visible. The wrapping paper has an average air permeability of at least 0 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa). The air permeability is measured according to ISO 2965: 2009 with a measuring head with an opening area of 2 mm x 15 mm, the mean air permeability being determined from ten measurements at randomly selected positions on the wrapping paper.

The composition applied to the wrapping paper must contain at least one substance that accelerates the thermal degradation of the cellulose in order to bring about the color change, as well as a binding agent in order to apply said substance on or in the paper fix. The substance accelerating the thermal degradation of cellulose is suitable for causing an irreversible color change of the wrapping paper that is visible to the naked eye when the wrapping paper is heated to a temperature of at least 130 ° C for 5 minutes due to the thermal degradation of cellulose in the paper.

If the wrapping paper has an air permeability of more than 10 cm ³ / (cm ² -min-kPa), it is important that the air can flow evenly over the surface of the wrapping paper, so that larger areas with low air permeability are to be avoided. Such areas of low air permeability can result from the application of the composition.

Sufficient air permeability is ensured according to the invention in that the composition is only applied in partial areas of the wrapping paper, the partial areas covering at least 0.5% and at most 70% of the area of the wrapping paper. This limits the extent to which the air permeability is influenced, but it is also ensured that the area is sufficiently large that the change in color can be clearly seen.

In addition, the homogeneity of the air permeability is ensured according to the invention in that the sub-areas are designed in a suitable manner and arranged on the wrapping paper, the suitable design or arrangement of these sub-areas for the purposes of the invention being assessed on the basis of two criteria, of which at least at least one thing must be fulfilled. According to the first criterion, if the mean air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 20 cm ³ / (cm ² -min-kPa), the standard deviation of the air permeability should not exceed 6 cm ³ / (cm ² -min-kPa), and should, if the mean air permeability of the wrapping paper is at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), the coefficient of variation in air permeability should not exceed 30%. To determine the standard deviation and the coefficient of variation of the air permeability, a measuring head with an opening area of 2 mm x 15 mm is used and the standard deviation and the coefficient of variation are determined from ten measurements on areas that are close together but not overlapping, so that the mean value and an area of about 300 mm ^{2 is} used for the standard deviation. The coefficient of variation is then the quotient of the standard deviation and the mean and is expressed as a percentage. The mean value used in this calculation is generally not related to the mean air permeability described above match, which is determined from measurements on ten randomly selected positions.

As an alternative or in addition to the specification of the air permeability scatter parameters, it is also sufficient, according to a second criterion, if with an average air permeability of at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa ) the sub-areas in which the composition is applied to the wrapping paper are designed so that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not applied, the diameter of the circle D in mm from the mean air permeability x in cm ³ / (cm ² -min-kPa) through

iPmax D _m in) (. ^x

D = D Iß)

max 190

is calculated and D _ma x = 12 mm and Dmin = 6 mm.

The effect of this formula is that with a low average air permeability, for example 10 cm ³ / (cm ² -min-kPa), the circle can have a relatively large diameter of 12 mm and thus the subregions can have coarser structures. This is possible because with low air permeability the influence of the partial areas on which the substance is applied is less significant. With high air permeability, for example 200 cm ³ / (cm ² -min-kPa), the circle may only have a relatively small diameter of 6 mm and the sub-areas must therefore have a finer structure so that the air continues to flow homogeneously through the surface of the wrapping paper flows.

In summary, the inventors have invented a wrapping paper for aerosol generating articles,

- which comprises cellulose fibers, at least 50% of the mass of the wrapping paper being formed by cellulose fibers,

- that has an average air permeability of at least o cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), measured with a measuring head of 2 mm x 15 mm according to ISO 2965: 2009 at ten randomly selected positions,

- A composition is applied to which comprises a substance which accelerates the thermal degradation of cellulose and a binding agent, and

In the event that the average air permeability of the wrapping paper is 10 cm ³ / (cm ² -min-kPa) or more, the said composition is only applied in partial areas that are at least 0.5% and at most 70% of the area of the Cover the wrapping paper, and wherein in this case, that is, if the average air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa), the aforementioned sub-areas are arranged on the wrapping paper in such a way that at least one of the following two criteria (1 ), (2) is fulfilled:

(1) if the mean air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 20 cm ³ / (cm ² -min-kPa), then the standard deviation of the air permeability is at most 6 cm ³ / ( cm ² -min-kPa) and if the mean air permeability of the wrapping paper is at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), then the

Coefficient of variation of air permeability not more than 30%, or

(2) the partial areas to which the composition is applied are designed so that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not applied, the diameter D in mm the mean air permeability x in cm ³ / (cm ² -min-kPa)

iPmax D _m in) (. ^x

D = D Iß)

max 190

is calculated, where D _ma x = 12 mm and Dmin = 6 mm. The mean air permeability x is determined as the mean value from ten measurements at randomly selected positions on the wrapping paper. The individual measurement is carried out in accordance with ISO 2965: 2009 with a measuring head with an opening area of 2 mm x 15 mm. During the measurement it should therefore be ignored that the opening area can typically simultaneously comprise areas to which the composition is applied and areas to which it is not applied.

To determine the standard deviation and the coefficient of variation of the air permeability, ten measurements are also carried out in accordance with ISO 2965: 2009 with a measuring head with an opening area of 2 mm x 15 mm, whereby the measurements are carried out on surfaces that are close together but not overlapping, see above - that an area of about 300 mm ^{2 is} used to form the mean and the standard deviation. The coefficient of variation is then the quotient of the standard deviation and the mean of the measured values determined in this way and is expressed as a percentage. The individual measuring surfaces are preferably arranged in such a way that they adjoin one another with their longer, that is to say the 15 mm long side, or lie parallel to one another at a small distance, preferably at most 2 mm. Typical wrapping papers not according to the invention for aerosol-generating articles with air permeability which is naturally homogeneous over the entire surface have a coefficient of variation of at most 15% measured in this way. On the other hand, wrapping papers to which a composition is applied to larger areas can achieve coefficients of variation in air permeability of 50% to 80%. This applies in particular when the composition is film-forming and thus closes the pores of the wrapping paper or the composition is applied in the form of strips several mm wide. The wrapping paper preferably has a basis weight of at least 15 g / m ² , particularly preferably of at least 18 g / m ² and very particularly preferably of at least 20 g / m ² . Such a weight per unit area gives the wrapping paper a tensile strength which is favorable for the further processing of the wrapping paper into an aerosol-generating article.

The wrapping paper preferably has a weight per unit area of at most 100 g / m ² , particularly preferably at most 60 g / m ² and very particularly preferably at most 45 g / m ² . The weight per unit area of the wrapping paper is preferably not so high that restoring forces can make the wrapping of the aerosol-generating material more difficult during the manufacture of the aerosol-generating article.

The basis weight of the wrapping paper includes the applied composition and can be measured according to ISO 536: 2012.

The wrapping paper contains cellulose fibers, the cellulose fibers accounting for at least 50% of the weight of the wrapping paper and preferably at least 60% of the weight of the wrapping paper and particularly preferably at least 65% of the weight of the wrapping paper. The cellulose fibers are necessary so that the effect of the substance which accelerates the thermal breakdown of cellulose can also be easily recognized optically from the change in color. The cellulose fibers are obtained from one or more plants that are selected from the group consisting of conifers, deciduous trees, spruce, pine, fir, beech, birch, eucalyptus, flax, hemp, jute, ramie, abaca, sisal, kenaf and cotton. The cellulose fibers can also be wholly or partly fibers made from regenerated cellulose, such as Tencel ™ fibers, Lyocell ™ fibers, viscose fibers or Modal ™ fibers.

The cellulose fibers are preferably at least partially bleached because the white color of the bleached cellulose fibers makes the color change more easily recognizable. The share of un- bleached cellulose fibers, which usually have a light brown to dark brown color, should preferably be at most 50% of the mass of the cellulose fibers.

The wrapping paper according to the invention can also contain one or more fillers. The total amount of fillers preferably makes up at most 40%, particularly preferably at least 10% and at most 38% and very particularly preferably at least 20% and at most 35% of the mass of the wrapping paper. The proportion of fillers can have a beneficial effect on the air permeability, color and opacity of the wrapping paper, so that a change in color when the aerosol-generating article made from it is heated is easier to see.

The filler or fillers are preferably white, water-insoluble particles and can particularly preferably be selected from the group consisting of calcium carbonate, magnesium carbonate, magnesium oxide, magnesium hydroxide, aluminum hydroxide, talc, kaolin and titanium dioxide.

The wrapping paper can also contain other substances that are required for the production of the wrapping paper or give the wrapping paper other special properties. Such substances can be, for example, pigments, dyes, sizing agents, starch, retention aids or processing aids and can be selected by the person skilled in the art according to type and amount on the basis of his experience.

Outside the subareas to which the composition was applied, the wrapping paper preferably does not contain any substances that accelerate the breakdown of cellulose, or only in an amount that is 0.5% of the weight of the wrapping paper, particularly preferably 0.25% of the weight of the wrapping paper and most preferably does not exceed 0.1% of the weight of the wrapping paper per area. Higher proportions of these substances would make the change in color of the wrapping paper more difficult to detect in comparison to the partial areas in which the said composition was applied.

A composition is applied over the entire surface or in partial areas to the wrapping paper, comprising a binding agent and a substance that accelerates the thermal degradation of cellulose. The amount of binder that is applied in partial areas of the wrapping paper should be rather small because the binder reduces the air permeability and increases the coefficient of variation of the air permeability. The amount of binder that is applied in partial areas of the wrapping paper is therefore preferably at most 15%, especially preferably at most 10% and very particularly preferably at most 5% of the mass of the wrapping paper per area.

The binder is preferably selected from the group consisting of starch, starch derivatives, cellulose derivatives, carboxymethyl cellulose, alginates, pectins, polyvinyl alcohol, guar and gum arabic or mixtures thereof.

The substance that accelerates the thermal degradation of cellulose is in the areas of the wrapping paper in which the composition containing it is applied in an amount preferably of at least 0.2 g / m ² and at most 8.0 g / m ² , particularly preferably of at least 0.3 g / m ² and at most 7.0 g / m ² and very particularly preferably of at least 0.5 g / m ² and at most 5.0 g / m ² . The amount of substance that accelerates the thermal breakdown of cellulose is selected here so that a change in color can be seen particularly well, especially with the naked eye, even in poor lighting conditions.

Alternatively and preferably, the amount of the applied substance, which accelerates the thermal degradation of the cellulose, can also be characterized in relation to the amount of the cellulose fibers contained in the wrapping paper. This quantitative ratio is important because, according to the invention, the substance should act on the cellulose fibers. The ratio of the amount of said substance in g / m ² based on the area to which the composition containing it is applied and the amount of pulp fibers in the wrapping paper in g / m ² is preferably at least 0.05 and at most 0.45, particularly preferably at least 0.06 and at most 0.30 and very particularly preferably at least 0.07 and at most 0.25. The most favorable ratio in each case depends on the specific substance that accelerates the thermal breakdown of the cellulose.

The substance that accelerates the thermal breakdown of cellulose is preferably one or more of the chemical compounds selected from the group consisting of citrates, malates, tartrates, acetates, nitrates, succinates, fumarates, gluconates, glycolates, lactates, oxylates, salicylates, a Hydroxycaprylates, hydrogen carbonates, carbonates, chlorides, polyphosphates, phosphonates and phosphates and particularly preferably one or more of the chemical compounds selected from the group consisting of tri-sodium citrate, tripotassium citrate, monoammonium phosphate, sodium acetate, potassium acetate, sodium hydrogen carbonate, potassium hydrogen carbonate, sodium carbonate, potassium carbonate, sodium carbonate , Potassium sodium tartrate, potassium formate, sodium formate, sodium nitrate and potassium nitrate. Very particularly preferably the substance is one or more of the chemical compounds selected from the group consisting of tripotassium citrate, monoammoni- umphosphate, sodium hydrogen carbonate, sodium acetate and potassium carbonate. The very particularly preferred chemical compounds cause a particularly noticeable change in the color of the cellulose, as they promote the formation of carbon particularly well.

If the average air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), then the sub-areas in which the said composition is applied are so designed that they make up at least 0.5% and at most 70%, preferably at least 1% and at most 60%, particularly preferably at least 1% and at most 20% and very particularly preferably at least 1% and at most 10% of the area of the wrapping paper.

If the average air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), the sub-areas must also be designed in such a way that at least one of the two the following criteria (3), (4) are met:

(3) if the average air permeability of the wrapping paper is greater than 10 cm ³ / (cm ² -min-kPa) and less than 20 cm ³ / (cm ² -min-kPa), then the standard deviation of the air permeability is at most 6 cm ³ / (cm ² -min-kPa), before given at most 5.5 cm ³ / (cm ² -min-kPa) and particularly preferably at most 5 cm ³ / (cm ² -min-kPa) and if the average air permeability of the Umhüllungspa piers at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), then the coefficient of variation of the air permeability is at most 30%, preferably at most 27.5% and particularly preferred at most 25%, or

(4) the partial areas to which the composition is applied are designed so that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not applied, the diameter D being in mm the mean air permeability x in cm ³ / (cm ² -min-kPa)

iPmax D _m in) (. ^x

D = D Iß)

max 190

is calculated, and wherein D _ma x = 12 mm and D _m in = 6 mm, preferably D _ma x = 10 mm and Dmin = 5 mm, and more preferably D _max = 8 mm and D min = 4 mm, and most preferably D _max = 6 mm and D _m in = 3 mm.

If the average air permeability of the wrapping paper is at least 0 cm ³ / (cm ² -min-kPa) and at most 10 cm ³ / (cm ² -min-kPa), the composition can be applied over the entire surface or in partial areas. When the order is in sub-areas the subareas in which the composition is applied to the wrapping paper, preferably designed so that each imaginary circle with a diameter of 12 mm, particularly preferably with a diameter of 10 mm and very particularly preferably with a diameter of 8 mm on the wrapping paper contains at least one area in which the composition is not applied.

If the average air permeability of the wrapping paper is at least o cm ³ / (cm ² -min-kPa) and at most 10 cm ³ / (cm ² -min-kPa) and the composition is only applied in partial areas, then the partial areas in to which said composition is applied, designed so that it is preferably at least 0.5% and at most 70%, particularly preferably at least 1% and at most 60%, particularly preferably at least 1% and at most 20% and in particular at least 1% and at most Make up at least 10% of the area of the wrapping paper.

The smaller the area on which the composition is applied, the less the air permeability of the wrapping paper is influenced in terms of its mean value and its coefficient of variation, but on the other hand it also makes the individual sub-areas on which the color change is visible, which is more difficult it can be seen that the aerosol-generating article made from it has already been used.

Criteria (3) and (4) are not equivalent in their effect, which means that the fulfillment of one criterion does not necessarily result in the fulfillment of the other, but each is sufficient to obtain a wrapping paper according to the invention that works well on aerosol generating articles. The same applies to criteria (1) and (2) mentioned above.

The aerosol-generating article according to the invention is rod-shaped and comprises an aerosol-generating material and the wrapping paper according to the invention, the wrapping paper wrapping the aerosol-generating material and wherein in the intended use of the aerosol-generating article, the aerosol-generating material is only heated but not burned.

In a preferred embodiment of the aerosol-generating article, the aerosol-generating material is heated to a maximum temperature of at least 120 ° C and at most 500 ° C and particularly preferably to a maximum temperature of at least 200 ° C and at most 400 ° C. In a preferred embodiment, the aerosol generating article additionally contains a filter.

The wrapping paper according to the invention can be produced by a method according to the invention which comprises the following steps A-C:

A - providing a wrapping base paper,

B - applying a composition to the wrapping base paper, and

C - drying the wrapping paper obtained in step B, wherein

the wrapping paper obtained in step C comprises cellulose fibers, at least 50% of the mass of the wrapping paper being formed by cellulose fibers, and the wrapping paper obtained in step C has an average air permeability of at least o cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), measured with a measuring head with 2 mm x 15 mm according to ISO 2965: 2009, and

In step B a composition is applied which comprises a substance accelerating the thermal degradation of cellulose and a binder, and which, if the average air permeability of the wrapping paper obtained in step C is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa) is applied in step B in partial areas that cover at least 0.5% and at most 70% of the area of the wrapping paper,

and wherein the wrapping paper obtained in step C if the average air permeability of the wrapping paper obtained in step C is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), at least one of the following two criteria (1), (2) met:

(1) if the average air permeability of the wrapping paper obtained in step C is at least 10 cm ³ / (cm ² -min-kPa) and at most 20 cm ³ / (cm ² -min-kPa), then the standard deviation of the air permeability is at most 6 cm ³ / (cm ² -min-kPa) and if the average air permeability of the wrapping paper obtained in step C is at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa) then the coefficient of variation of the air permeability is at most 30%, or

(2) the partial areas to which the composition is applied in step B are designed so that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not applied, the diameter D in mm from the mean air permeability x in cm ³ / (cm ² -min-kPa) of the wrapping paper obtained after step C through iPmax D _m in) (A Iß)

D = D max 190

is calculated and D _max = 12 mm and Dmin = 6 mm.

With regard to the properties and components of the wrapping paper obtained in step C, the same necessary, preferred, particularly preferred and very particularly preferred value ranges and properties apply as were already mentioned for the wrapping paper according to the invention. This applies in particular to the weight per unit area, the standard deviation and the coefficient of variation of the air permeability, the type and amount of pulp fibers, the type and amount of fillers and the design of the sub-areas in which the composition is applied, for example with regard to their proportion of the total area of the Wrapping paper and the choice of parameters D _max and Dmin.

The composition which is applied in step B comprises a substance which accelerates the thermal degradation of cellulose, a binder and a solvent, the solvent preferably being water.

The substance in the composition of step B that accelerates the thermal breakdown of cellulose is a chemical compound or a mixture of two or more chemical compounds and preferably dissolves in the solvent of the composition.

The substance contained in the composition of step B, which accelerates the thermal degradation of the cellulose, is preferably one or more of the chemical compounds selected from the group consisting of citrates, malates, tartrates, acetates, nitrates, succinates, fumarates, gluconates, glycolates, Lactates, oxylates, salicylates, α-hydroxycaprylates, hydrogen carbonates, carbonates, chlorides, polyphosphates, phosphates and phosphates and particularly preferably one or more of the chemical compounds selected from the group consisting of trisodium citrate, tripotassium citrate, monoammonium phosphate, sodium acetate, potassium acetate, Sodium hydrogen carbonate, potassium hydrogen carbonate, sodium carbonate potassium carbonate, sodium tartrate, potassium sodium tartrate, potassium formate, sodium formate, sodium nitrate and potassium nitrate. The substance is very particularly preferably one or more of the chemical compounds selected from the group consisting of tripotassium citrate, monoammonium phosphate, sodium hydrogen carbonate, sodium acetate and potassium carbonate.

The composition that is applied to the wrapping base paper in step B contains the substance that accelerates the thermal degradation of the cellulose in an amount of preferably at least 3% and at most 30%, particularly preferably at least 4% and at most 25% and very particularly preferably at least 5% and at most 20%, each based on the mass of the composition.

The binder in the composition of step B is preferably selected from the group consisting of starch, starch derivatives, cellulose derivatives, carboxymethyl cellulose, alginates, pectins, polyvinyl alcohol, guar and gum arabic or mixtures thereof.

The composition that is applied to the wrapping base paper in step B contains the binder in an amount of preferably at least 0.1% and at most 15%, particularly preferably at least 0.3% and at most 12% and very particularly preferably at least 0.5 % and at most 10%, each based on the amount of the composition. The amount of binder also depends on the requirements of the application process in step B, in particular with regard to the viscosity of the composition.

During the drying in step C, the solvent is largely removed from the composition and the applied dried composition is then in an amount of preferably at least 0.2 g / m ² and at most 8 g / m ² , particularly preferably at least 0.5 g / m ² ² and at most 6 g / m ² and very particularly preferably at least 1 g / m ² and at most 5 g / m ² applied based on the area to which the composition was actually applied.

The application in step B can be carried out by various methods, printing and spraying being preferred and gravure printing or flexographic printing being very particularly preferred.

The drying process in step C can be carried out by various processes, preferably by contact with one or more heated cylinders, contact with hot air, infrared radiation, microwave radiation and combinations thereof.

In a particularly preferred embodiment of the method according to the invention, after step C it also comprises the additional steps D and E, where in step D water is applied over the entire surface of the wrapping paper obtained in step C and in step E the wrapping paper from step D is dried, very particularly preferably by contact with one or more heated cylinders. When applying the composition in step B, in particular if the solvent contains water, wrinkles can occur after drying in step C. By means of steps D and E of this particularly preferred embodiment of the method according to the invention, such wrinkles can be considerably reduced or avoided entirely. BRIEF DESCRIPTION OF THE FIGURE

Fig. 1 shows an example of a wrapping paper and the positions at which the ten

Measurements to determine the standard deviation and the coefficient of variation of the air permeability can be carried out.

DESCRIPTION OF THE PREFERRED EMBODIMENT In the following, some preferred embodiments of wrapping papers according to the invention are described.

As the wrapping base paper in step A of the method of the present invention, two papers referred to as wrapping base paper A and wrapping base paper B were used.

Wrapping base paper A had a basis weight of 29 g / m ² and contained 69% wood pulp fibers and 31% precipitated calcium carbonate as filler. The percentages relate to the mass of the wrapping base paper. The wood pulp fibers were a mixture of pulp fibers obtained from conifers and deciduous trees. Wrapping base paper A had an average air permeability of 60.1 CU, the air permeability being measured according to ISO 2965: 2009 with a measuring head with an opening area of 2 mm x 15 mm at ten randomly selected positions and a mean value calculated from these ten measurements . Wrapping base paper B had a basis weight of 24 g / m ² and contained 71% wood pulp fibers and 29% precipitated calcium carbonate as filler. The percentages relate to the mass of the wrapping base paper. The wood pulp fibers were a mixture of pulp fibers obtained from conifers and deciduous trees. Wrapping base paper B had an average air permeability of 74.8 CU, the air permeability being measured according to ISO 2965: 2009 with a measuring head with an opening area of 2 mm x 15 mm at ten randomly selected positions and a mean value calculated from these ten measurements has been.

Various compositions were applied to the wrapping base papers A and B in partial areas in the form of a pattern of intersecting 1.5 mm wide lines by gravure printing so that the partial areas to which the composition was applied accounted for about 40% of the area of the wrapping base paper. - l6 -

The amount of the composition which was applied in the partial areas was 30 g / m ² for wrapping base paper A and 25 g / m ² for wrapping base paper B, based on the area to which the composition was actually applied. The wrapping papers were then dried according to step C of the method according to the invention.

The parameters of the wrapping papers that are relevant for production are given in Table 1. The "No." column indicates the number of the wrapping paper, the "BP" column indicates which wrapping base paper was used for production. The “Composition” column shows the binder and the substance that accelerates the thermal breakdown of the cellulose in% based on the mass of the composition. The type of binding agent is indicated, with “CMC” meaning carboxymethyl cellulose and “St” meaning starch. The type of substance is also indicated, with “TKZ” tripotassium citrate, “MAP” monoammonium phosphate, “NaAc” sodium acetate and “KCrb” potassium carbonate mean. The “Wrapping paper” column shows the amounts of binding agent and the substance that accelerates the thermal degradation of cellulose in g / m ² and in% based on the weight per unit area of the wrapping paper, as well as the “V” ratio of the amount of said substance in g / m ² to the amount of cellulose fibers in the wrapping paper in g / m ² .

As for the wrapping base papers A and B, the air permeability was measured at ten random positions in accordance with ISO 2965: 2009 with a measuring head with an opening area of 2 mm x 15 mm and the mean value was calculated from this. For the wrapping papers 1 to 12, which were produced from the wrapping base paper A, the average air permeability was between 42 cm ³ / (cm ² -min-kPa) and 48 cm ³ / (cm ² -min-kPa), while the mean air permeability for the wrapping papers 13 to 18, which were made from the wrapping base paper B, was between 50 cm ³ / (cm ² -min-kPa) and 55 cm ³ / (cm ² -min-kPa).

To test criteria (1) or (3), the coefficient of variation of the air permeability was determined in accordance with ISO 2965: 2009 using a measuring head with an opening area of 2 mm x 15 mm. The measuring method is explained with reference to FIG. 1. On the wrapping paper 1 in Figure 1, the composition is applied in the form of intersecting lines 2 and the measuring head with an opening area of 2 mm x 15 mm was placed on ten adjacent positions 3a to 3j, the individual positions offset by 3 mm so that there was a distance of 1 mm between the surfaces. The air permeability was measured at each of positions 3a to 3j. From this, the mean and the standard deviation were determined and the coefficient of variation calculated. For the wrapping papers 1 to 12, which were made from the wrapping base paper A, there were coefficients of variation between 10% and 15%, and for the wrapping papers 13 to 18, which were made from the wrapping base paper B, there were coefficients of variation between 12% and 17%. , whereby criteria (1) and (3) are met.

To test criteria (2) and (4), the diameter of the imaginary circle was determined on the basis of the measured average air permeability for each of the wrapping papers 1 to 18.

For the wrapping papers 1 to 12, which were produced from the wrapping base paper A, a diameter of 42 cm ³ / (cm ² -min-kPa) to 48 cm ³ / (cm ² -min-kPa) was obtained on the basis of an average air permeability of the circle of

(12-6) (42-10)

D = 12 - = 11.0 mm

190 - l8 - to

(12-6) (48-10)

D = 12 10.8 mm.

190

For the wrapping papers 13 to 18 made from the wrapping base paper B, a mean air permeability of 50 cm ³ / (cm ² -min-kPa) to 55 cm ³ / (cm ² -min-kPa) resulted Diameter of the circle of

(12-6) (50-10)

D = 12 - = 10.7 mm

190

to

(12 - 6) (55 - 10)

D = 12 10.6 mm.

190

The pattern with 1.5 mm wide crossing lines obviously fulfills the requirements of criteria (2) and (4) and thus these criteria are fulfilled for all wrapping papers 1 to 18.

The wrapping papers 1 to 18 were heated to 130 ° C. for 5 minutes. Color changes on the wrapping papers 1, 3, 6, 8, 11, 12, 13 and 17 were already visible after one minute. After 5 minutes, all of the wrapping papers according to the invention showed a clear, irreversible color change to yellowish hues in the partial areas in which the composition was applied and, with prolonged heating, to light brown to dark brown hues that clearly differed from the unchanged or hardly changed color could be distinguished outside of these sub-areas.

According to the state of the art, aerosol-generating articles were produced from the wrapping papers, which were heated as intended in a heater. After removing the aerosol-generating articles from the heater, a clear color change was also found in the printed areas, so that used and unused aerosol-generating articles could be clearly distinguished from one another.

Claims

CLAIMS l. Wrapping paper for aerosol-generating articles, which comprises cellulose fibers, at least 50% of the mass of the wrapping paper being formed by cellulose fibers which have an average air permeability of at least 0 cm3 / (cm2-min-kPa) and at most 200 cm3 / (cm2-min-kPa ), measured with a measuring head measuring 2 mm x 15 mm according to ISO 2965: 2009 at ten randomly selected positions, and to which a composition is applied which comprises a substance that accelerates the thermal breakdown of cellulose and a binder, the thermal Degradation of cellulose-accelerating substance is suitable, when heating the wrapping paper to a temperature of at least 130 ° C for 5 min, to cause an irreversible color change of the wrapping paper that is visible to the naked eye due to the thermal degradation of cellulose in the paper, whereby for the Case that the average air permeability of the wrapping paper is 10 cm3 / (cm2-min-kPa) or more, the Said composition is only applied in partial areas that cover at least 0.5% and at most 70% of the area of the wrapping paper, and the named partial areas in this case are arranged on the wrapping paper in such a way that at least one of the following two criteria (1) , (2) is fulfilled:

(1) if the mean air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 20 cm ³ / (cm ² -min-kPa), then the standard deviation of the air permeability is at most 6 cm ³ / ( cm ² -min-kPa), whereby the standard deviation is to be determined from ten measurements with the named measuring head of 2 mm x 15 mm on areas that are close to one another but not overlap,

and when the average air permeability of the wrapping paper is at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), then the coefficient of variation of the air permeability is at most 30%, the coefficient of variation is defined as the quotient of the specified standard deviation and the mean of the ten measurements from which the standard deviation is determined,

(2) The partial areas to which the composition is applied are designed so that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not is plotted, the diameter D in mm from the mean air permeability x in cm ³ / (cm ² -min-kPa) through

D - D _m ax

190

is calculated, with D _max = 12 mm and D _m in = 6 mm, the mean air permeability x corresponding to the mean value mentioned from ten measurements at randomly selected positions on the wrapping paper.

2. Wrapping paper according to claim 1, which has a basis weight of at least 15 g / m ² , preferably of at least 18 g / m ² and particularly preferably of at least 20 g / m ² .

3. Wrapping paper according to claim 1 or 2, which has a basis weight of at most 100 g / m ² , preferably of at most 60 g / m ² and particularly preferably of at most 45 g / m ² .

4. Wrapping paper according to one of the preceding claims, wherein the Zellstofffa fibers make up at least 60% of the mass of the wrapping paper and preferably at least 65% of the mass of the wrapping paper.

5. Wrapping paper according to one of the preceding claims, in which the Zellstofffa fibers are obtained from one or more plants which are selected from the group consisting of conifers, deciduous trees, spruce, pine, fir, beech, birch, eucalyptus, flax, hemp , Jute, ramie, abaca, sisal, kenaf and cotton.

6. Wrapping paper according to one of the preceding claims, in which at least part of the cellulose fibers is bleached, a proportion of unbleached cellulose fibers, if present, preferably being at most 50% of the mass of the cellulose fibers.

7. Wrapping paper according to one of the preceding claims, which contains one or more fillers, the total amount of fillers making up at most 40%, preferably at least 10% and at most 38% and particularly preferably at least 20% and at most 35% of the mass of the wrapping paper.

8. Wrapping paper according to claim 7, in which the fillers are formed by white, wasserunlösli che particles and are preferably selected from the group consisting of calcium carbonate, magnesium carbonate, magnesium oxide, magnesium hydroxide, aluminum hydroxide, talc, kaolin and titanium dioxide.

9. Wrapping paper according to one of the preceding claims, which outside of the partial areas to which the composition was applied, contains no substances accelerating the degradation of the cellulose, or only in an amount which is 0.5% of the weight of the wrapping paper, preferably 0.25 % of the mass of the wrapping paper and particularly preferably 0.1% of the mass of the wrapping paper per area does not exceed.

10. Wrapping paper according to one of the preceding claims, in which the amount of binder that is applied in partial areas of the wrapping paper is at most 15%, preferably at most 10% and particularly preferably at most 5% of the mass of the wrapping paper per area.

11. Wrapping paper according to one of the preceding claims, in which the Bindemit tel is selected from the group consisting of starch, starch derivatives, Cellulosederi derivatives, carboxymethyl cellulose, alginates, pectins, polyvinyl alcohol, guar and gum mi arabic or mixtures thereof.

12. Wrapping paper according to one of the preceding claims, in which the substance accelerating the thermal degradation of cellulose in the areas of the wrapping paper in which the composition containing it is applied, in an amount of at least 0.2 g / m ² and at most 8.0 g / m ² , preferably of at least 0.3 g / m ² and at most 7.0 g / m ² and particularly preferably of at least 0.5 g / m ² and at most 5.0 g / m ² .

13. Wrapping paper according to one of the preceding claims, in which the ratio of the amount of the thermal degradation of cellulose accelerating substance in g / m ² based on the area on which the composition containing it is applied conditions, and the amount of pulp fibers in the wrapping paper in g / m ² , at least 0.05 and at most 0.45, preferably at least 0.06 and at most 0.30 and particularly preferably at least 0.07 and at most 0.25.

14. Wrapping paper according to one of the preceding claims, in which the substance that accelerates the thermal degradation of the cellulose is one or more of the chemical compounds selected from the group consisting of citrates, malates, tartrates, acetates, nitrates, succinates , Fumarates, gluconates, glycols, lactates, oxylates, salicylates, α-hydroxycaprylates, hydrogen carbonates, carbonates, chlorides, polyphosphates, phosphonates and phosphates, preferably one or several of the chemical compounds selected from the group consisting of trisodium citrate, tripotassium citrate, monoammonium phosphate, sodium macetate, potassium acetate, sodium hydrogen carbonate, potassium hydrogen carbonate, sodium carbonate, potassium carbonate, sodium tartrate, potassium sodium tartrate, potassium formate, sodium formate and especially sodium nitrate, potassium formate, sodium formate be preferably one or more of the chemical compounds selected from the group consisting of tripotassium citrate, monoammonium phosphate, sodium hydrogen carbonate, sodium acetate and potassium carbonate.

15. Wrapping paper according to one of the preceding claims, wherein in the event that the average air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), the Subareas in which the said composition is applied are designed so that they make up at least 1% and at most 60%, preferably at least 1% and at most 20% and particularly preferably at least 1% and at most 10% of the area of the wrapping paper .

16. Wrapping paper according to one of the preceding claims, in which, in the event that the average air permeability of the wrapping paper is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), the sub-areas are designed in such a way that at least one of the following two criteria (3), (4) is met:

(3) if the mean air permeability of the wrapping paper is greater than 10 cm ³ / (cm ² -min-kPa) and less than 20 cm ³ / (cm ² -min-kPa), then the standard deviation of the air permeability is at most 5.5 cm ³ / (cm ² -min-kPa) and preferably at most 5 cm ³ / (cm ² -min-kPa) and if the average air permeability of the wrapping paper is at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), then the coefficient of variation of the air permeability is 27.5% and preferably at most 25%, or

(4) the subareas to which the composition is applied are designed such that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not applied, the diameter D in mm from the mean air permeability x in cm ³ / (cm ² -min-kPa)

iPmax D _m in) (A Iß)

D = D max

190 is calculated and where D _ma x = 10 mm and D _m in = 6 mm, preferably D _ma x = 8 mm and Dmin = 4 mm, and particularly preferably D _max = 6 mm and Dmin = 3 mm.

17. Wrapping paper according to one of the preceding claims, in which, in the event that the average air permeability of the wrapping paper is at least o cm ³ / (cm ² -min-kPa) and at most 10 cm ³ / (cm ² -min-kPa), the composition is applied over the entire surface or in partial areas, in the case of an application in partial areas, the partial areas in which the composition is applied to the wrapping paper, are preferably designed so that each imaginary circle with a diameter of 12 mm, preferably with a diameter of 10 mm and particularly preferably with a diameter of 8 mm on the wrapping paper contains at least one area in which the composition is not applied.

18. Wrapping paper according to one of the preceding claims, in which, in the event that the average air permeability of the wrapping paper is at least o cm ³ / (cm ² -min-kPa) and at most 10 cm ³ / (cm ² -min-kPa) and the composition is only applied in partial areas, the partial areas in which the said composition is applied are designed so that they are preferably at least 0.5% and at most 70%, preferably at least 1% and at most 60%, particularly preferred make up at least 1% and at most 20% and in particular at least 1% and at most 10% of the area of the wrapping paper.

19. Rod-shaped, aerosol-generating article which comprises an aerosol-generating material and a wrapping paper according to one of claims 1 to 18, wherein the wrapping paper wraps the aerosol-generating material and wherein the aerosol-generating material is only heated but not burned when the aerosol-generating article is used as intended.

20. Rod-shaped, aerosol-generating article according to claim 19, in which the aerosol-generating material is heated to a maximum temperature of at least 120 ° C and at most 500 ° C and preferably to a maximum temperature of at least 200 ° C and at most 400 ° C when used as intended, and / or which contains a filter.

21. A method for producing a wrapping paper for aerosol-generating articles, comprising the steps Ab to C:

A - providing a wrapping base paper, B - applying a composition to the wrapping base paper, and

C - drying the wrapping paper obtained in step B, wherein

the wrapping paper obtained in step C comprises cellulose fibers, at least 50% of the mass of the wrapping paper being formed by cellulose fibers, and the wrapping paper obtained in step C has an average air permeability of at least o cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), measured with a measuring head measuring 2 mm x 15 mm according to ISO 2965: 2009, and in step B a composition is applied which contains a substance that accelerates the thermal breakdown of cellulose and a binder comprises, wherein the substance accelerating the thermal degradation of cellulose is suitable, when the wrapping paper is heated to a temperature of at least 130 ° C for 5 min, an irreversible color change of the wrapping paper that can be seen with the naked eye due to the thermal degradation of cellulose in the paper to effect, and where in the composition, if the average air permeability of the envelope p obtained in step C apiers is at least 10 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), in step B it is only applied in partial areas that are at least 0.5% and at most 70% of the Cover the area of the wrapping paper,

(1) if the mean air permeability of the wrapping paper obtained in step C is at least 10 cm ³ / (cm ² -min-kPa) and at most 20 cm ³ / (cm ² -min-kPa), then the standard deviation of the air permeability is at most 6 cm ³ / (cm ² -min-kPa); and if the average air permeability of the wrapping paper obtained in step C is at least 20 cm ³ / (cm ² -min-kPa) and at most 200 cm ³ / (cm ² -min-kPa), then the coefficient of variation of the air permeability is at most 30% , or

(2) the subareas to which the composition is applied in step B are designed so that each imaginary circle with a diameter of D mm on the wrapping paper contains at least one area in which the composition is not applied, the diameter D in mm from the mean air permeability x in cm ³ / (cm ² -min-kPa) of the wrapping paper obtained after step C through

iPmax D _m in) (. ^x 10

D = D)

Max

190

is calculated and D _ma x = 12 mm and Dmin = 6 mm.

22. The method according to claim 21, wherein the composition applied in step B comprises a substance accelerating the thermal degradation of cellulose, a binder and a solvent, the solvent preferably being water.

23. The method of claim 22, wherein the substance in the composition of step B that accelerates the thermal degradation of cellulose is a chemical compound or a mixture of two or more chemical compounds and dissolves in the solvent of the composition.

24. The method according to any one of claims 21 to 23, wherein the substance contained in the composition of step B, which accelerates the thermal degradation of the cellulose, one or more of the chemical compounds is selected from the group consisting of citrates, malates, tartrates , Acetates, nitrates, succinates, fumarates, gluconates, glycolates, lactates, oxylates, salicylates, α-hydroxycaprylates, hydrogen carbonates, carbonates, chlorides, polyphosphates, phosphonates and phosphates and preferably one or more of the chemical compounds selected from the group consisting from trisodium citrate, tripotassium citrate, monoammonium phosphate, sodium acetate, potassium acetate, sodium hydrogen carbonate, potassium hydrogen carbonate, sodium carbonate, potassium carbonate, sodium tartrate, potassium sodium tartrate, potassium formate, sodium formate, sodium nitrate and potassium nitrate, with one or more chemical compounds being selected from the group of chemical compounds existing from tripotassium citrate, monoammonium phosphate, sodium hydrogen carbonate, sodium acetate and potassium carbonate.

25. The method according to any one of claims 21 to 24, wherein the composition that is applied to the wrapping base paper in step B, the thermal degradation of the cellulose accelerating substance in an amount of at least 3% and at most 30%, preferably at least 4 % and at most 25% and particularly preferably at least 5% and at most 20%, each based on the mass of the composition.

26. The method according to any one of claims 21 to 25, wherein the binding agent in the composition of step B is selected from the group consisting of starch, starch derivatives, cellulose derivatives, carboxymethyl cellulose, alginates, pectins, polyvinyl alcohol, guar and gum arabic or mixtures from it.

27. The method according to any one of claims 21 to 26, wherein the composition that is applied to the wrapping base paper in step B, the binder in an amount of at least 0.1% and at most 15%, preferably at least 0.3% and at most 12 % and particularly preferably at least 0.5% and at most 10%, each based on the amount of the composition.

28. The method according to any one of claims 21 to 27, in which in the course of drying in step C a solvent is largely removed from the composition, and the applied dried composition is then in an amount of at least 0.2 g / m ² and at most 8 g / m ² , preferably at least 0.5 g / m ² and at most 6 g / m ² and particularly preferably at least 1 g / m ² and at most 5 g / m ² , in each case based on the area on which the Composition was actually applied.

29. The method according to any one of claims 21 to 28, wherein the application of the composition in step B is done by printing or spraying, preferably by gravure or flexographic printing.

30. The method according to any one of claims 21 to 29, wherein the drying process in step C is carried out by contact with one or more heated cylinders, by contact with hot air, by infrared radiation, microwave radiation or combinations thereof.

31. The method according to any one of claims 21 to 30, wherein the method according to step C also comprises additional steps D and E, where in step D water is applied over the entire surface of the wrapping paper obtained in step C and in step E the wrapping paper from step D is dried, preferably by contact with one or more heated cylinders.