JP2021108574A - Heated aroma generating base material, heated aroma generating source using base material, heated aroma cartridge with its generating source and method for manufacturing base material - Google Patents

Abstract

To provide a heated aroma generating base material in which volatile matter is generated sufficiently and a smoker can satisfactorily enjoy smoke and aroma, and provide a heated aroma generating source using this, a hated aroma cartridge and a method for manufacturing the base material.SOLUTION: A heated aroma generating base material is mounted in heating type smoking equipment, and is heated and sucked up to form a heated aroma generating source of a heated aroma cartridge for generating aerosol and aroma. The heated aroma generating base material contains at least an aroma source material, an aerosol former and a heat melting substance, in which the aromatic thermal melting powder with the aroma source material mixed in the heat melting substance is dispersed uniformly in the heated aroma generating base material.SELECTED DRAWING: Figure 1-I

Description

The present invention is an inhomogeneous heated aroma generating group containing at least an aroma source material, an aerosol former, and a heat-melting substance, which generates an aerosol and an aroma by heat transferred by a heat source such as a heater instead of a flame. The present invention relates to a material, a heat-heated aerosol source using the base material, a heat-heated aerosol cartridge provided with the heat source, and a method for manufacturing the base material. In particular, a heat-heated fragrance-generating base material that is easily melted by a heat source, promotes the generation of aerosols and fragrances, has high toughness, and is excellent in molding processability, and a heat-heated fragrance-generating base material using the base material. The present invention relates to an aerosol cartridge to be heated provided with the source thereof, and a method for producing the base material thereof.

Conventionally, the above-mentioned "base material for generating aroma to be heated" is often referred to as "aerosol-forming base material", but together with an aerosol former that forms an aerosol by heating, an aromatic source material such as an aromatic plant or the like. Since the scent component of the fragrance is also volatilized and the smoke of the aerosol and the scent of the fragrance source material and the fragrance can be enjoyed by smoking, it is referred to as a "heated fragrance generating base material" in the present invention. Based on this, the "aerosol-forming body" filled with the aerosol-forming base material and the "electronic cigarette cartridge" provided with the aerosol-forming body are the "heated fragrance source" and the "heated fragrance cartridge", respectively. Is called.

In recent years, as the quitting of tobacco has become widespread in spaces where people gather, such as workplaces and restaurants, the number of people who smoke by burning tobacco with flames has decreased, while the heat transferred by heat sources such as heaters has decreased. Heats a heated fragrance cartridge with a heated fragrance source formed using a heated fragrance generating substrate, which contains an fragrance source material containing an aerosol former that generates aerosols, tobacco plants of the genus Tobacco of the family Tobacco. The number of people who smoke with formula smoking equipment is increasing rapidly. This is because the heat-not-burn smoking reduces the inhalation of harmful components generated by the thermal decomposition and combustion of conventional tobacco, and technological development on various products for enjoying the heat-not-burn smoking is actively carried out. (For example, Patent Documents 1 to 5).

The mechanism of such heated smoking differs depending on the form of the heated smoking device, the heated fragrance cartridge, and the like, and typical examples thereof are shown below. A heated fragrance cartridge having a heated fragrance source filled with a heated fragrance generating base material at one end and a mouthpiece at the other end brings the heated fragrance source into contact with the heat source of a heated smoking device. When attached and heated, the volatiles of the fragrance source material including the aerosol former and tobacco plants are released from the fragrance source to be heated, and at the same time, the volatiles are released together with the air at the other end by the smoker's suction. It is sucked into the mouthpiece side. In this volatile transport process, the aerosol former volatiles cool and condense to form a smoky aerosol, while other volatiles fragrance the smoker's mouth and nose, resulting in this. You can enjoy smoking. Therefore, in the case of heat-not-burn smoking, the temperature is about 200 to 350 ° C., which can volatilize the aerosol former such as glycerin and propylene glycol contained in the aroma generating base material to be heated, that is, the degree to which thermal decomposition of tobacco leaves starts. Since smoking is possible at temperature and tobacco leaves do not burn, the generation of harmful substances is extremely low, and the amount of harmful substances inhaled by the smoker and passive smokers in the vicinity of the smoker is significantly reduced.

In order to further reduce harmful substances, a material design is applied to reduce the content of tobacco in the heated aroma generating base material constituting the heated aroma generating source. For example, as an alternative material to tobacco plants, a combination of non-tobacco plants that generate various fragrances, and even a nicotine-less cover that allows you to enjoy comfortable smoking with non-tobacco plants alone without using tobacco plants at all. A heated high fragrance generating base material has also been developed (Patent Document 5). On the other hand, effective utilization of materials and reduction of material costs are also aimed at by using tobacco stems, leaf pieces, dust and the like generated in the conventional tobacco manufacturing process.

On the other hand, in the case of flame-type smoking in which tobacco is burned by a conventional flame, a temperature exceeding 600 ° C is required for burning at least, and the maximum temperature may reach 900 ° C when smoking, which is a harmful substance of flame-type smoking. The amount of smoke generated is extremely large. However, because it contains no ingredients other than tobacco plants, burning tobacco provides enough smoke to satisfy the smoker's visual needs, nicotine, which is the source of smokers' dependence on tobacco, and a myriad of aromatic ingredients. Occurs in.

Due to the difference in the essential mechanism between the heated smoking and the flame smoking, the heated fragrance generating base material filled in the heated fragrance source constituting the heated fragrance cartridge corresponding to the cigarette is smoked. The material composition is such that not only the aroma and nicotine generated from tobacco plants, but also various aromas generated from non-tobacco plants, which people want, are suppressed.

First, as described above, an aerosol former for producing an aerosol that looks like smoke without burning is used as an indispensable material to form a base material for generating aroma to be heated.

In Patent Documents 1 to 5, a heated aroma generating base material is composed of the following materials that suppress not only aroma and nicotine generated from tobacco plants but also various aromas generated from non-tobacco plants. It is stated that it is.

Since the aerosol former, which is an essential component of the substrate for generating aroma to be heated, is a liquid such as glycerin or propylene glycol, a highly safe binder is used so that it can be retained even when mixed with tobacco plants and non-tobacco plants. It is used. Typical examples include polysaccharide-based natural polymers and cellulosic-based natural polymers. Further, cellulose fibers may be added so that the binding force thereof can be enhanced and the columnar heated aroma generating base material can be molded.

In addition to the same purpose, microcrystalline cellulose may be added as a molding agent in order to reduce shrinkage of the aromatic base material to be heated during drying and to improve its molding processability.

When fragrances for supplementing fragrance components, such as refreshing agents and nicotine, are used, they are not released until they reach the optimum temperature for smoking and are stably retained. It may also contain crosslinked polyvinylpyrrolidone, cyclodextrin, etc. that function as agents.

As described above, the heated fragrance generating base material forming the heated fragrance generating source provided in the heated fragrance cartridge in the heated smoking includes an aerosol former as a smoke component, a tobacco plant as an fragrance component, and a non-cigarette. Smokers must use a large number of materials other than plants and fragrances, such as binders, molding agents, and scavengers, that inhibit the generation and volatilization of smoke and fragrance components due to heating. It is not easy to generate smoke and aromas that can be enjoyed.

As a method for solving this problem, in Patent Document 6, homogenization formed by a casting method from a slurry which is a dispersion of tobacco powder in a solution in which natural wax derived from a plant having a melting point of 50 to 150 ° C. is dissolved in an aerosol former is used. We are proposing a tobacco material, that is, a homogeneous aerosol-generating substrate. However, this method is considered to be insufficient, and Patent Document 7 proposes a solution for introducing a plant-derived oil at 20 to 50 ° C.

Japanese Patent Publication No. 2008-518614 Special Table 2010-520964 Special Table 2013-591384 Special Table 2016-538848 Japanese Patent No. 6280287 Patent No. 64333626 Patent No. 6442110

As described in the background technology, at least a heated fragrance cartridge corresponding to a cigarette and a heated smoking device in which a heated fragrance source and a mouthpiece are connected are used, and the heated fragrance source is heated. Smoking that is carried out by attaching it to the heat source of the cigarette is healthy because it sucks less harmful substances such as nicotine. However, the heated fragrance generating base material forming the heated fragrance generating source contains an aerosol former as a smoke component, and a tobacco plant, a non-tobacco plant, and a fragrance as a fragrance component. It is necessary to use a large number of materials such as agents, molding agents, and scavengers that inhibit the generation and volatilization of smoke components and aromatic components due to heating, and generate smoke and aromatics that smokers can fully enjoy. There is a problem that it is difficult.

Therefore, in the present invention, the heat source of the heat-not-burn smoking equipment is sufficient to release these volatile substances from the aerosol former as a smoke component and the fragrance source material and fragrance agent such as tobacco plant and non-tobacco plant which are fragrance components. A heated fragrance generating base material that is generated and allows smokers to enjoy smoke and fragrance with satisfaction, a heated fragrance generating source using the base material, a heated fragrance cartridge provided with the generation source, and the like. It is an object of the present invention to provide a method for producing a base material.

The present inventor uses a heat-heated fragrance-generating base material that forms a heat-heated fragrance source provided in a heat-heated fragrance cartridge, and a heat-melting substance containing an fragrance source material and / or an fragrance agent, that is, an aromatic heat-melting powder. It was thought that if the phase-separated structure was uniformly dispersed, the volatilization amount of the aromatic component and the smoke component could be increased by the following hypothesis.

First, the phase separation of the fragrance source material and / or the fragrance and the aerosol former makes each of them more likely to volatilize upon contact with the heat source. In particular, by unevenly distributing the fragrance source material and / or the fragrance agent that volatilizes the fragrance component by the heat source to the heat-melting substance, the fragrance source material and / or the fragrance agent can be used more than when it is present in the entire substrate for generating the fragrance to be heated. The concentration can be increased locally, and the aroma component can be efficiently volatilized by contact with a heat source. Secondly, due to the high thermal fluidity of the heat-melting substance, the volatile components of the fragrance source material and / or the fragrance generated therein move to the surface of the aroma generating substrate to be heated together with the aerosol former and volatilize. Is promoted. Thirdly, the heat-melting substance such as wax or wax has a weaker interaction with the aroma component than the aerosol former such as glycerin or propylene glycol, and the aroma component is easily released from the heat-melting substance.

On the other hand, the heat-melting substance can reliably fix the fragrance source material and / or the fragrance agent at room temperature, and can maintain the heterogeneous structure of the heated fragrance generating base material formed by phase separation from the aerosol former. I thought that it would also fulfill the important function of being able to do it. In particular, in order to maintain this heterogeneous structure, it was presumed that a heat-melting substance having a poor affinity for aerosol formers would be more preferable.

Based on such a hypothesis, as a result of various studies on the materials constituting the heated aroma generating base material, the manufacturing method, etc., the aroma source material, the aerosol former, and the heat-melting substance are contained at least, and the aroma source material and / or A subject provided with a heat-heated fragrance source wrapped with a heat-heated fragrance-generating base material having an inhomogeneous structure in which an fragrance heat-melted powder in which a fragrance is mixed with a heat-melting substance is dispersed in a heat-heated fragrance-generating base material. It has been demonstrated that the heated fragrance cartridge can fully enjoy the fragrance and smoke even when the composition excluding the heat-melting substance is the same as that of the conventional product in smoking using a general heating type smoking tool. At the same time, it was confirmed that the inhomogeneous structure of the aroma-generating substrate to be heated was stably maintained, and the present invention was completed.

That is, the present invention is a heated aroma generating base material which is attached to a heated smoking device and forms a heated aroma generating source of a heated aroma cartridge which is heated and sucked to generate an aerosol and aroma, and is an aroma source material. , Aerosolformer, and an aromatic heat-melted powder containing at least a heat-melting substance and in which an aromatic source material is mixed with the heat-melting substance, is uniformly dispersed in a heat-heated aroma-generating base material. It is a heated aroma generating base material.

The minimum outer diameter of this aromatic heat-melted powder is preferably 125 to 355 μm, more preferably 150 to 300 μm, and even more preferably 180 to 250 μm. If the outer diameter of the aromatic heat-melting powder is too large, its total surface area will be small, the chances of contact with the heat source will be reduced, the heat-melting material will be insufficiently melted, and the amount of volatilization of the aromatic component will be reduced. On the other hand, if the outer diameter of the aromatic heat-melted powder is too small, it is difficult to form a sea-island structure in which the powder is uniformly dispersed on the aroma generating substrate to be heated, and the powder exists as an agglomerated mass. , A region where the melting rate is reduced due to contact with the heat source is created, and the amount of volatile components of the aroma component is reduced.

The blending ratios of the fragrance source material, the aerosol former, and the heat-melting substance are 55 to 75% by mass, 20 to 40% by mass, and 50 to 40% by mass, respectively, in order to balance the volatile amounts of the smoke component and the fragrance component. It is preferably 2 to 15% by mass, more preferably 60 to 70% by mass, 25 to 35% by mass, and 3 to 10% by mass.

The heat-melting substance that plays an important role in such a base material for generating aroma to be heated is particularly limited as long as it is an "organic compound that exhibits a melting point or a softening point when heated and becomes a non-Newtonian fluid". It's not a thing. Organic compounds generally called waxes and waxes are preferable, and petroleum-based natural waxes, synthetic waxes, plant-based natural waxes, and animal-based natural waxes, which are typical waxes and waxes, can be used. In addition, various tack fires (adhesive imparting agents) to which rosin, which is also used as wax and wax, belong can be used. These can be used alone or as a mixture containing at least one selected from them.

Since the petroleum-based natural wax is a hydrocarbon compound, the interaction with the aromatic component and the aerosol former is small, so that the wax is not particularly limited, and vaseri, paraffin wax, and microcrystalline wax may be preferably used. can. However, they have different properties based on their molecular structure. Vaseline is a mixture of branched hydrocarbons and alicyclic hydrocarbons, and has a wide melting point range of 36 to 60 ° C. Most paraffin waxes are mainly composed of linear hydrocarbons, have high crystallinity, and have a melting point of 40 to 70 ° C., and have a narrow melting point range. Microcrystalline wax is a mixture of branched hydrocarbons and saturated cyclic hydrocarbons. It has low crystallinity but high molecular weight, and has the highest melting point of 60 to 90 ° C., which is second only to petrolatum. wide. As described above, all of them are hydrocarbon compounds extracted from crude oil, but paraffin wax and microcrystallin wax have low melt viscosity at the time of heat melting, and have low surface energy and mutual interaction with aromatic components and aerosol formers. Since it has little action, it is most suitable as a heat-melting substance for a base material for generating aroma to be heated.

Examples of such paraffin wax include Paraffin Wax-115, 120, 125, 130, 135, 140, 145, 150, and 155, which are standard products manufactured by Nippon Seiro Co., Ltd. Is also preferably used. In addition, special paraffin wax, for example, HNP series products, which are high-purity refined paraffin wax manufactured by Nippon Seiro Co., Ltd., SP series products for specific applications, and isoparaffin manufactured by a special manufacturing method. EMW series products containing paraffin as the main component are also preferably used. Further, as the microcrystalline wax, for example, any of the Hi-Mic series manufactured by Nippon Seiro Wax Co., Ltd. is preferably used.

Synthetic waxes include Fischer-Tropsch wax, polyethylene (PE) wax and modified PE wax, polypropylene (PP) wax and modified PP wax, fatty acid amide, fatty acid, fatty alcohol, polyoxyalkylene glycol, polyoxy. Polyethylene alkyl ether and polyoxyethylene alkyl amine can be preferably used.

In particular, since Fisher-Tropschwax is a linear hydrocarbon-based organic compound, it has a low melt viscosity during thermal melting, has a low surface energy, and has a small interaction with aerosol formers and aromatic components. Suitable as a heat-melting substance for materials. Sasоl standard product H1 etc. (melting point: about 112 ° C), medium melting point product C80 etc. (melting point: about 85-88 ° C), high melting point product C105 / H105 etc. (melting point: about 117 ° C), and BYK CERAFAK (Registered trademark) 117 (melting point: about 110 ° C.), 127N (melting point: about 120 ° C.) and the like can be used.

Further, PE wax and modified PE wax, and PP wax and modified PP wax are also hydrocarbon compounds and can be preferably used. Specifically, High Wax (registered trademark) manufactured by Mitsui Chemicals, Inc., Sun Wax and Viscol manufactured by Sanyo Chemical Industries, Ltd., CERAFAK (registered trademark) manufactured by BYK, 929, 950, 913, 914, and 915 and the like have a melting point of about 94 to 161 ° C. and can be preferably used. In particular, the metallocene-catalyzed polyolefin wax is more preferable because it has a narrow molecular weight distribution. For example, Excelex (registered trademark) manufactured by Mitsui Kagaku Co., Ltd., which is a metallocene-catalyzed PE wax, has a melting point of 89 to 128 ° C. due to its narrow molecular weight distribution and composition distribution, but has a low melt viscosity during thermal melting. It is very excellent as such a polyolefin wax.

As the fatty acid amide, monoamide and bisamide are suitable. As the monoamide, stearic acid monoamide, oleic acid monoamide, and erucic acid monoamide have a melting point of about 72 to 105 ° C. and are preferable. As the bisamide, ethylene bisstearic acid amide and ethylene bisoleic acid amide are preferable because they have a melting point of about 140 to 145 ° C. Although such amides have polar groups, they have a lower molecular weight and no molecular weight distribution, so they have a lower thermal melt viscosity than plant-derived waxes and oils, further promoting the movement of aerosol formers. For example, monoamide is NOF Corporation's Alflo (registered trademark) S-10, E-10, and P-10, and bisamide is NOF Corporation's Alflo (registered trademark) H series and AD series. And Kao Wax EB series manufactured by Kao Corporation can be used.

As fatty acids, capric acid, lauric acid, myristic acid, pentadecylic acid, palmitic acid, margaric acid, stearic acid, arachidic acid, behenic acid, lignoceric acid, and melissic acid have a melting point of about 30 to 94 ° C. It is preferably used. For example, capric acid, lauric acid, myristic acid, palmitic acid, stearic acid, and behenic acid are more preferable because they are industrially produced by NOF CORPORATION and the like.

The aliphatic alcohols include lauryl alcohol, tridecyl alcohol, myristyl alcohol, pentadecyl alcohol, cetyl alcohol, 1-heptadecanol, stearyl alcohol, setostearyl alcohol, ellaidyl alcohol, nanodecyl alcohol, arachidyl alcohol, and Heneiko. Sanol, behenyl alcohol, lignoceryl alcohol, ceryl alcohol, 1-heptacosanol, montanyl alcohol, 1-nonacosanol, and myricyl alcohol have a melting point of about 23 to 87 ° C. and are preferably used. For example, lauryl alcohol, myristyl alcohol, cetyl alcohol, stearyl alcohol, and cetostearyl alcohol are more preferable because they are industrially produced by Nichiyu Co., Ltd. and the like.

Such higher fatty acids and higher fatty alcohols have a carboxyl group and a hydroxyl group bonded to the terminal of a linear hydrocarbon, respectively, and have no molecular weight distribution or have an extremely narrow molecular weight distribution. Therefore, paraffin is used. Like wax, it has a low melt viscosity during heat melting and a narrow melting point range, so it has a great effect of promoting deformation and flow during heating of the aroma generating substrate to be heated.

As the polyoxyalkylene glycol, those having an average molecular weight of polyethylene glycol of 600 to 11,000 are preferable because they have a low melting point and a low melt viscosity during hot melting. Further, a polyethylene glycol-polypropylene glycol block polymer having a polyethylene glycol unit of 40 to 80 wt% and an average molecular weight of 3,000 to 13,000 has a melting point of about 20 to 60 ° C. Glycol is preferable. Although it is also used as a nonionic surfactant, it has a narrow molecular weight distribution and a narrow melting point, so that it has excellent fluidity during thermal melting.

As the polyoxyethylene alkyl ether, those having an average molecular weight of 1,000 to 4,000 of polyoxyethylene-monomethyl ether have a melting point of about 40 to 55 ° C. and are preferable. This is also used as a nonionic surfactant, but it has a narrow molecular weight distribution and a narrow melting point, so that it has excellent fluidity during thermal melting.

As the polyoxyethylene alkylamine, for example, NOF Corporation Nymeen (registered trademark) S204, which has a melting point of about 25 ° C. of polyoxyethylene-stearylamine, for example, NOF Corporation, which has a melting point of about 45 ° C. NOF Corporation (registered trademark) S202 is preferably used. Although these are also used as nonionic surfactants, they have a linear hydrocarbon unit having 18 carbon atoms, have a narrow molecular weight distribution, and have a narrow melting point range, so that they are used during thermal melting. Excellent fluidity.

The plant-based natural wax and the animal-based natural wax are also not particularly limited, but the plant-based natural wax is preferably goby wax, urushi wax, carnauba wax, sugar cane wax, palm wax, and candelilla wax, and is animal-based. As the natural wax, beeswax, whale wax, Ibota wax, wool wax, and shelac are preferable. This is because they have a relatively high melting point, can stably fix the fragrance source material and / or the fragrance agent, and have high thermal fluidity.

However, plant-based natural wax and animal-based natural wax are mainly composed of esters of fatty acids and aliphatic alcohols, but are a mixture of esters of fatty acids having various carbon atoms and aliphatic alcohols, and are free fatty acids and esters. It also contains free aliphatic alcohols and hydrocarbons, and has a wide molecular weight distribution, so it has a wide melting temperature range, high viscosity during melting, and organic compounds with ester bonds, free fatty acids, and free fats. Since it contains group alcohol, it has a large interaction with the aerosol former and aromatic components. Therefore, natural petroleum wax, synthetic wax, and rosin and rosin derivatives, which are tackifiers described later, are more heat-melting substances. preferable.

As the tack fire, rosin and rosin derivatives, and terpene resin and modified terpene resin can be preferably used. Specifically, as the rosin and the rosin derivative, gum rosin, rosin ester (Pencel), maleic acid-modified rosin resin, and rosin-modified phenol resin (Tamanol) manufactured by Arakawa Chemical Industry Co., Ltd. are preferable. The terpene resin and the modified terpene resin are terpene monomer homopolymerized resin (YS resin PX and YS resin PXN) manufactured by Yasuhara Chemical Co., Ltd., aromatic modified terpene resin (YS resin TO), and terpene phenol resin (YS Polystar series). ) Is preferably used. In particular, rosins and rosin derivatives having low interaction with aromatic components and aerosol formers and having high thermal fluidity are more preferable, and rosins are even more preferable.

As described above, there are a wide variety of heat-melting substances, but in order to uniformly disperse the aromatic heat-melting powder in the aroma-generating substrate to be heated of the present invention, it is particularly a hydrocarbon-based organic compound. , Petroleum-based natural wax, Fisher-Tropsch wax, PE wax and modified PE wax, PP wax and modified PP wax, and rosin and rosin derivatives are preferable. Of these, paraffin wax, microcrystalline wax, Fisher-Tropsch wax, PE wax, PP wax, and metallocene-catalyzed polyolefin wax are particularly preferable from the viewpoint of melting point and thermal fluidity.

Although these heat-melting substances have a melting point and a softening point, they have a melting point of 20 from the viewpoint of securely fixing the fragrance source material and / or the fragrance at room temperature and heat fluidity when they come into contact with the heat source. Those in the temperature range of ~ 200 ° C. are preferable, and those in the temperature range of 50 to 200 ° C. are more preferable.

Further, it is more preferable that the melting point of the heat-melting substance is in the temperature range of 150 to 200 ° C. This is considered to be due to the following reasons. The heated aroma generating base material in which the aromatic heat-melted powder of the present invention is uniformly dispersed is also molded into a columnar shape as in the conventional case, and is filled and wound in a packaging material so as to be in contact with the side surface thereof. A heated aroma source is formed and provided in the heated aroma cartridge. When a heated fragrance cartridge is attached to a heated smoking device to smoke, the heat source is inserted into such a heated fragrance source and heated, so that the heat source is uniformly dispersed in the heated fragrance generating base material. When the melting point of the heat-melting substance of the aromatic heat-melting powder is low, the aroma-generating substrates to be heated are fused to each other, and the gas flow path is blocked. Therefore, the melting point of the heat-melting substance is preferably 150 to 200 ° C. in order to secure the suction amount of the volatilized smoke component and aromatic component up to the vicinity of the maximum temperature reached by the heat source.

As described above, few waxes and waxes have a melting point of 150 to 200 ° C., and are limited to PP waxes and modified PP waxes, and rosin derivatives and modified terpene resins. PP wax and modified PP wax are particularly preferably used because they have excellent thermal fluidity. Specific examples of the PP wax and the modified PP wax include NP500 of High Wax (registered trademark) manufactured by Mitsui Chemicals, Inc., CERAFAK (registered trademark) 913, 914, and 915 manufactured by BYK. These have a melting point of about 160 ° C. and can be preferably used. Examples of the rosin derivative include rosin esters (Pencel) D-160 and KK manufactured by Arakawa Chemical Industry Co., Ltd., and rosin-modified phenolic resin (Tamanol) manufactured by Arakawa Chemical Industry Co., Ltd. Examples of the modified terpene resin include YS Polystar T160 and YS Polystar G150 manufactured by Yasuhara Chemical Co., Ltd.

On the other hand, fragrance sources are, in particular, Chinese tea, tea, roses, plants of the genus Peppermint, lavender, and saffron flowers, and underground stems of mint, eshalot, garlic, onion, and konjak. , And Karin, plants of the genus Peppermint (Mentha, Peppermint, Peppermint, Hassaku, Iyokan, Echan Lemon, Karatachi, Orange, Mandarin Orange, Cabos, Kishumikan, Kinotte, Grapefruit, Koji, Sanbokan, Citron, Jabara, Sudachi, Tachibana, Tangor, Natsumikan, Hanayuzu, Hyuga Natsu, Hirami Lemon (Shikuwasa), Buntan (Zabon), Yuzu, Lime, Lemon, Kobumikan, etc.) , Melon, pomegranate, horse, apricot, blueberry, rose family Dutch strawberry genus plant, raspberry, banana, and grape fruit, and peppermint family plant (peppermint, Japanese mint, apple mint, water mint, Corsica mint, Pennyroyal mint, etc.), Sparemint plants of the genus Peppermint (Sparemint, Horsemint, Midorihakka, Chirimenhakka, Gingermint, etc.) , And, including, but not limited to, including at least one selected from the above-ground foliage of plants of the mint family of Peppermint to provide a pleasant aroma to smokers. ..

However, the fragrance defined as the scent drifting from the heated fragrance cartridge itself when the heated fragrance cartridge is attached to the heated smoking equipment, the aroma defined as the scent drifting in the space when the heated fragrance cartridge is heated, and the heated fragrance. It is preferable to combine the three elements of flavor, which is defined as the scent that drifts in the mouth when the fragrance cartridge is heated and sucked together with the aerosol.

As a fragrance, at least one selected from Chinese tea, black tea, roses, plants of the genus Oleaceae of the family Oleaceae, lavender, saffron flowers, and above-ground foliage of plants of the genus Nicotiana tabacum of the Solanaceae family. It is preferable to include the above.

The aroma preferably contains at least one selected from the rhizomes of scallions, shallots, garlic, onions, konjac, and the above-ground foliage of plants of the Solanaceae Bemisia tabacum.

Flavors include Karin, a plant belonging to the genus Mentha of the family Mentha (Daidai, Unshuumikan, Natsudaidai, Peppermint, Hassaku, Iyokan, Echan Lemon, Karatachi, Orange, Mandarin Orange, Kabos, Kishumikan, Kinotte, Grapefruit, Koji, Sanbokan, Citron.・ Jabala ・ Sudachi ・ Tachibana ・ Tangoru ・ Natsumikan ・ Hanayuzu ・ Hyuga Natsu ・ Hirami Lemon (Shikuwasa) ・ Buntan (Zabon) ・ Yuzu ・ Lime ・ Lemon ・ Kobumikan etc. Kinkan, melon, pomegranate, horse, apricot, blueberry, rose family Dutch strawberry plant, raspberry, banana, and grape fruit, and peppermint family plant (peppermint, Japanese peppermint, apple mint, water mint) , Corsica mint, Pennyroyal mint, etc.), Sparemint plants of the genus Peppermint (Sparemint, Horsemint, Midorihakka, Chirimenhakka, Gingermint, etc.) ), And at least one selected from the above-ground foliage of plants of the genus Mentha.

As the aerosol former, propylene glycol, ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, glycerin, monoacetin (glycerin monoacetate), diacetin (glycerin diacetate) and the like can be used. Among them, containing at least one selected from propylene glycol, ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, and glycerin appears to be volatile due to contact with a heat source and smoke during cooling. It has excellent aerosol forming properties and is particularly preferable.

Further, it is preferable to further contain an fragrance agent for the purpose of assisting the fragrance source material, and it is more preferable that the fragrance source material is mixed with the heat-melting substance together with the fragrance source material. As the fragrance, at least one or more selected from a refreshing agent and nicotine can be used. In particular, the refreshing agent is important as a flavor and is important as a flavor: menthol and menthol derivatives, menthone and menthone derivatives, menthanecarboxylic acid amides, 2,3-dimethyl-2- (2-propyl) -butyric acid derivatives, menthane and menthane derivatives, L. -Carvone, xylitol, eucalyptus essential oil, peppermint oil, spearmint essential oil, and spiranthol are preferred. The amount of this fragrance may be 3 to 25 parts by mass with respect to 100 parts by mass of the total amount of the fragrance source material, the aerosol former, and the heat-melting substance, but when 5 to 20 parts by mass is contained, the fragrance of the fragrance source material is contained. It is more preferable because the components can be supplemented and there is no adverse effect such as a decrease in the strength of the aroma generator to be heated.

As described above, the material constituting the aroma generating base material to be heated can improve the sensory functions such as smoke and aroma generated in contact with the heat source. It is necessary that the heated aroma generating base material has a mold releasability from a molding machine that comes into contact with the heated aroma generating base material and prevents damage such as breakage of the heated aroma generating base material in the molding process. be. Further, it is required to reduce the volume shrinkage after the molding process, prevent the base material for generating aroma generated to be heated from falling off, and maintain the optimum state of the gas flow path with time. Therefore, it is preferable to further contain a molding agent.

The molding agent is preferably microcrystalline cellulose, and in particular, its average particle size is preferably 70 to 120 μm. When the average particle size of the microcrystalline cellulose is 70 μm or less, it is not possible to prevent the adhesion between the heated aroma generating base material and the molding machine as well as the effect of suppressing the shrinkage of the heated aroma generating base material, and 120 μm. With the above, there is no problem in the releasability between the heat-heated aroma-generating base material and the molding machine, but the heat-heated aroma-generating base material is likely to break. The mass average molecular weight (Mw) of the microcrystalline cellulose is preferably 20,000 to 60,000. If it is 20,000 or less, there is no effect of suppressing the shrinkage of the aroma generating base material to be heated, and if it is 60,000 or more, the aroma generating base material to be heated is easily broken and a problem occurs in the molding process. In the case of this molding agent, it may be 2 to 25 parts by mass with respect to 100 parts by mass of the total amount of the aromatic source material, the aerosol former, and the heat-melting substance, but by containing 3 to 20 parts by mass, the above-mentioned function can be obtained. At the same time, it is more preferable because it does not hinder the generation of volatile substances of the aromatic source material and the aerosol former.

Since the aroma generating base material to be heated contains at least an aromatic source material, an aerosol former, and a heat-melting substance, since the aerosol former is liquid, these are bound to maintain a lumpy state, and the above-mentioned molding process is performed. It is preferable that a highly safe binder is further used so as to solve the problem. Typical examples include polysaccharide-based natural polymers and cellulosic-based natural polymers, but cellulose can be molded into a columnar heated aroma-generating base material by further enhancing their cohesiveness. It is more preferable to add fibers.

As the polysaccharide-based polymer, konjak mannan (glucomannan), guar gum, pectin, carrageenan, tamarin seed gum, arabic gum, soybean polysaccharide, locust bean gum, karaya gum, xanthan gum, agar and the like can be used. From the viewpoint of strength and moldability, glucomannan, guar gum, pectin, carrageenan, tamarin seed gum, locust bean gum, karaya gum, and xanthan gum are preferable, and neutral polysaccharides glucomannan, guar gum, tamarin seed gum, and , Locust bean gum is more preferred.

Examples of the cellulose-based polymer include carboxymethyl cellulose (CMC), carboxyethyl cellulose, hydroxymethyl cellulose, hydroxyethyl cellulose, and hydroxypropyl cellulose, CMC sodium salt, potassium salt, and calcium salt, and carboxyethyl cellulose sodium salt. , Potassium salt and calcium salt can be used, but from the viewpoint of strength and moldability, CMC sodium salt and potassium salt, and carboxyethyl cellulose sodium salt and potassium salt are particularly preferable.

Polysaccharide-based polymers and cellulose-based polymers may be used in combination. In this case, glucomannan, guar gum, tamarin seed gum, and locust bean gum are used as the former, and sodium salt and potassium of CMC are used as the latter. It is preferable to use a salt and a sodium salt and a potassium salt of carboxyethyl cellulose from the viewpoint of strength and moldability.

Cellulose fibers are particularly preferably sugar cane, bamboo, wheat, rice, esparto, and jute cellulose fibers. This is because these fiber diameters and fiber lengths are in the range of 5 to 25 μm and 0.25 to 6 mm, respectively, and are thinner and shorter than the cellulose fibers of other plants, but the composition of the aroma generating base material to be heated. It has been found that the effect of binding the components is enhanced.

The binder is preferably 5 to 30 parts by mass with respect to 100 parts by mass of the total amount of the fragrance source material, the aerosol former, and the heat-melting substance, solves the strength and moldability, and volatilizes the fragrance source material and the aerosol former. In order to avoid adverse effects on the generation of substances, the amount is more preferably 8 to 28 parts by mass. As for the blending amount of the cellulose fibers, it is preferable that the ratio of the polysaccharide polymer and the cellulosic polymer to the cellulose fibers is 1: 1 to 1:25 in terms of the mass ratio from the viewpoint of the binding effect.

On the other hand, when the fragrance is introduced without being contained in the heat-melting substance in order to supplement the fragrance of the fragrance source material, the heat source of the heating type smoking equipment is the aerosol former which is a smoke component and the fragrance source material which is an fragrance component. The air freshener can volatilize and be released before it reaches the optimum temperature for volatilization. Therefore, it is necessary for the material to be heated to have the fragrance accumulating until the temperature reaches a predetermined temperature. Therefore, it is preferable to further contain a scavenger.

As described above, when the sorbent is a refreshing agent and nicotine, the cooling agent is preferably a hydrophilic crosslinked polymer or cyclodextrin, and the hydrophilic crosslinked polymer is preferably crosslinked polyvinylpyrrolidone (PVP). ) Adsorbs a chemical substance having a phenolic hydroxyl group, which is particularly preferable. In addition, the crosslinked PVP has a nitrogen-containing 5-membered heterocyclic compound similar to nicotine in the structure, and it is considered that an interaction between the two is formed. Therefore, the crosslinked PVP can also be crosslinked as a nicotine scavenger. PVP is suitable. On the other hand, α, β, and γ-cyclodextrin are known to form clathrate compounds with chemical substances having hydroxyl groups and carboxyl groups of various sizes. In particular, β-cyclodextrin is associated with menthol. It forms clathrate compounds and is ideal as a clathrate for menthol.

In the case of crosslinked PVP, the amount of such a scavenger may be 4 to 25 parts by mass, but 5 to 20 parts by mass, based on 100 parts by mass of the total amount of the aromatic source material, the aerosol former, and the heat-melting substance. In the case of cyclodextrin, it may be 0.1 to 1.2 parts by mass, but 0.2 to 1.0 parts by mass is more preferable. And it is more preferable to include both.

Finally, a dried and insecticidal aroma source material is used, but in order to store the heated aroma generating cartridge for a long period of time, it is necessary to include a preservative in the heated aroma generating base material. In particular, potassium sorbate and / or sodium benzoate is suitable for the substrate for generating aroma to be heated of the present invention, and in this case, with respect to 100 parts by mass of the total amount of the aroma source material, the aerosol former, and the heat-melting substance. , 0.005 to 0.04 parts by mass is preferably contained.

The heated fragrance generating base material described above constitutes a heated fragrance generating source on the insertion side of the heated fragrance cartridge to be attached to the heated smoking equipment, and the heated fragrance generating source is provided in the heated fragrance cartridge. The present invention also provides a heated fragrance source formed by using the heated fragrance generating base material, and a heated fragrance cartridge using the heated fragrance generating source.

First, a heated fragrance generating source formed by using a heated fragrance generating base material will be described. The heated fragrance generating source may be at least an aggregate of the heated fragrance generating base material, but the needle-shaped heat source is easily pierced into the heated fragrance generating source, and a flow path of the gas to be sucked is secured. Must be formed. Therefore, the heated aroma generating source of the present invention is characterized in that a columnar material obtained by molding a heated aroma generating base material is filled and wrapped in a packaging material so as to come into contact with the side surface thereof. The shape is not particularly limited, such as columnar, prismatic, granular, scaly, etc., but columnarity is preferable in order to satisfy the function required for the aroma source to be heated, and is prismatic. Is more preferable. Further, it is more preferable that the aggregate is in contact with the side surface of the columnar body or the prismatic body. As a result, when the heated fragrance is attached and detached, the heat source easily pierces the heated fragrance source without the heated fragrance generating base material falling off, and the gas flow path is formed in the direction in which the smoke component and the fragrance component flow. It is secured and comfortable smoking is possible.

Considering the installation of the heated fragrance cartridge, the heated fragrance generating source in which the aggregate of the heated fragrance generating base material is wound by the heated fragrance generating base material wrapping member which is a tubular scroll is , Easy to handle and preferable. In addition, this heated fragrance generating source prevents the heated fragrance generating base material from the heated fragrance generating source, the collapsed material of the heated fragrance generating base material, and the dust generated by the collapsed material from falling off and scattering. But it is preferable. In particular, if the aggregate that comes into contact with the side surface of the columnar or prismatic heated aroma generating base material is a heated aroma generating source wrapped with a heated aroma generating base material wrapping member, the heat source can be easily inserted. , A gas flow path can be secured, which is more preferable.

Next, the heated fragrance cartridge provided with the above-mentioned heated fragrance source of the present invention will be described. In one of the heated fragrance cartridges having a simple structure of the present invention, the heated fragrance source is housed in a tubular body of the heated fragrance cartridge exterior member, and the heated fragrance source is excluded from the exterior of the heated fragrance cartridge. It is characterized in that the tubular space of the member is formed as a mouthpiece. Further, one of the heated fragrance cartridges having a simple structure of the present invention is a tubular mouthpiece in contact with the heated fragrance source together with the heated fragrance source, which is a tubular body. The feature is that it is housed in the cartridge exterior member.

This is a form peculiar to a heated fragrance cartridge that smokes using a heated smoking device. In the case of cigarettes, almost every part of the cigarette that is added by mouth is equipped with a filter member that functions as a mouthpiece, which filters the solid components of the burned smoke and nicotine. It plays a role of adsorbing cigarettes and tar to give it a mellow taste. However, the heated fragrance cartridge using the heated smoking equipment does not burn the heated fragrance source, and enjoys the aerosol smoke in which the fragrance of the heated fragrance source and the volatile matter of the aerosol former are cooled. In addition, the smoke does not contain solid components, and since there are few or no tobacco plants in the aromatic source material, there is little nicotine and tar, and the mouthpiece does not require a filter function. The mouthpiece of the heated fragrance cartridge provides a gas flow path with moderate hardness that makes the lips and tongue feel good and easy to hold, without feeling the heat from the heat source when the smoker smokes in the mouth. The tubular body and the columnar body are not particularly limited as long as they are provided. Therefore, with the above-mentioned heated fragrance cartridge of the present invention, it is possible to enjoy sufficiently comfortable smoking.

However, it is necessary to prevent the heated fragrance generating base material and the heated fragrance generating source from moving toward the mouthpiece side by inhaling during smoking, and the smoke fluctuation that amplifies the enjoyment of smoking should be sufficiently drifted. Is desired. Therefore, the mouthpiece, which is a tubular space of the exterior member of the aroma cartridge to be heated, and the tubular mouthpiece, which is in contact with the aroma generating source, are attached to the aroma generating substrate and the aroma source, which are heated. It is preferable to include a support member that prevents movement to the piece side or an aerosol by cooling the volatile matter of the aerosol former, that is, a cooling member that promotes the generation of smoke. Further, in consideration of the habit of cigarette lovers, it is preferable to provide a filter member.

The structure of such a support member is limited as long as it has a surface that comes into contact with the source of the aroma to be heated and passes through the gas, and a surface that supports the surface and has at least a gas flow path such as a through hole. It's not something. Further, the structure of such a cooling member includes, for example, a porous body of open cells, a honeycomb structure, and the like having a gas flow path having a large contact area with volatile substances, but is limited to these. It's not a thing.

The material is not particularly limited, but in the case of the support member, paper, plastic, rubber, wood, metal, ceramic, etc. can be used, but it is molded into various shapes. It is more preferably made of possible plastic. The plastic may be either a thermoplastic resin or a thermosetting resin, and may be a polyolefin resin, a polyester resin, a polystyrene resin, a nylon resin, an acrylic resin, a silicon resin, a fluorine resin, or a polyurethane resin. Resins, ethylene-vinyl acetate (EVA) -based resins, phenol-based resins, amino-based resins, ABS-based resins, biodegradable plastics, etc. can be used, but they will eventually become waste, so it is called natural environment protection. From the viewpoint, it is a biodegradable plastic such as poly (3-hydroxybutyrate) (PHB), poly (ε-caprolactone) (PCL), poly (butylene succinate) (PBS), and polylactic acid (PLA). Is desirable.

In the case of a cooling member, a metal compound or the like having excellent thermal conductivity is preferable, but since it is inferior in molding processability and expensive, it is inferior in thermal conductivity but excellent in productivity and cost. , Polyester resin, Polystyrene resin, Nylon resin, Acrylic resin, Silicon resin, Fluorine resin, Polyurethane resin, EVA resin, Phenolic resin, Amino resin, ABS resin, and biodegradability Although plastics and the like can be used, biodegradable plastics such as PHB, PCL, PBS, and PLA are desirable from the viewpoint of protecting the natural environment.

As is clear from such a structure and material, the support member and the cooling member also have the functions of the cooling member and the support member, respectively, but the mouthpiece includes at least the support member and the cooling member to support the mouthpiece. It is more preferable that the member and the filter member are arranged in this order in the longitudinal direction from the side of the source of the aroma to be heated because they can have both functions.

However, as mentioned above, since almost all cigarettes are equipped with a filter member, the habits of cigarette lovers are extremely important, and at least the mouthpiece equipped with the filter member is brought into contact with the heated aroma source. Is preferable. Since this filter member can also function as a support member and a cooling member like the support member and the cooling member, it can be used alone. In this case, it is more preferable that the filter member is filled in the entire mouthpiece that is in contact with the heat aroma generation source because the functions of the filter member, the support member, and the cooling member can be effectively exhibited. ..

Such filter members are typical such as a plain filter using cellulose acetate fiber used in conventional cigarettes, a dual charcoal filter containing activated charcoal in the plain filter, and an AFT (Advanced Filter Technology) having irregularities on the filter surface. A cigarette filter can be used, but the type and structure of the fiber are not limited as long as the filter has the air permeability required for smoking. From the viewpoint of protecting the natural environment, it is preferable that the filter member uses plant fibers such as hemp and wood, and biodegradable plastic fibers such as PHB, PCL, PBS, and PLA. In addition, a fragrance, a microcellized fragrance, and the like may be included.

As described above, when the filter member independently provided on the mouthpiece comes into contact with the heated fragrance source, the function of the support member is exhibited, but the heated fragrance generating base material and the heated fragrance generating source are the filter members. It is preferable that at least one of a support member and a cooling member is interposed between the heated aroma generation source and the filter member in order to clog the eyes. In order to maximize the function of preventing the movement of the heated fragrance generating base material and the heated fragrance generating source from the heated fragrance generating source to the mouthpiece side, the supporting member or the cooling member also has the heated fragrance. It is preferable to come into contact with the source.

Further, in order to have all the functions required for the mouthpiece and to effectively exhibit the functions, the mouthpiece includes at least a support member, a cooling member, and a filter member, and the support member, the cooling member, and the mouthpiece are provided. It is more preferable that the filter members are arranged in this order in the longitudinal direction from the side of the aroma source to be heated.

On the other hand, in the heated fragrance cartridge, which is characterized in that the mouthpiece is attached in the longitudinal direction of the heated fragrance source and is housed in the outer member of the heated fragrance cartridge which is a tubular body. It is preferable that the heating aroma generation source, the support member, the cooling member, and the filter member constituting the mouthpiece are wrapped with a mouthpiece wrapping member which is a tubular scroll. This is because if the heat fragrance source, the support member, the cooling member, and the filter member constituting the mouthpiece have the same shape, these can be easily stored in the heat fragrance cartridge exterior member, and productivity is improved. To do. In particular, with respect to the heat-heated aroma generating source, the workability is greatly improved by wrapping the mouthpiece wrapping member, and as described above, the heated aroma-generating base material and the heated aroma-generating base material are used. The collapsed material and the dust generated by the collapsed material are reduced from falling off and scattered.

Here, there are the following three forms in which the support member, the cooling member, and the filter member constituting the mouthpiece are wound by the mouthpiece wrapping member which is a tubular scroll. First, the support member, the cooling member, and the filter member are individually wrapped with the mouthpiece wrapping member, and second, the support member and the filter member, and the support member and the cooling member, and The cooling member and the filter member are wound and integrated with the mouthpiece wrapping member, and the third, the support member, the cooling member, and the filter member are wound and integrated with the mouthpiece wrapping member. ..

As a typical example of such a mouthpiece ramping member, wrapping paper made of plant fibers such as hemp and wood used in conventional cigarettes can be mentioned, but unlike cigarettes, it burns. Therefore, a plastic film or the like that can be rolled up can also be applied, and the material is not particularly limited. General-purpose resin films such as polyolefin resins, polyester resins, nylon resins, EVA resins, and acrylic resins are preferably used. From the viewpoint of protecting the natural environment, wrapping paper made of plant fibers, PHB, and PCL are used. , PBS, and biodegradable plastic films such as PLA are more preferred.

Then, on the interface between the heated fragrance source and the mouthpiece, the heated fragrance generating base material, the collapsed material of the heated fragrance generating base material, and the dust generated by the collapsed material fall off and scatter. It is more preferable that a mesh for preventing the above-mentioned substances is provided in order to prevent the invasion of these foreign substances into the oral cavity by suction and the clogging of the filter member.

This mesh has a function of having a size of a hole that blocks the heat-treated fragrance-generating base material, the collapsed material of the heated fragrance-generating base material, and the dust generated by the collapsed material, and does not obstruct the passage of gas. It is not limited as long as it has a structure and a material. However, for example, plant fibers such as hemp and wood, and polyolefin-based resins, polyester-based resins, and nylon-based resins. It is preferable to use woven fabrics and non-woven fabrics made of synthetic fibers such as acrylic resins and having excellent breathability. From the viewpoint of protecting the natural environment, plant fibers and raw materials such as PHB, PCL, PBS, and PLA are used. It is desirable to use degradable plastic fiber as a material.

Further, on the surface of the opposite end surface of the mesh of the heat-not-burned aroma generating source, the heated aroma generating base material, the collapsed material of the heated aroma generating base material, and the dust generated by the collapsed material are inside the heated smoking equipment chamber. It is preferable that a cover for preventing the heat-not-burn smoking equipment from falling off and scattering is provided in order to prevent contamination and failure of the heat-not-burn smoking equipment. In particular, it is more preferable that the heat source insertion hole is provided at the opposite end of the mesh of the heat-not-burn aroma generation source because the heat source of the heat-not-burn smoking equipment must penetrate.

When the cover is provided with a heat source insertion hole, for example, plant fibers such as hemp and wood, and polyolefin-based resin, polyester-based resin, and nylon-based resin. Woven fabrics and non-woven fabrics made of synthetic fibers such as acrylic resin can be used to block the fragrance-generating base material to be heated, the collapsed material of the fragrance-generated base material to be heated, and the dust generated by the collapsed material. The structure and material are not limited as long as they have an opening of a size and have a function of not obstructing the passage of gas. From the viewpoint of protecting the natural environment, it is desirable to use plant fiber or biodegradable plastic fiber such as PHB, PCL, PBS, PLA as a material. However, if there is no heat source insertion hole, the heat source and the cover come into slight contact with each other, so it is preferable to use a woven fabric or non-woven fabric made of plant fibers such as hemp and wood and having excellent breathability.

In this way, the heated fragrance cartridge wrapped around the tubular body to be heated fragrance cartridge exterior member of the present invention uses a space other than the heated fragrance source charged in the heated fragrance cartridge housing member as a mouthpiece. In the case of mounting the heated fragrance source and the mouthpiece in the heated fragrance cartridge housing member, the heated fragrance source, the mouthpiece, and the support member constituting the mouthpiece are also used. , The cooling member, and the filter member can be replaced. Therefore, a heated fragrance cartridge provided with a heated fragrance cartridge housing member not only enjoys various smokes and fragrances by exchanging various types of heated fragrance sources, but also supports members, cooling members, and It is not necessary to replace the filter member until it deteriorates, which is economical.

The heated fragrance cartridge wrapped by the tubular body to be heated fragrance cartridge exterior member of the present invention can be finished into a tubular scroll as the heated fragrance cartridge exterior member of the tubular body. It is preferable to apply a heated fragrance cartridge wrapping member. The reason for this is that the heated fragrance source, the heated fragrance source and the mouthpiece are mechanically wound, and the heated fragrance cartridge is installed, so that the productivity of the heated fragrance cartridge is dramatically increased. Because it can be enhanced.

As a typical example of such a heated fragrance cartridge wrapping member, wrapping paper made of plant fibers such as hemp and wood used in conventional cigarettes can be mentioned, but unlike cigarettes, it is different from cigarettes. Since it does not burn, a plastic film or the like that can be rolled up can also be applied, and the material is not particularly limited. General-purpose resin films such as polyolefin resins, polyester resins, nylon resins, EVA resins, and acrylic resins are preferably used. From the viewpoint of protecting the natural environment, wrapping paper made of plant fibers, PHB, and PCL are used. , PBS, and biodegradable plastic films such as PLA are more preferred. However, when paper is used as the wrapping member for the fragrance cartridge to be heated and is used as a mouthpiece by itself, it is necessary to thicken the paper or increase the number of times the paper is wound.

Further, by using the heated fragrance cartridge exterior member of the tubular body of the heated fragrance cartridge of the present invention as the heated fragrance cartridge housing member which is a tubular housing, new advantages can be imparted. In this case, even if the heated fragrance cartridge has a space other than the heated fragrance source charged in the housing member as the mouthpiece, the heated fragrance source and the mouthpiece are combined with the heated fragrance. Even if the heated fragrance cartridge is installed in the cartridge housing member, it does not wind up like the heated fragrance cartridge wrapping member. Therefore, the heated fragrance source, the mouthpiece, and the support constituting the mouthpiece. It becomes easier to replace the member, the cooling member, and the filter member.

In order to fully exert such an advantage, the heating fragrance source and the mouthpiece, and the support member, the cooling member, and the filter member constituting the mouthpiece are repeatedly loaded and removed. There is a need for a heated fragrance cartridge housing member having a structure and material having a mechanical strength and a low friction coefficient. When paper is applied as the material of the housing member, a desired thickness corresponding to the mechanical strength is required, but it is preferable to apply plastic, wood, metal, ceramic or the like because it can be made thinner. Further, considering that it is molded into a tubular housing, plastic, wood, metal, ceramic, etc. are preferable to paper, and in particular, it is made of plastic having excellent molding processability. More preferred. The plastic may be either a thermoplastic resin or a thermosetting resin, and may be a polyolefin resin, a polyester resin, a polystyrene resin, a nylon resin, an acrylic resin, a silicon resin, a fluorine resin, or a polyurethane resin. Resins, ethylene-vinyl acetate (EVA) -based resins, phenol-based resins, amino-based resins, ABS-based resins, biodegradable plastics, etc. can be used, but from the viewpoint of protecting the natural environment, PHB, PCL, PBS, PLA, etc. can be used. It is desirable that it is a biodegradable plastic such as.

Further, by making the heated fragrance cartridge exterior member of the tubular body of the heated fragrance cartridge of the present invention a heated fragrance cartridge connecting member detachably connected at at least one place, various advantages can be obtained. It becomes possible to provide a heated fragrance cartridge.

First, the heated fragrance cartridge connecting member is divided into a heated fragrance source connecting portion capable of charging the heated fragrance source and a mouthpiece connecting portion capable of forming a mouthpiece. It is possible to provide a heated fragrance cartridge characterized in that a heated fragrance source connecting portion and a mouthpiece connecting portion, which are charged with a heated fragrance source, are detachably connected and installed.

In such a heated fragrance cartridge, the heated fragrance source connecting portion is removed and heated more easily than in the case where the heated fragrance cartridge exterior member is a heated fragrance cartridge wrapping member or a heated fragrance cartridge housing member. Since the fragrance source can be freely exchanged, it becomes possible to enjoy various fragrances and smoke according to the smoker's taste. Then, the connecting portion of the aroma generation source to be heated can be cleaned and used many times. Further, as described above, in the case of smoking the heated fragrance cartridge using a heated smoking tool, the mouthpiece is a tubular body that is easy for the smoker to smoke in the mouth. If it is, there is no particular limitation, so the mouthpiece connecting part is applied to the mouthpiece. Depending on the structure and material of the mouthpiece connecting part, the mouthpiece has an excellent touch with the lips and tongue and is easy to hold in the mouth. Can be formed. Further, by making the mouthpiece connecting portion a mouthpiece connecting portion into which the mouthpiece can be inserted, various mouthpieces suitable for the smoker's taste can be attached.

The mouthpiece to be charged into the mouthpiece connecting portion can also have the same preferable mode and form as the mouthpiece described above. That is, a mouthpiece having at least one selected from a support member, a cooling member, and a filter member, a support member, and a cooling member are provided, and the support member and the cooling member are provided from the side of the connecting portion of the heat aroma generation source. Is provided with at least a mouthpiece, a support member and a filter member, or a cooling member and a filter member, which are arranged in this order in the longitudinal direction, and the support member and the filter member or the cooling member and the filter member are provided from the side of the connecting portion of the aroma generating source to be heated. The mouthpieces are arranged in this order in the longitudinal direction, and at least the support member, the cooling member, and the filter member are provided, and the support member, the cooling member, and the filter member are provided from the side of the connecting portion of the aroma generating source to be heated. The mouthpieces are arranged in this order in the longitudinal direction. In this case as well, since the mouthpiece connecting portion can be removed, the mouthpiece can be attached and detached more easily than in the case of the heated fragrance cartridge wrapping member or the heated fragrance cartridge housing member.

The mouthpiece to be mounted in such a mouthpiece connecting portion is also a mouthpiece in which the support member, the cooling member, and the filter member are tubular scrolls so that the mouthpiece can be easily loaded by the mouthpiece connecting portion. It is preferably wrapped with a piece wrapping member. In this case as well, there are three types of winding, the first is a form in which the support member, the cooling member, and the filter member are individually wound by the mouthpiece wrapping member. The second is a form in which the support member and the cooling member, the support member and the filter member, and the cooling member and the filter member are wound and integrated with the mouthpiece wrapping member, and the third is the support member, the cooling member, and the filter. It is a form in which the members are wrapped with a mouthpiece wrapping member and integrated.

As described above, the mouthpiece to be charged into the mouthpiece connecting portion may have the same preferable modes and forms as those of the mouthpiece described above, and the same applies to the material. Therefore, the description of the material will be omitted.

Secondly, the mouthpiece connecting part is a support member connecting part in which a support member is charged, a cooling member connecting part in which a cooling member is charged, and a filter member connecting part in which a filter member is charged. At least two connecting portions selected from the support member connecting portion, the cooling member connecting portion, and the filter member connecting portion from the side of the heated fragrance generating source connecting portion. Can provide a heated fragrance cartridge, characterized in that the mouthpieces are arranged in this order in the longitudinal direction and are detachably connected to each other. In this case, since the support member connecting portion, the cooling member connecting portion, and the filter member connecting portion are detachably connected to each other, the support member, the cooling member, and the filter member are individually wrapped in the mouthpiece. It needs to be wrapped with a member.

That is, in this heated fragrance cartridge, the heated fragrance generating source connecting portion and the mouthpiece connecting portion are detachably connected, and further, the mouthpiece connecting portion has a support member from the heated fragrance generating source connecting portion. A heated fragrance cartridge in which the connecting portion of the supporting member to be loaded and the connecting portion of the cooling member to which the cooling member is loaded are detachably connected in this order in the longitudinal direction, supported from the connecting portion of the fragrance generating source to be heated. A heated fragrance cartridge and a heated fragrance source connecting portion in which a support member connecting portion in which a member is charged and a filter member connecting portion in which a filter member is charged are detachably connected in this order in the longitudinal direction. A heated fragrance cartridge and a heated fragrance generator in which the cooling member connecting portion in which the cooling member is charged and the filter member connecting portion in which the filter member is charged are detachably connected in this order in the longitudinal direction. The support member connecting part in which the support member is charged from the connecting part, the cooling member connecting part in which the cooling member is charged, and the filter member connecting part in which the filter member is charged can be attached and detached in this order in the longitudinal direction. At least four types of heated fragrance cartridges connected to can be provided.

In the form of the heated fragrance cartridge, not only the heated fragrance source connecting portion and the mouthpiece connecting portion are detachably connected, but also the support member connecting portion, the cooling member connecting portion, and the filter member connecting portion are connected. Since each part is detachably connected, not only can the mouthpiece be made according to the smoker's taste, but each part can be easily cleaned and only the worn out one can be replaced, which is economical. be.

Third, when the heated fragrance source connecting unit connects the heated fragrance source connecting unit and the mouthpiece connecting unit, the inside of the mouthpiece connecting unit is between the heated fragrance source and the mouthpiece. Provided is a heat-heated fragrance-generating base material, a collapsed material of the heat-heated fragrance-generating base material, and a mesh to prevent the dust generated by the collapsed material from falling off and scattering. can do.

Further, on the surface of the opposite end of the mouthpiece connecting portion of the heat-not-burned fragrance generating source connecting portion, the heated fragrance generating base material, the collapsed material of the heated fragrance generating base material, and the dust generated by the collapsed material are heated. A heat-not-burn fragrance cartridge can be provided, characterized in that it is provided with a cover that prevents it from falling off and scattering into the smoker chamber. In particular, it is preferable that the cover is provided with a heat source insertion hole for the heat-not-burn smoking equipment.

Further, it is also possible to provide a fragrance-heated cartridge characterized in that the mesh and the cover are provided in the connecting portion of the fragrance-generating source to be heated.

By providing the mesh and / or cover in the connecting portion of the aroma generating source to be heated in this way, not only these original functions are fulfilled, but also the connecting portion of the aroma generating source to be heated is easily heated without protruding. Aroma sources can be charged. In particular, it is preferable that the mesh and the cover are removable so that the heated aroma generation source can be easily taken in and out.

Since the connecting member is repeatedly attached and detached and has poor durability with paper, it is preferable to apply plastic, wood, metal, ceramic or the like having excellent mechanical strength. Further, considering that the tubular housing and the fitting portion are to be molded, plastic, wood, metal, ceramic and the like are preferable, and plastic having excellent molding processability is more preferable. The plastic may be either a thermoplastic resin or a thermosetting resin, and may be a polyolefin resin, a polyester resin, a polystyrene resin, a nylon resin, an acrylic resin, a silicon resin, a fluorine resin, or a polyurethane resin. Resins, ethylene-vinyl acetate (EVA) -based resins, phenol-based resins, amino-based resins, ABS-based resins, biodegradable plastics, etc. can be used, but from the viewpoint of protecting the natural environment, PHB, PCL, PBS, PLA, etc. can be used. It is desirable that it is a biodegradable plastic such as.

Each connecting portion described above, and the method of attaching / detaching the mesh and the cover are not particularly limited, but may be any of fitting, screwing, meshing, and hooking. It is preferable to have. Further, it is preferable that the attachment / detachment is easy even if a magnetic force is used regardless of the connection form.

As described above, the heated fragrance generating base material of the present invention, the heated fragrance generating source which is an aggregate thereof, the heated fragrance generating source in which the aggregate is wrapped with the heated fragrance generating base material wrapping member, and the subject The heated fragrance cartridge provided with the heated fragrance source has been described. However, the technique underlying the present invention is a heat-melting substance containing an fragrance source material and / or an fragrance agent in a heat-heated fragrance generating base material constituting the heated fragrance generating source provided in the heated fragrance cartridge. , The aromatic heat-melted powder has a uniformly dispersed phase-separated structure, which is based on the method for producing a heated aroma generating substrate of the present invention. In particular, the aroma generating substrate to be heated of the present invention is a material containing at least an aroma source material, an aerosol former, and a heat-melting substance, and the aroma source material does not dissolve, and the chemical properties of the aerosol former and the heat-melting substance are completely different. Therefore, it has been found that the following production methods suitable for these material properties are preferable. Hereinafter, the method for producing the heated aroma generating base material of the present invention will be described in detail.

The basic production method of the aromatic base material to be heated of the present invention is a mixed powder production step (AI) in which an aromatic source material and / or an aromatic agent and a heat-melting substance are mixed, and cellulose fibers are produced from a fiber plant. Cellulous fiber production step (B), material preparation step (CI) for preparing the desired material selected from aerosolformers, fragrances, molding agents, binders, preservatives, and water, and mixed powder production. A heated aroma generating base material manufacturing step (D) for producing a heated aroma generating base material from the materials manufactured in the step (AI), the cellulose fiber manufacturing step (B), and the material preparation step (CI). ), Which is a method for producing a base material for generating aroma to be heated.

More specifically, the mixed powder manufacturing process (AI) uses the aroma source material produced in the drying / insecticidal step (A-1) for drying / killing the aroma source material and the drying / insecticidal step (A-1). A crushed product produced in a crushing step (A-2) for crushing, a crushing step (A-5) for crushing a heat-melting substance, a crushing step (A-2), or a crushing step (A-2). A compression / shear mixing step (A-6) and a compression / shear mixing step (A-6) in which the crushed product and the fragrance produced and the crushed product produced in the crushing step (A-5) are compressed and sheared to be mixed. Each step of the cooling step (A-7) for cooling the mixture produced in 6) to 0 ° C. or lower and the pulverization step (A-8) for crushing the mixture cooled in the cooling step (A-7). It is characterized in that an aromatic source material / heat-melting substance mixed powder is produced. Further, the cellulose fiber manufacturing step (B) includes a squeezing step (B-1) for squeezing the fiber plant, a crushing step (B-2) for crushing the fiber plant that has undergone the squeezing step (B-1), and a crushing step (B). A boiling step (B-3) for boiling the crushed product produced in -2), a dehydration / drying step (B-4) for dehydrating / drying the boiled product produced in the boiling step (B-3), and Cellulous fibers are produced by a pulverization step (B-5) in which the dried product produced in the dehydration / drying step (B-4) is pulverized. Then, the material produced in the mixed powder manufacturing step (AI), the cellulose fiber manufacturing step (B), and the material preparation step (CI) is mixed in the heated aroma generating base material manufacturing step (D). Mixing step (D-1), compression / shearing step (D-2) of compressing / shearing the mixture produced in the mixing step (D-1) to form a sheet, and compression / shearing step. A cutting step (D-3) for cutting the sheet produced in (D-2) is included, and a base material for generating aroma to be heated is produced.

In particular, when the fragrance is contained in the heat-melting substance, it is preferable to adopt the following production method in order to make the fragrance uniformly present in the heat-melting substance. That is, a mixed powder manufacturing process (A-II) in which an aromatic source material, an aromatic agent, and a heat-melting substance are mixed, a cellulose fiber manufacturing step (B) in which cellulose fibers are produced from a fiber plant, an aerosol former, a molding agent, and a binder. A material preparation step (C-II) for preparing a desired material selected from an agent, a preservative, and water, a mixed powder manufacturing step (A-II), the cellulose fiber manufacturing step (B), and Each step of the heated aroma generating base material manufacturing step (D) for manufacturing the heated aroma generating base material from the material manufactured in the material preparation step (C-II) is included in the mixed powder manufacturing step (A-II). It has characteristics.

That is, in this mixed powder manufacturing step (A-II), the aroma source material produced in the drying / insecticidal step (A-1) for drying / killing the aroma source material and the aroma source material produced in the drying / insecticidal step (A-1) is crushed. The crushing step (A-2), the mixing step (A-3) in which the heat-melting substance and the fragrance are mixed at a temperature equal to or higher than the melting temperature of the heat-melting substance, and the mixture produced in the mixing step (A-3) are 0. With the crushed product produced in the cooling step (A-4) for cooling to ℃ or less, the crushing step (A-5) for crushing the mixture cooled in the cooling step (A-4), and the crushing step (A-2). The mixture produced in the compression / shear mixing step (A-6) and the compression / shear mixing step (A-6), in which the pulverized product produced in the crushing step (A-5) is compressed / sheared and mixed, is 0. It is characterized by including a cooling step (A-7) for cooling below ° C. and a crushing step (A-8) for pulverizing the mixture cooled in the cooling step (A-7). An agent / heat-melting substance mixture powder is produced. However, the cellulose fiber manufacturing step (B) is completely the same as the above-mentioned cellulose fiber manufacturing step, and the heated aroma generating base material manufacturing step (D) is also the same as the basic step, only the material is different. A mixing step (D-1) and a mixing step (D-1) for mixing the materials produced in the mixed powder manufacturing step (A-II), the cellulose fiber manufacturing step (B), and the material preparation step (C-II). The compression / shearing process (D-2) in which the mixture produced in) is compressed / sheared to form a sheet, and the cutting process in which the sheet produced in the compression / shearing process (D-2) is cut. This is a method for producing a base material for generating aroma to be heated, which comprises (D-3).

As described above, in the mixed powder manufacturing step (A-II), in the mixing step (A-3) and the mixing step (A-3) in which the heat-melting substance and the fragrance are mixed at a temperature equal to or higher than the melting temperature of the heat-melting substance. Aroma by passing through a cooling step (A-4) for cooling the produced mixture to 0 ° C. or lower and a crushing step (A-5) for crushing the mixture cooled in the cooling step (A-4). The agent can be reliably present in the heat-melting substance, and the functions of the heat-melting substance such as fixing and accommodating the fragrance and generating the fragrance component can be sufficiently exhibited.

The inhomogeneous heated aroma generating base material manufacturing step (D) is a compression / shearing step (D-2).
This is a method for producing a sheet of a base material for generating an inhomogeneous aroma to be heated, but the method is not limited to this method. It is also possible to apply the casting process (D'-2) using the following paper manufacturing process.

That is, the heated aroma generating substrate manufacturing step (D) is a mixed powder manufacturing step (AI) or (A-II), a cellulose fiber manufacturing step (B), and a material preparation step (CI) or. The slurry production step (D'-1) for producing a slurry by mixing the materials produced in (C-II), and the slurry produced in the slurry production process (D'-1) are paper-making, compressing, and drying. It is characterized by comprising a casting process (D'-2) for forming into a sheet and a cutting process (D-3) for cutting the sheet produced in the casting process (D'-2). ..

However, it should be noted in the process (D) of manufacturing the base material for generating aroma to be heated that it is above the melting point of the heat-melted substance regardless of whether it is passed through the compression / shearing process or the casting process. It is impossible to apply the temperature of. This is because the phase-separated structure in which the aromatic heat-melted powder containing the aromatic source material and / or the aromatic agent is dispersed in the aroma generating substrate to be heated is destroyed.

In the heated fragrance generating base material produced by any of the above-mentioned production methods, the fragrance heat-melted powder containing the fragrance source material and / or the fragrance in the heat-melting substance is dispersed in the heated fragrance generating base material. It is a base material for generating aroma to be heated, characterized in that a phase-separated structure is formed, and the minimum outer diameter of the aromatic heat-melted powder thereof is preferably 125 to 355 μm, preferably 150 to 300 μm. It is more preferably 180 to 250 μm, and even more preferably 180 to 250 μm. This minimum outer diameter is determined by the thermomeltability and uniform dispersibility of the aromatic heat-melting material, and the heat-melting material containing the crushed aroma source material and the aroma agent is screened and sorted. If the outer diameter of the aromatic heat-melting powder is too large, its total surface area will be small, the chances of contact with the heat source will be reduced, the heat-melting material will be insufficiently melted, and the amount of volatilization of the aromatic component will be reduced. On the other hand, if the outer diameter of the aromatic heat-melted powder is too small, it is difficult to form a sea-island structure in which the powder is uniformly dispersed on the aroma generating substrate to be heated, and the powder exists as an agglomerated mass. , A region where the melting rate is reduced due to contact with the heat source is created, and the amount of volatile components of the aroma component is reduced.

The fragrance source material and / or the fragrance agent forms a heated fragrance source provided in the heated fragrance cartridge having a phase-separated structure in which the fragrance heat-melted powder mixed with the heat-melting substance is uniformly dispersed. Due to the aroma generating base material, these volatile substances are sufficiently generated from the aerosol former which is a smoke component, and the tobacco plant, the non-tobacco plant, and the air freshener which are the aroma components, and the smoker is satisfied with the smoke and the aroma. It has become possible to provide a heated aromatic cartridge that can be enjoyed.

This is based, firstly, on the effect that the fragrance source material and / or the fragrance agent and the aerosol former are phase-separated so that each of them easily volatilizes when they come into contact with the heat source. In particular, by unevenly distributing the fragrance source material and / or the fragrance agent that volatilizes the fragrance component by the heat source to the heat-melting substance, the fragrance source material and / or the fragrance agent can be used more than when it is present in the entire substrate for generating the fragrance to be heated. This is because the concentration is locally increased and the effect of efficiently volatilizing the aromatic component by contact with the heat source is obtained. Secondly, due to the high thermal fluidity of the heat-melting substance, the volatile components of the fragrance source material and / or the fragrance generated therein move to the surface of the aroma generating substrate to be heated together with the aerosol former and volatilize. Is due to the effect of being promoted. Thirdly, heat-melting substances such as wax and wax have a weaker interaction with aromatic components than aerosol formers such as glycerin and propylene glycol, so that the aromatic components are more likely to be released from the heat-melting substances. Based on the effect.

On the other hand, the heat-melting substance can reliably fix the fragrance source material and / or the fragrance agent at room temperature, and can stably maintain the structure of the heated fragrance generating base material formed by phase separation from the aerosol former. There is also an effect.

FIG. 5 is a schematic diagram of a manufacturing process showing a manufacturing method using compression / shear molding of a heat-affected fragrance generating base material in which a heat-melting substance mixed with an fragrance source material is dispersed, according to an embodiment of the present invention. FIG. 5 is a schematic diagram of a manufacturing process showing a manufacturing method using compression / shear molding of a heat-affected fragrance generating base material in which a heat-melting substance mixed with an fragrance source material and an fragrance agent is dispersed, according to an embodiment of the present invention. A production method according to an embodiment of the present invention using compression / shear molding of a heat-affected aroma-generating base material in which a heat-melting substance mixed with an aroma source material and an aroma agent is dispersed at a temperature equal to or higher than the melting point of the heat-melting substance is shown. It is a schematic diagram of a manufacturing process. It is a schematic of the manufacturing process which shows the manufacturing process using the cast processing of the heat-absorption aroma generating base material in which the heat-melting substance which mixed the fragrance source material and the fragrance agent is dispersed, which concerns on one Embodiment of this invention. A wrapping type heated fragrance cartridge according to an embodiment of the present invention, in which a heated fragrance source and a mouthpiece are brought into contact with each other in the longitudinal direction and wound by using a heated fragrance cartridge wrapping member. It is a perspective schematic diagram which shows the appearance of. A perspective schematic showing an overview of a housing-type heated fragrance cartridge in which a heated fragrance source and a mouthpiece are brought into contact with each other in the longitudinal direction according to an embodiment of the present invention and are charged in a heated fragrance cartridge housing member. It is a figure. According to an embodiment of the present invention, a heated fragrance source connecting portion (1) to which a heated fragrance source is charged and having a female screw and a mouthpiece connecting portion (2) to which a mouthpiece is charged and having a male screw are It is a perspective schematic diagram which shows the appearance of the connecting type heated fragrance cartridge (3) which is fitted and installed. It is a perspective schematic diagram which shows the overview of the connecting part of four typical types of the fragrance to be heated, which can be applied to the connecting type fragrance to be heated cartridge of this invention. (A) is a heating fragrance generation source connecting portion which is provided with a female screw and is only wound. In (b), the base material for generating aroma to be heated, the collapsed material of the base material for generating aroma to be heated, and the mesh for preventing the dust generated by the collapsed material from falling off and scattering into the mouthpiece are further added to (a). It is a connecting part of a heat-resistant fragrance generation source provided. In (c), the heated fragrance generating base material, the collapsed material of the heated fragrance generating base material, and the dust generated by the collapsed material are prevented from falling off and scattering into the heated smoking equipment chamber. A connecting portion of a heat-not-burn aroma source, which is further provided with a cover. (D) is a heating fragrance generation source connecting portion in which a heat source insertion hole is further provided in the cover of (c). In FIG. 2-I according to an embodiment of the present invention, the heated fragrance source and the mouthpiece provided with the filter member are brought into contact with each other in the longitudinal direction and wrapped with the heated fragrance cartridge wrapping member. it is a schematic diagram showing an overview of a cutting plane through the X ₁ -X ₂ wire wrapping type heated aroma cartridges are. In (a), the heated fragrance generating base in which the heated fragrance generating base material is wrapped with the heated fragrance generating base material wrapping member and the mouthpiece in which the filter member is wrapped with the mouthpiece wrapping member are longitudinal. It is a wrapping type heated fragrance cartridge that is attached in a direction and wound using a heated fragrance cartridge wrapping member. In (b), the heated fragrance source, which is the base material for generating the fragrance to be heated, and the mouthpiece, which is the filter member, are brought into contact with each other in the longitudinal direction via the mesh for the wrapping portion of the fragrance to be heated, and the fragrance to be heated is wrapped. It is a wrapping type heated fragrance cartridge that is wound using a member. In FIG. 2-I according to an embodiment of the present invention, a support member of a mouthpiece, which is provided with a support member and a filter member attached in the longitudinal direction, is attached to the heated aroma generation source. is a schematic diagram showing an overview of a cutting plane through the X ₁ -X ₂ wire wrapping type heated aroma cartridge that is wound with a heating aroma cartridge wrapping member. In (a), the support member and the filter member are brought into contact with the heated fragrance generating source in which the heated fragrance generating base material is wrapped with the heated fragrance generating base material wrapping member in the longitudinal direction, and the mouthpiece wrapping member. It is a wrapping type heated fragrance cartridge in which a support member of a mouthpiece wound with is attached and wound using a heated fragrance cartridge wrapping member. In (b), the support member and the filter member are brought into contact with the heated fragrance generating source, which is the heated fragrance generating base material, in this order in the longitudinal direction via the mesh for the wrapping portion of the heated fragrance cartridge. It is a wrapping type heated fragrance cartridge that is provided with a cover for the heated fragrance cartridge wrapping portion at the end of the heated fragrance generation source in the opposite direction of the mouthpiece, and is wound by using the heated fragrance cartridge wrapping member. In FIG. 2-I according to an embodiment of the present invention, a support member, a cooling member, and a support member of a mouthpiece to which a filter member is attached in this order in the longitudinal direction are attached to a heat aroma generation source. is contact, is a schematic diagram showing an overview of a cutting plane through the X ₁ -X ₂ wire wrapping type heated aroma cartridges are wound in the heated aroma cartridge wrapping member. In (a), a support member, a cooling member, and a filter member are arranged in this order in the longitudinal direction on a heated fragrance generating source in which a heated fragrance generating base material is wrapped with a heated fragrance generating base material wrapping member. A wrapping type heated fragrance cartridge in which a support member of a mouthpiece that is attached and wound with a mouthpiece wrapping member is attached and attached and wound using a heated fragrance cartridge wrapping member. In (b), a support member, a cooling member, and a filter member are attached to a heat fragrance generation source, which is a heat fragrance generation base material, in this order via a mesh for a wrapping portion of a heat fragrance cartridge in the longitudinal direction. In addition, a cover for the heated fragrance cartridge wrapping portion is provided with a heat source insertion hole at the end of the heated fragrance generating source in the opposite direction of the mouthpiece, and the mouthpiece is wrapped using the heated fragrance cartridge wrapping member. It is a wrapping type heated fragrance cartridge. In FIG. 2-II according to an embodiment of the present invention, each of the heated fragrance cartridge housing members is brought into contact with the heated fragrance source and the mouthpiece provided with the filter member in the longitudinal direction. it is a schematic diagram showing an overview of a cutting plane through the X ₁ -X ₂ wire housing type heated aroma cartridge that is loaded into. In (a), the heated fragrance generating base in which the heated fragrance generating base material is wrapped with the heated fragrance generating base material wrapping member and the mouthpiece in which the filter member is wrapped with the mouthpiece wrapping member are longitudinal. Each of the heated fragrance cartridges is a housing type heated fragrance cartridge that is charged in the housing member so as to be brought into contact with each other in the direction. In (b), each of the heated fragrance generating source, which is the heated fragrance generating base material, and the mouthpiece, which is the filter member, are brought into contact with each other in the longitudinal direction via the mesh for the wrapping portion of the heated fragrance cartridge. Heated fragrance cartridge A housing-type heated fragrance cartridge that is housed in a housing member. In FIG. 2-II according to an embodiment of the present invention, each of the heated fragrance cartridge housing member is in contact with the heated fragrance source in the longitudinal direction in this order. it is a schematic diagram showing an overview of a cutting plane through the X ₁ -X ₂ wire housing type heated aroma cartridge that is loaded into. In (a), the support member and the filter member are brought into contact with the heated fragrance generating source in which the heated fragrance generating base material is wrapped with the heated fragrance generating base material wrapping member in the longitudinal direction, and the mouthpiece wrapping member. Each is a housing-type heated fragrance cartridge that is loaded into the heated fragrance cartridge housing member so that the support member of the mouthpiece wound with the above is attached. In (b), the support member and the filter member are brought into contact with the heated fragrance generating source, which is the heated fragrance generating base material, in this order via the mesh for the heated fragrance cartridge housing portion in the longitudinal direction. A housing-type heated fragrance cartridge having a cover for the heated fragrance cartridge housing portion at the end of the heated fragrance generation source in the opposite direction of the mouthpiece, each of which is housed in the heated fragrance cartridge housing member. In FIG. 2-II according to an embodiment of the present invention, each of the support member, the cooling member, and the filter member is brought into contact with the heated fragrance source in this order in the longitudinal direction. it is a schematic diagram showing an overview of a cutting plane through the X ₁ -X ₂ wire housing type heated aroma cartridge that is loaded into the aroma cartridge housing member. In (a), a support member, a cooling member, and a filter member are arranged in this order in the longitudinal direction on a heated fragrance generating source in which a heated fragrance generating base material is wrapped with a heated fragrance generating base material wrapping member. Each is a housing type heated fragrance cartridge that is loaded into the heated fragrance cartridge housing member so that the support member of the mouthpiece that is attached and wound around the mouthpiece wrapping member is attached and contacted. In (b), the support member, the cooling member, and the filter member are brought into contact with the heated fragrance generation source, which is the heated fragrance generating base material, in this order in the longitudinal direction via the mesh for the wrapping portion of the heated fragrance cartridge. At the same time, a cover for the heated fragrance cartridge housing portion provided with a heat source insertion hole at the end of the heated fragrance generation source in the opposite direction of the mouthpiece is provided, and each is charged into the heated fragrance cartridge housing member. It is a housing type heated fragrance cartridge. In FIG. 2-III-1 according to an embodiment of the present invention, a mouthpiece connecting portion in which a female screw and a mouthpiece of the heated fragrance generating source connecting portion in which the heated fragrance generating source is charged are charged. is a schematic perspective view showing an overview of a cutting plane through the X ₁ -X _2-wire connecting type heated aroma cartridge and the male screw is fitted. In (a), the heated fragrance generating base material is wrapped with the heated fragrance generating base material wrapping member, and the heated fragrance generating source connecting portion (I) is charged with the heated fragrance generating base (FIG. 2). A connecting type in which the female screw of −III-2 (a)) and the male screw of the mouthpiece connecting portion in which the mouthpiece in which the filter member is wound with the mouthpiece wrapping member are fitted are fitted. It is a fragrance cartridge to be heated. (B) is a heated fragrance generating source connecting portion (II) provided with a mesh for a heated fragrance generating source connecting portion charged with a heated fragrance generating base material (FIGS. 2-III-2 (b). ))) Is a connecting type heated fragrance cartridge in which the female screw and the male screw of the mouthpiece connecting portion in which the filter member is mounted are fitted. In FIG. 2-III-1, according to an embodiment of the present invention, the female screw of the heated fragrance source connecting portion in which the heated fragrance source is charged, and the support member and the filter member are the mouthpiece connecting portion. _{X 1-} X of the connecting type heated fragrance cartridge in which the male screw of the mouthpiece connecting part into which each is inserted is fitted so that the male screw of the mouthpiece is attached in this order in the longitudinal direction. _It is a perspective schematic diagram which shows the appearance of the cut surface passing through 2 lines. In (a), the heated fragrance generating base material is wound with the heated fragrance generating base material wrapping member, and the female screw of the heated fragrance generating source connecting portion in which the heated fragrance generating source is charged is supported. Mouthpiece connecting portion in which the member and the filter member are attached in the longitudinal direction and the support member of the mouthpiece wound with the mouthpiece wrapping member is arranged so as to be arranged on the male screw side of the mouthpiece connecting portion. It is a connecting type heated fragrance cartridge in which the male screw of the above is fitted. (B) is a heated fragrance generating source connecting portion (III) provided with a mesh and a cover for the heated fragrance generating source connecting portion charged with the heated fragrance generating base material (Fig. 2-III-). The female screw of 2 (c)) and the male screw of the mouthpiece connecting portion in which the support member and the filter member are attached and attached in the longitudinal direction in this order from the male screw side of the mouthpiece connecting portion are fitted. It is a connecting type heated fragrance cartridge that is combined. In FIG. 2-III-1, according to an embodiment of the present invention, the female screw of the heated fragrance source connecting portion, which is charged with the heated fragrance source, and the support member, the cooling member, and the filter member are A connecting type to be heated in which the male screw of the mouthpiece connecting portion is fitted and constructed so that the male screw of the mouthpiece connecting portion is fitted and contacted in the longitudinal direction in this order from the male screw side of the mouthpiece connecting portion. it is a schematic perspective view showing an overview of a cutting plane through the X ₁ -X _2-wire aroma cartridge. In (a), the heated fragrance generating base material is wound with the heated fragrance generating base material wrapping member, and the female screw of the heated fragrance generating source connecting portion in which the heated fragrance generating source is charged is supported. The member, the cooling member, and the filter member are attached in this order in the longitudinal direction, and the support member of the mouthpiece wound with the mouthpiece wrapping member is arranged so as to be arranged on the male screw side of the mouthpiece connecting portion. It is a connecting type heated fragrance cartridge in which a male screw of a mouthpiece connecting portion is fitted. (B) is a heated fragrance generating source connecting portion (IV) provided with a mesh for a heated fragrance generating source connecting portion in which a heated fragrance generating base material is charged and a cover provided with a heat source insertion hole. ) (The female screw of FIG. 2-III-2 (d)), the support member, the cooling member, and the filter member are mounted so as to be attached in the longitudinal direction in this order from the male screw side of the mouthpiece connecting portion. It is a connecting type heated fragrance cartridge in which a male screw of a mouthpiece connecting portion is fitted. The heated fragrance generating base material cut into a square columnar shape according to an embodiment of the present invention is perpendicular to the X (longitudinal) direction of the heated fragrance generating base material wrapped with the heated fragrance generating base material wrapping member. It is a schematic diagram which shows the appearance of the cut surface. FIG. 5 is a schematic view showing an overview of a YZ cut surface perpendicular to the X (longitudinal) direction of a support member attached to a fragrance to be heated cartridge according to an embodiment of the present invention. In FIGS. 3-IB and C, 3-II-B and C, and 3-III-B and C, the X direction of this support member is parallel to the paper surface, and the left-right direction of the paper surface is the Y direction. However, they are arranged so that the Z direction is perpendicular to the paper surface in the vertical direction of the paper surface in parallel with the paper surface. FIG. 5 is a schematic view showing an overview of an XZ cut surface perpendicular to the Y (radius) direction of a support member attached to a fragrance to be heated cartridge according to an embodiment of the present invention. Schematic diagram illustrating an overview of a cutting plane through the Figure _{3-I-C X 1 -X} 2 -wire heated smoking article wrapping type heated aroma cartridge is mounted as shown in (a) according to an embodiment of the present invention Is.

Hereinafter, the present invention will be described in more detail using embodiments, but the present invention is not limited thereto, and various modifications can be made without departing from the gist of the present invention. , It is limited only by the technical idea described in the claims.

First, the fragrance in which the fragrance source material and / or the fragrance agent is mixed in the heat-melting substance in the heated fragrance generating base material constituting the heated fragrance generating source provided in the heated fragrance cartridge, which is the basis of the present invention. In order to specifically explain the effect brought about by the phase-separated structure in which the heat-melted powder is uniformly dispersed, Examples 1 to 4 and Comparative Examples were performed.
<< Example 1 >>

As an aroma source material, tea, konjak powder, mokusei flower, and amachazuru, as an aerosol former, glycerin and propylene glycool, as a heat-melting substance, paraffin wax wax (Paraffin Wax-145 manufactured by Nippon Seiwa Co., Ltd., petroleum-based) Natural wax, melting point 63 ° C), peppermint oil and menthol as fragrance, sodium salt of CMC as binder, sugar cane fiber, crosslinked PVP and β-cyclodextrin as scavenger, potassium sorbate as antibacterial agent and Using sodium benzoate in the following compounding ratio, a heated fragrance generating base material, a heated fragrance generating source, and a heated fragrance cartridge are prepared, attached to a commercially available heated smoking tool, and heated fragrance. Ten cartridge enthusiasts were the subjects, and a sensory test of smoke and aroma was conducted. Pure water was added as a composition because it was necessary for molding, but it was dried and removed after molding to the aroma generation source.
Aroma source material 65% by mass 100 parts by mass Black tea Konjac powder Sweet osmanthus flower Jiaogulan Aerosolformer 25% by mass
Glycerin Propylene Glycool Heat Melting Material Paraffin Wax 10% by Mass
Air Freshener 15 parts by mass Mentha oil Menthol binder 23 parts by mass CMC sodium salt Sugar cane fiber sorbent 21 parts by mass Crosslinked PVP
β-Cyclodextrin Preservative 0.005 parts by mass
Potassium sorbate Sodium benzoate Pure water 20 parts by mass

As shown in FIG. 1-I, the base material for generating aroma to be heated includes a mixed powder manufacturing step (AI) in which an aroma source material and a heat-melting substance are mixed at room temperature, and a cellulose fiber manufacturing step in which cellulose fibers are manufactured from a fiber plant. (B), Aerosolformer, fragrance, molding agent, binder, preservative, and material preparation step (CI) for preparing water, mixed powder manufacturing step (AI), cellulose fiber manufacturing step (B) ), And the material produced in the material preparation step (CI) according to the heated aroma generating base material manufacturing step (D) for producing a heated aroma generating base material using compression / shearing.

More specifically, the mixed powder manufacturing step (AI) in which the aroma source material and the heat-melting substance are mixed includes a drying / insecticidal step (A-1) for drying / killing the aroma source material and a drying / insecticidal step (A-1). Crushing step (A-2) for crushing the fragrance source material produced in -1), crushing step (A-5) for crushing the heat-melting substance, crushing the fragrance source material produced in the crushing step (A-2). A compression / shear mixing step (A-6) and a compression / shear mixing step in which the material and the crushed heat-melted material produced in the crushing step (A-5) are roughly mixed with a Henschel mixer and then compressed / sheared to be mixed. A cooling step (A-7) for cooling the mixture produced in (A-6) to 0 ° C. or lower, and a crushing step (A-8) for pulverizing the mixture cooled in the cooling step (A-7). According to this step, an aromatic heat-melting powder in which the aromatic source material powder was dispersed in the heat-melting substance was produced. The aromatic heat-melted powder produced in this manner was sieved by 80 mesh, and a powder having a minimum outer diameter of about 250 μm was selected and used.

Further, in the cellulose fiber manufacturing step (B) for producing cellulose fibers from a fiber plant, a fiber plant that has undergone a pressing step (B-1) and a pressing step (B-1) in which sugar cane is used as a fiber plant and is squeezed is used. The crushing step (B-2) for crushing, the boiling step (B-3) for boiling the crushed product produced in the crushing step (B-2), and the boiling product produced in the boiling step (B-3) are dehydrated. It consists of a dehydration / drying step (B-4) for drying and a crushing step (B-5) for crushing the dried product produced in the dehydration / drying step (B-4). One sugar cane fiber was produced.

From the material thus obtained and the material prepared in the material preparation step (CI), the heated aroma generating base material in which the aromatic heat-melted powder is dispersed according to the heated aroma generating base material manufacturing step (D). Was manufactured. That is, the aromatic heat-melted powder produced in the mixed powder manufacturing step (AI), the sugar cane fibers produced in the cellulose fiber manufacturing step (B), and the aerosol prepared in the material preparation step (CI). After mixing the former, the fragrance, the sodium salt of CMC which is one of the binders, the scavenger, the preservative, and pure water by the kneader in the mixing step (D-1), the composition thereof is 3. In the compression / shearing step (D-2) of forming a sheet using this roll, the sheet was formed so that the thickness of the sheet was 0.28 ± 0.02 mm. This compression / shearing step (D-2) was performed below the melting point of the paraffin wax. The sheet formed in this way is cut into a width of 1.5 ± 0.1 mm and a length of about 240 mm in a cutting step (D-3) of cutting the sheet, and then a predetermined amount of filling rate is obtained. It was wrapped in paper so that it would be. Next, the paper-wrapped base material for generating aroma to be heated was cut to a length of 11.5-12.0 mm and then dried to produce a source of aroma to be heated.

For the heat-heated fragrance generation source produced in this manner, two types of heat-heated fragrance cartridges were manufactured in order to carry out a sensory test by smoking using a heating type smoking tool equipped with a blade-type heat source using a heater.

On the other hand, as shown in FIG. 3-III-B, the heated fragrance generating base material 1121 manufactured in the present embodiment is wound with the heated fragrance generating base material wrapping member 112. Is attached to the heated fragrance generating source connecting portion (I) 1031A provided with the fitting female screw 10311 for the heated fragrance generating source connecting portion, while the support member 123 and the filter member 122 are brought into contact with each other in the longitudinal direction. , The filter mouthpiece 120-B1 with a support member wound by the mouthpiece wrapping member 121 is attached to the mouthpiece connecting portion 1032 provided with the fitting male screw 10321 for the mouthpiece connecting portion, and then these heated fragrances. The cartridge connecting member (A) 103A was fitted into the connecting type heated fragrance cartridge (B) 100-III-B (a) provided with a filter mouthpiece with a supporting member.

On the other hand, as shown in FIG. 3-III-C, the heated fragrance generation source 110 in which the heated fragrance generating base material aggregate 1121 produced in the present embodiment is wrapped with the heated fragrance generating base material wrapping member 112. Is attached to the heated fragrance generating source connecting portion (I) 1031A provided with the fitting female screw 10311 for the heated fragrance generating source connecting portion, while the support member 123, the cooling member 124, and the filter member 122 are longitudinal. The filter mouthpiece 120-C1 with a support / cooling member, which is attached in this order in this order and wound around the mouthpiece wrapping member 121, has a mouthpiece connecting portion 1032 provided with a fitting male screw 10321 for the mouthpiece connecting portion. These heated fragrance cartridges (A) 103A are fitted to the heated fragrance cartridge (A) 103A, and a connecting type heated fragrance cartridge (C) 100-III-C (a) provided with a filter mouthpiece with a support / cooling member. And said.

The support member 123 used here has a function of preventing the heated fragrance source 110 from moving in the suction direction and cooling the volatile matter generated from the heated fragrance source 110, which is an example. As a support member 123 having the structure shown in FIGS. 5-I and II, the support member 123 was used. The support member central portion 1231 is located along the central axis of both connecting type heated fragrance cartridges 100-III-B (a) and 100-III-C (a) in the X direction, and the support member central portion thereof. With 1231 as the center of the object, the first support member peripheral portion 1232A and the second support member peripheral portion 1232B extending in the radial direction form the support member peripheral portion 1232. Then, the space created between the first support member peripheral portion 1232A and the second support member peripheral portion 1232B facing each other becomes the gas flow path 1233. The outermost peripheral portion of the support member peripheral portion 1232 is caught in the mouthpiece wrapping member 121 via an adhesive and fixed to the inner surface thereof.

Further, the internal structure of the heated fragrance generating source 110 is wound up by placing the heated fragrance generating base material 112 on the wrapping member 111 of the heated fragrance generating base material in the longitudinal direction, and the heated fragrance generating base material aggregate is wound up. The heated fragrance generating source 110 in which 1121 is wrapped with the heated fragrance generating base material wrapping member 111 will be described as an example. FIG. 4 shows a schematic schematic view of the cross section. When the heated aroma generating base material 112 is assembled, a large number of heated aroma generating base material aggregates 112A are formed, so that the primary aggregate flow created by the displacement of the heated aroma generating base material 112 in the aggregates 112A. The base material-wrapping member gas flow path 112D, which is a space between the path 112B, the secondary agglomerate flow path 112C generated between the agglomerates 112A, and the heated aroma generating base material 112 and the heated aroma generating base material wrapping member 111. Since the gas flow paths such as the above are generated, the volatile matter generated by heating passes through these gas flow paths, and the smoker can suck the aroma and smoke with a stable air flow. All of the heat-heated fragrance sources of the heated fragrance cartridge of the present invention, which will be described later, form an internal structure similar to this. Since the heated fragrance source 111 shredded into a prismatic shape forms the heated fragrance source 110 in a state of being bundled in a predetermined number, the smoker can stably blow the volatile matter generated by heating. Can be sucked with.

The sensory test was evaluated by the smoker who was the subject smoking as follows using the above two types of connecting type heated fragrance cartridges 100-III-B (a) and 100-III-C (a). .. As shown in FIG. 6, the connecting type heated fragrance cartridge 100-III-C (a) is mounted on the chamber 202 formed in the body 201 of the heat-not-burn smoking device 200 , and is mounted on the central portion of the bottom of the chamber 202. The provided heat source 203 pierces the heated fragrance source 110, and the heated fragrance source 110 is heated electronically and can be smoked. A sensory test was performed using the connecting type heated fragrance cartridge 100-III-B (a) in the same manner.

As a comparative example, the composition of the aroma generating base material to be heated has exactly the same composition except that it does not contain paraffin wax, and the aroma source material is dried / insecticidal step (A-1) and pulverized step (A). Two types of crushed aroma source material produced in -2) are charged in the same manner as in Example 1 except that they are put into the mixing step (D-1) of the aroma generating substrate manufacturing step (D) to be heated. A fragrance to be heated cartridge was manufactured. Then, a sensory test was conducted in the same manner as in Example 1.

As a result, it was obtained that 8 or more of the 10 subjects were able to smoke more strongly and comfortably in Example 1 than in Comparative Example for both heated fragrance cartridges. rice field. As is clear from this, the effect of unevenly distributing the aroma source material to the heat-melting substance was recognized. Below, if this standard is satisfied, it is considered as a pass.
<< Example 2 >>

Similar to Example 1, the heated fragrance generating source and the subject are subject to the same composition as in Example 1, except that the heated fragrance generating base material was produced by the production method of FIG. 1-II. A heated fragrance cartridge was manufactured. The production method of FIG. 1-II is characterized in that a fragrance source material crushed product, a heat-melting substance crushed product, and an fragrance agent are mixed to produce an fragrance heat-melted powder containing the fragrance source material and the fragrance agent. The compression / shearing step (D-2) was carried out below the melting point of the paraffin wax, as in Example 1. As a result of conducting a sensory test in the same manner as in Example 1, the results were passed, but in this case, it was obtained that all 10 subjects were able to smoke more strongly and comfortably in both smoke and aroma than in the comparative example. The effect of unevenly distributing the fragrance to the heat-melting substance was observed.
<< Example 3 >>

As in Example 1, the heated fragrance generating source and the subject to be heated, except that the heated fragrance generating base material was produced by the production method of FIG. 1-III with the same composition as in Example 1. A heated fragrance cartridge was manufactured. The production method of FIG. 1-III is characterized in that the fragrance is mixed at a temperature equal to or higher than the melting point of the heat-melting substance, and solves an operational problem when the fragrance is mixed with the heat-melting substance. In this case as well, the compression / shearing step (D-2) was performed at a temperature equal to or lower than the melting point of the paraffin wax, as in Example 1. The result of the sensory test was the same as that of Example 2 and passed.
<< Example 4 >>

Similar to Example 1, the heated fragrance generating source and the subject are subject to the same composition as in Example 1, except that the heated fragrance generating base material was produced by the production method of FIG. 1-IV. A heated fragrance cartridge was manufactured. In the manufacturing method of FIG. 1-IV, the slurry manufacturing step (D'-1) and the casting process (D'-2) using the paper manufacturing step were applied in the heated aroma generating base material manufacturing step. There is a feature in. The slurry manufacturing step (D'-1) and casting step (D'-2) were also carried out at a temperature equal to or lower than the melting point of the paraffin wax, as in the compression / shearing step (D-2). Also in this production method, the same sensory test results as in Example 2 were obtained.

The effects based on the characteristics of the heated fragrance generating base material of the present invention have been specifically described above. Next, the heated fragrance generating source of the present invention using the heated fragrance generating base material, and the subject. The heated fragrance cartridge using the heated fragrance source will be described in detail with reference to the drawings. However, the present invention is not limited to these, and various modifications can be made without departing from the gist of the present invention, and the present invention is limited only by the technical idea described in the claims. It is a thing.

As shown in each (b) of FIGS. 3-IA to 3-III-C, the heated aroma generating source 110 is at least an aggregate of the heated aroma generating base materials 112 produced in Examples 1 to 4. It may be 1121, and in the present embodiment, the heated fragrance cartridge exterior member which is a tubular body of the heated fragrance cartridge, that is, the heated fragrance cartridge wrapping member 101 which is a tubular roll, and the tubular housing. An example is illustrated of a certain heated fragrance cartridge housing member 102, which is embedded in a heated fragrance cartridge connecting member 103, which is a tubular housing that is detachably connected at at least one place. These heated fragrance cartridge exterior members will be described in detail in the heated fragrance cartridge.

Further, as shown in each (a) of FIGS. 3-IA to 3-III-C, the heated aroma generating source 110 is an assembly of the heated aroma generating base materials 112 produced in Examples 1 to 4. The body 1121 may be wrapped with a heated aroma generating base material wrapping member 111, which is a tubular roll. The material of the material for wrapping the base material for generating aroma to be heated is not particularly limited as long as it can be made into a tubular scroll, but in the present embodiment, a thin paper and a plastic film are exemplified.

The shape of the heated aroma generating base material 112 constituting the heated aroma generating source 110 is also not particularly limited, such as sheet shape, columnar shape, prismatic shape, granular shape, scale shape, etc., but from the viewpoint of securing the flow path of the aroma and smoke. To columnar or prismatic is preferable. In the present embodiment, for example, in FIG. 4, a schematic cross-sectional view of a heated fragrance generating source 110 in which an aggregate 1121 of the heated fragrance generating base material 112 is wrapped with a heated fragrance generating base material wrapping member 111 is illustrated. As shown above, the square pillar heated aroma generating base material 112 is used. As is clear from the figure, in the aggregate 1121 of the aroma generating base material 112 to be heated, a large number of aroma generating base material aggregates 112A to be heated are formed, so that the aroma generating base material 112 to be heated is contained in the aggregates 112A. It is a space between the primary agglomerate flow path 112B created by the misalignment of the above, the secondary agglomerate flow path 112C generated between the agglomerates 112A, and the heated aroma generating base material 112 and the heated aroma generating base material wrapping member 111. Since gas flow paths such as the base material-wrapping member gas flow path 112D are generated, the volatile matter generated by heating passes through these gas flow paths, and the smoker emits aroma and smoke in a stable air flow. Can be aspirated. Such a gas flow path is similarly formed even if it has a sheet shape, a columnar shape, a prismatic shape, a granular shape, a scale shape, or the like.

As an embodiment of the heated fragrance cartridge of the present invention using such a heated fragrance source 110, the following three types of heated fragrance cartridge 100 will be exemplified. First, as shown in FIG. 2-I, the heated fragrance source 110 is wound by the heated fragrance cartridge wrapping member 101, which is a tubular scroll, and the mouthpiece 120 is formed. , A wrapping type heated fragrance cartridge 100-I , which is installed in a smokeable form. Secondly, as shown in FIG. 2-II, the heated fragrance source 110 is wound by the heated fragrance cartridge housing member 102, which is a tubular housing, and the mouthpiece 120 is formed. It is a heated fragrance cartridge that is installed in a smokeable form as a housing type heated fragrance cartridge 100-II. Thirdly, as shown in FIG. 2-III-1, the heated fragrance source connecting portion provided with the fitting female screw 10311 for the heated fragrance source connecting portion in which the heated fragrance source 110 is charged. The heated fragrance cartridge connecting member 103, which is a tubular housing in which the 1031 and the mouthpiece connecting portion 1032 having the male screw for the mouthpiece connecting portion to be the mouthpiece 120 are detachably connected to each other, is formed. It is a heated fragrance cartridge that is installed in a smokeable form as a connecting type heated fragrance cartridge 100-III.

In particular, in the connecting type heated fragrance cartridge 100-III , as shown in FIG. 2-III-1, the heated fragrance source connecting portion 1031 and the mouthpiece connecting portion 1032 constituting the heated fragrance cartridge connecting member 103 are connected. Since it is removable, the heated fragrance source 110 and various mouthpieces 120 described later can be freely replaced according to the smoker's preference, and the heated fragrance source connecting unit 1031 and the mouthpiece connecting unit. The 1032 can be easily washed and can be used repeatedly.

Further, the heated fragrance cartridge of the present invention is characterized by the mouthpiece 120 shown in FIGS. 2-I, 2-II, and 2-III-1. As shown in FIG. 6, the smoke in smoking of the heated fragrance cartridge using the heat-not-burn smoking tool 200 is based on the aerosol generated by cooling after the aerosol former volatilizes, and is similar to a cigarette. Since the smoke does not contain solid components and the aroma source contains little or no tobacco plants, it is low in nicotine and tar and does not require a filter function in the mouthpiece. Since at least a cooling function is required in which the volatile components of the aerosol condense to form an aerosol, the wrapping type heated fragrance cartridge 100-I shown in FIGS. 2-I, 2-II, and 2-III-1 is required. , The housing type aerosol to be heated cartridge 100-II , and the mouthpiece 120 of the connecting type aerosol to be heated cartridge 100-III show an embodiment in which the cavity is formed.

In this case, since the heated fragrance cartridge wrapping member 101 is held in the mouth, paper cannot be used, and in the present embodiment, the case of the polyolefin-based resin film is illustrated. The material of the heated fragrance cartridge housing member 102 and the connecting member 103 is also a polyolefin resin, but the molded housing thereof is exemplified. The materials for the heated fragrance cartridge housing member and the connecting member are the same below.

However, the wrapping type heated fragrance cartridge 100-IA , the housing type heated fragrance cartridge 100-II-A , of FIGS. 3-IA, 3-II-A, and 3-III-A, And, as shown in the connecting type heated fragrance cartridge 100-III-A , the mouthpiece can be provided with the filter member 122 according to the smoker's habit of the cigarette. In particular, in this case, the heated fragrance cartridge wrapping member 101 of the wrapping type heated fragrance cartridge 100-IA is preferably a wrapping paper similar to a cigarette, and in the present embodiment, the case where the wrapping paper is used is illustrated. There is. As is clear from the figure, in each of the heated fragrance cartridges, the filter mouthpiece 120-A1 in which the filter member 122 is wound by the mouthpiece wrapping member 121 and the filter member 122 are directly charged in the exterior member of the heated fragrance cartridge. As illustrated in the filter mouthpiece 120-A2, either one may be used, but in the case of the housing type heated fragrance cartridge 100-II-A and the connecting type heated fragrance cartridge 100-III-A , the filter is used. Since the mouthpieces 120-A1 and A2 can be attached and detached, it is preferable that the mouthpieces are wrapped with the mouthpiece wrapping member 121. Further, in the present embodiment, the mouthpiece wrapping member 121 made of a thin polyolefin resin film is illustrated in consideration of resistance to an aerosol former. The same applies hereinafter.

Further, in FIGS. 3-IA (b), 3-II-A (b), and 3-III-A (b), the heated fragrance source 110 is covered with the filter member 122. Each heated fragrance cartridge 100 provided with a heated fragrance generating base material, a collapsed material of the heated fragrance generating base material, and meshes 1011, 1021, and 10312 for preventing the dust generated by the collapsed material from falling off and scattering. -IA (b) , 100-II-A (b) , 100-III-A (b) are exemplified. The meshes 1011 and 1021 of the present embodiment exemplify a non-woven fabric produced from polyester resin fibers.

Here, in the case of the connecting type heated fragrance cartridge 100-III-A (b) , as shown in FIG. 2-III-2 (b), the heated fragrance source connecting portion to which the mesh 10312 is detachably attached. It can be 1031B. Therefore, the heated fragrance generating source connecting portion 1031B to which the mesh 10312 is attached can not only prevent the above-mentioned dropout and scattering, but also charge the heated fragrance generating source 110 without protruding from the heated fragrance generating source connecting portion 1031B. The amount of charge can be adjusted, and the mesh 10312 can be cleaned. Such a mesh 10312 is also provided with a non-woven fabric produced from polyester resin fibers, but in the present embodiment, a woven fabric produced from polyester resin fibers having excellent strength for repeated use is exemplified. ..

Further, the heated fragrance cartridge 100 provided with the support member 123 for preventing the heated fragrance source 110 from moving toward the filter member 122 is shown in FIGS. 3-IB, 3-II-B, and FIGS. 100-I-B of the 3-III-B, 100- II-B, and shows the 100-III-B. Also in this case, like the mouthpieces 120-A1 and A2 having only the filter member 122, the mouthpieces 120-B1 and B2 corresponding to the presence / absence of the mouthpiece wrapping member 121 are illustrated.

In this embodiment, as shown in FIGS. 3-IB (b), 3-II-B (b), and 3-III-B (b), the filter member is sent from the heated fragrance source 110. In addition to the meshes 1011, 1021, and 10312 for preventing the heat-not-burned fragrance-generating base material, the collapsed material of the heated fragrance-generating base material, and the dust generated by the collapsed material from falling off and scattering, the heated fragrance is added to 122. A cover for preventing the heated fragrance generating base material, the collapsed material of the heated fragrance generating base material, and the dust generated by the collapsed material from falling off and scattering from the source 110 to the chamber 202 of the heated smoking tool 200. The heated fragrance cartridge 100 provided with 1012, 1022, and 10313 is illustrated. Since the heat source 203 of the heat-not-burn smoking tool 200 shown in FIG. 6 penetrates the heat source 203 and makes slight contact with the heat source 203, a non-woven fabric or woven fabric made of vegetable fibers is used so as not to contaminate the heat source 203. Covers 1012 and 1022 exemplify non-woven fabrics.

In this case as well, the connecting type heated fragrance cartridge 100-III-B (b) has the heated fragrance source connecting portion 1031C to which the cover 10313 is detachably attached as shown in FIG. 2-III-2 (c). However, since the heat source 203 must be inserted when the heat source 203 is used for the first time, it is preferable that the non-woven fabric is made of vegetable fiber, and in the present embodiment, it is made of vegetable fiber. The non-woven fabric is illustrated.

Then, the fragrance to be heated cartridge 100 provided with the cooling member 124 for cooling the volatile matter of the aerosol former and promoting the generation of smoke is shown in FIGS. 3-IC, 3-II-C, and 3-. 100-I-C of the III-C, 100-II- C, and, shown in 100-III-C. Also in this case, like the mouthpieces 120-A1 and A2 having only the filter member 122, the mouthpieces 120-B1 and B2 corresponding to the presence / absence of the mouthpiece wrapping member 121 are illustrated.

Also in this embodiment, similarly to FIGS. 3-IB (b), 3-II-B (b), and 3-III-B (b), the heated fragrance source 110 to the filter member 122 In addition to the meshes 1011, 1021, and 10312 for preventing the heat-not-burned fragrance-generating base material, the collapsed material of the heated fragrance-generating base material, and the dust generated by the collapsed material from falling off and scattering, the heated fragrance is generated. A cover 1013 for preventing the heat-heated fragrance-generating base material, the collapsed material of the heated fragrance-generating base material, and the dust generated by the collapsed material from falling off and scattering from the source 110 to the chamber 202 of the heat-not-burn smoking tool 200. The heated fragrance cartridge 100 provided with 1023 and 10314 is illustrated. However, since these covers 1013, 1023, 10314 are provided with heat source insertion holes 10131, 10231, 103141 through which the heat source 203 of the heat-not-burn smoking tool 200 shown in FIG. 6 is inserted, these covers 1013, 1023 are provided. , 10314 and the heat source 203 do not come into contact with each other. Therefore, the heat source 203 is easily inserted into the fragrance source 110 to be heated, and the covers 1013, 1023, and 10314 are not heated to contaminate the heat source 203. Therefore, as the material of the covers 1013, 1023, 10314, a non-woven fabric or woven fabric made of plastic fibers can be used, and in the present embodiment, the non-woven fabric or woven fabric made of polyester fibers is exemplified.

In this case as well, the connecting type heated fragrance cartridge 100-III-C (b) has the heated fragrance source connecting portion 1031D to which the cover 10314 is detachably attached as shown in FIG. 2-III-2 (d). Since the heat source insertion hole 103141 through which the heat source 203 is inserted is provided so that it can be used repeatedly, it is preferable that the woven fabric is made of polyester fiber in consideration of repeated use. In the examples, a woven fabric made of polyester fibers is exemplified.

As described above, the heated fragrance source 110, the mouthpiece 120, the heated fragrance cartridge wrapping member 101 in which the heated fragrance source 110 and the mouthpiece 120 are the exterior materials of the heated fragrance cartridge, the heated fragrance cartridge housing member 102, Moreover, although the embodiment of the heated fragrance cartridge which is wound and installed around the heated fragrance cartridge connecting member 103 is illustrated, the present invention is not limited thereto. The heated fragrance source and the heated fragrance cartridge of the present invention can be variously modified and implemented within a range that does not deviate from the gist of the present invention, and are limited only by the technical idea described in the claims. It is a thing.

The present invention is a technique capable of providing the enjoyment of smoking smoke and aroma derived from plants including tobacco belonging to the genus Nicotiana of the Solanaceae family. When it does not contain tobacco plants, not only the smoker himself but also the non-smokers around him can enjoy smoking without adversely affecting his health, and it has a healing effect that brings alpha waves to the brain. A new smoking tool that helps improve health and beauty. Therefore, the technique for promoting the generation of smoke and fragrance related to the heated fragrance generating base material of the present invention can be applied to incense sticks, burning scents, scents, scents, etc., aromatherapy and the like similar to the heated fragrance generating base material. there is a possibility.

100 heated fragrance cartridge
100-I wrapping type heated fragrance cartridge
100-IA wrapping type heated fragrance cartridge (A) filter mouthpiece
100- IB wrapping type heated fragrance cartridge (B) Filter mouthpiece with support member
100- IC wrapping type heated fragrance cartridge (C) Filter mouthpiece with support / cooling member 101 Heated fragrance cartridge wrapping member 1011 Heated fragrance cartridge wrapping part mesh 1012 Heated fragrance cartridge wrapping part cover (I)
1013 Cover for wrapping part of aromatic cartridge to be heated (II)
10131 Heat source insertion hole
100-II housing type fragrance to be heated cartridge
100-II-A Housing Type Heated Fragrance Cartridge (A) Filter Mouthpiece
100-II-B Housing type Aroma cartridge to be heated (B) Filter mouthpiece with support member
100-II-C Housing type Heated fragrance cartridge (C) Filter mouthpiece with support / cooling member 102 Heated fragrance cartridge housing member 1021 Heated fragrance cartridge housing part mesh 1022 Heated fragrance cartridge housing part cover (I)
1023 Cover for fragrance cartridge housing to be heated (II)
10231 Heat source insertion hole
100-III connecting type aroma cartridge to be heated
100-III-A Connecting Type Heated Fragrance Cartridge (A) Filter Mouthpiece
100-III-B Connecting type Aroma cartridge to be heated (B) Filter mouthpiece with support member
100-III-C Connecting type heated fragrance cartridge (C) Filter mouthpiece with support / cooling member 103 Heated fragrance cartridge connecting member 103A Heated fragrance cartridge connecting member (A)
103B Heated Fragrance Cartridge Connecting Member (B)
103C Aroma cartridge to be heated Connecting member (C)
103D Heated Fragrance Cartridge Connecting Member (D)
1031 Heated fragrance source connecting unit 1031A Heated fragrance source connecting unit (I)
1031B Heated aroma source connecting part (II)
1031C Heated aroma source connecting part (III)
1031D Heated aroma source connecting part (IV)
10311 Fitting female screw for connecting part of heated fragrance source 10312 Mesh for connecting part of heated fragrance source 10313 Cover (I) for connecting part of heated fragrance source (III)
10314 Cover (II) for connecting part (IV) to generate aroma to be heated
103141 Heat source insertion hole 1032 Mouthpiece connecting part 10321 Mouthpiece connecting part fitting male screw 110 Heated fragrance generating source 111 Heated fragrance generating base material Wrapping member 112 Heated fragrance generating base material 1121 Heated fragrance generating base material aggregate 112A Heated aroma generating base material aggregate 112B Primary aggregate gas flow path (I)
112C Secondary Aggregate Gas Channel (II)
112D base material-lamping member gas flow path (III)
120 Mouthpiece 120-A1, A2 Filter Mouthpiece 120-B1, B2 Filter with support member Mouthpiece 120-C1, C2 Filter mouthpiece with support / cooling member 121 Mouthpiece wrapping member 122 Filter member 123 Support member 1231 Support member center Part 1232 Support member peripheral part 1232A First support member peripheral part 1232B Second support member peripheral part 1233 Gas flow path 124 Cooling member
200 Heating type smoking equipment 201 Body 202 Chamber 203 Heat source L Length of support part D Diameter of support part d Distance between the periphery of the first support member and the periphery of the second support member X ₁ , X ₂ Cross section of the aromatic cartridge to be heated Center X Longitudinal direction of the heated fragrance cartridge parallel to the paper surface Y Cross-sectional direction of the heated fragrance cartridge parallel to the paper surface Z Cross-sectional direction of the heated fragrance cartridge parallel to the paper surface

Claims (68)

A heated aroma generating base material that forms a heated aroma generating source of a heated aroma cartridge that is attached to a heated smoking device to generate aerosol and aroma, and contains at least an aroma source material, an aerosol former, and a heat-melting substance. A heat-heated aroma-generating base material in which an aromatic heat-melting powder containing the aroma source material mixed with the heat-melting substance is dispersed in the heat-heated aroma-generating base material. The base material for generating aroma to be heated according to claim 1, wherein the minimum outer diameter of the aromatic heat-melted powder is 125 to 355 μm. The first or second claim, wherein the compounding ratios of the aerosol former, the fragrance source material, and the heat-melting substance are 20 to 40% by mass, 55 to 75% by mass, and 2 to 15% by mass, respectively. Heated fragrance generating base material. Any one of claims 1 to 3, wherein the heat-melting substance contains at least one selected from petroleum-based natural wax, synthetic wax, plant-based natural wax, animal-based natural wax, and tack fire. The base material for generating aroma to be heated according to. The heated aroma generating base material according to claim 4, wherein the petroleum-based natural wax is at least one selected from petrolatum, paraffin wax, and microcrystalline wax. The synthetic wax is Fischer-Tropsch wax, polyethylene (PE) wax and modified PE wax, polypropylene (PP) wax and modified PP wax, fatty acid amide, fatty acid, fatty alcohol, polyoxyalkylene glycol, poly. The base material for generating aroma to be heated according to claim 4, which is at least one selected from oxyethylene alkyl ether and polyoxyethylene alkyl amine. The heterogeneous heated aroma generating base material according to claim 4, wherein the plant-based natural wax is at least one selected from goby wax, sumac wax, carnauba wax, sugar cane wax, palm wax, and candelilla wax. .. The heated aroma generating base material according to claim 4, wherein the animal-based natural wax is at least one selected from beeswax, spermaceti, privet wax, wool wax, and shellac. The heated aroma generating base material according to claim 4, wherein the tackifier is at least one selected from rosin and rosin derivatives, and terpene resin and modified terpene resin. The base material for generating aroma to be heated according to any one of claims 1 to 9, wherein the melting point of the heat-melting substance is in the range of 20 to 200 ° C. The base material for generating aroma to be heated according to claim 6, wherein the PP wax and the modified PP wax are substances that melt in the range of 150 to 200 ° C. The base material for generating aroma to be heated according to claim 9, wherein the rosin derivative and the modified terpene resin are substances that melt in the range of 150 to 200 ° C. The aroma source material is at least one selected from teas and plant flowers, rhizomes, fruits, and above-ground foliage.
The teas are at least one selected from Chinese tea and black tea.
The flower is at least one selected from the flowers of roses, plants of the genus Oleaceae of the family Oleaceae, lavender, and saffron.
The rhizome is at least one selected from the rhizomes of scallions, shallot, garlic, onions, and konjac.
The fruits are Karin, a plant belonging to the genus Citrus of the Rutaceae family (Daidai, Satsuma mandarin, Natsudaidai, Pomelo, Hassaku, Iyokan, Echan Lemon, Karatachi, Orange, Mandarin orange, Cabos, Kishumikan, Kinotte, Grapefruit, Koji, Sanbokan, Citron.・ Jabara, Sudachi, Tachibana, Tangerine, Natsumikan, Hanayuzu, Hyuga Natsu, Hirami Lemon (Shikuwasa), Pomelo (Zabon), Yuzu, Lime, Lemon, Kobumikan, etc. At least one selected from citrus, melon, pomelo, ume, apricot, blueberry, Rutaceae Dutch strawberry plant, raspberry, banana, and grape fruit,
The above-ground foliage is peppermint-based plants of the Labiatae genus Peppermint (peppermint, Japanese mint, apple mint, water mint, corsica mint, penny royal mint, etc.) Mentha, ginger mint, etc.), dog mint, kousui mint (lemon balm), kidachi mint (savory), yanagi mint (hisop), and at least one selected from the above-ground foliage of plants of the Labiatae tobacco species. The base material for generating aroma to be heated according to any one of 1 to 12. The subject according to any one of claims 1 to 13, wherein the aerosol former contains at least one selected from propylene glycol, ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, and glycerin. Heated aroma generating base material. The base material for generating a fragrance to be heated according to any one of claims 1 to 14, further comprising a fragrance agent. The heated fragrance generating base material according to claim 15, wherein the fragrance is contained in the fragrance heat-melted powder. The base material for generating aroma to be heated according to claim 15 or 16, wherein the fragrance contains at least one selected from a refreshing agent and nicotine. The refreshing agents are menthol and menthol derivatives, menthol and menthol derivatives, mentancarboxylic acid amides, 2,3-dimethyl-2- (2-propyl) -butyric acid derivatives, mentan and mentan derivatives, L-carboxylics, xylitol, eucalyptus. The heterogeneous heated aroma generating base material according to claim 17, which is at least one selected from essential oils, peppermint oils, sparemint essential oils, and spiranthol. The base material for generating aroma to be heated according to any one of claims 1 to 18, further comprising a molding agent. The base material for generating aroma to be heated according to claim 19, wherein the molding agent is microcrystalline cellulose. The base material for generating aroma to be heated according to any one of claims 1 to 20, further comprising a binder. The heated aroma generating base material according to claim 21, wherein the binder contains at least one selected from a polysaccharide polymer, a cellulosic polymer, and a cellulosic fiber. The polysaccharide polymer is at least one selected from konjac mannan (glucomannan), guar gum, pectin, carrageenan, tamarin seed gum, locust bean gum, caraya gum, and xanthan gum.
The cellulosic polymer is carboxymethyl cellulose (CMC), carboxyethyl cellulose, hydroxymethyl cellulose, hydroxyethyl cellulose, and hydroxypropyl cellulose, and sodium salt, potassium salt, calcium salt of CMC, and sodium salt of carboxyethyl cellulose. , Potassium salt, and at least one selected from calcium salts,
The heated aroma generating base material according to claim 22, wherein the cellulose fiber is at least one selected from sugar cane, bamboo, wheat, rice, esparto, and jute cellulose fibers. The base material for generating aroma to be heated according to any one of claims 1 to 23, further comprising a scavenger. The base material for generating aroma to be heated according to claim 24, wherein the scavenger is crosslinked polyvinylpyrrolidone and / or cyclodextrin. The base material for generating aroma to be heated according to any one of claims 1 to 25, further comprising a preservative. The heated aroma generating base material according to claim 26, wherein the preservative is potassium sorbate and / or sodium benzoate. A heat-heated fragrance generation source that constitutes a heat-heated fragrance generation cartridge and is an aggregate of the heat-heated fragrance generation base material according to any one of claims 1 to 27. The source for generating aroma to be heated according to claim 28, wherein the base material for generating aroma to be heated is a columnar body or a prismatic body. A heat-heated fragrance generating source constituting the heated fragrance-generating cartridge, wherein the aggregate of the heated fragrance-generating base material according to any one of claims 1 to 27 is a tubular scroll. Aroma generating base material A heated aroma generating source wrapped with a wrapping member. The source for generating aroma to be heated according to claim 30, wherein the base material for generating aroma to be heated is a columnar body or a prismatic body. The heated fragrance source according to any one of claims 28 to 31 is housed in a tubular body of the heated fragrance cartridge exterior member, and the heated fragrance cartridge exterior member forms a mouthpiece. Heated fragrance cartridge. The heated item according to claim 32, wherein at least one selected from a support member, a cooling member, and a filter member is provided in the longitudinal direction on the mouthpiece formed by the exterior member of the aromatic cartridge to be heated. Fragrance cartridge. A heated fragrance cartridge in which a mouthpiece is attached in the longitudinal direction of the heated fragrance source according to any one of claims 28 to 31, and is housed in a tubular body heated fragrance cartridge exterior member. The heated fragrance cartridge according to claim 34, wherein at least one selected from a support member, a cooling member, and a filter member is provided on the mouthpiece in the longitudinal direction. The heated fragrance according to claim 33 or 35, wherein at least one selected from the support member, the cooling member, and the filter member is wrapped with a mouthpiece wrapping member which is a tubular scroll. cartridge. The heated fragrance cartridge according to claim 36, wherein the support member, the cooling member, and the filter member are individually wound with a mouthpiece wrapping member which is a tubular scroll. Between the source of the aroma to be heated and the mouthpiece, the base material for generating the aroma to be heated, the collapsed material of the base material for generating the aroma to be heated, and the dust generated by the collapsed material into the mouthpiece. The heated fragrance cartridge according to any one of claims 32 to 37, which is provided with a mesh for preventing falling off and scattering. On the surface of the opposite end of the mesh of the heated fragrance generating source, the heated fragrance generating base material, the collapsed material of the heated fragrance generating base material, and the heated smoking tool of the dust generated by the collapsed material. The heated fragrance cartridge according to any one of claims 32 to 38, which is provided with a cover for preventing falling into the chamber and scattering. The heated fragrance cartridge according to claim 39, wherein the cover is provided with a heat source insertion hole for the heat-not-burn smoking device. The heated fragrance cartridge according to claim 32 to 40, wherein the heated fragrance cartridge exterior member is a tubular scroll, which is a wrapping member for the heated fragrance cartridge. The heated fragrance cartridge according to any one of claims 32 to 40, wherein the heated fragrance cartridge exterior member is a tubular housing member. The heated fragrance cartridge according to claim 32, which is a connecting member for the heated fragrance cartridge, which is a tubular housing in which the exterior member of the heated fragrance cartridge is detachably connected at at least one place. The heated fragrance cartridge connecting member has a heated fragrance generating source connecting portion capable of charging the heated fragrance source and a mouthpiece connecting portion capable of forming a mouthpiece, and the heated fragrance generating portion. A tubular housing in which the fragrance source connecting portion and the mouthpiece connecting portion are detachably connected, and the heated fragrance source connecting portion and the heated fragrance source connecting portion in which the heated fragrance source is charged are described. The heated fragrance cartridge according to claim 43, wherein the mouthpiece connecting portion is detachably connected to the mouthpiece. The heated fragrance cartridge according to claim 34, wherein the heated fragrance cartridge exterior member is a tubular housing to which the exterior member is detachably connected at at least one place. The heated fragrance cartridge connecting member has a heated fragrance source connecting portion capable of charging the heated fragrance source and a mouthpiece connecting portion capable of charging the mouthpiece. The heated fragrance source connecting portion and the mouthpiece connecting portion are detachably connected to each other in a tubular housing, and the heated fragrance source connecting portion is charged with the heated fragrance source. The heated fragrance cartridge according to claim 45, wherein the mouthpiece and the mouthpiece connecting portion into which the mouthpiece is mounted are detachably connected to each other. The heated fragrance cartridge according to claim 44 or 46, wherein the mouthpiece connecting portion or the mouthpiece incorporated in the mouthpiece connecting portion includes at least a support member. The heated fragrance cartridge according to claim 44 or 46, wherein the mouthpiece connecting portion or the mouthpiece charged in the mouthpiece connecting portion includes at least a cooling member. The heated fragrance cartridge according to claim 44 or 46, wherein the mouthpiece connecting portion or the mouthpiece charged in the mouthpiece connecting portion includes at least a filter member. The mouthpiece connecting portion or the mouthpiece mounted in the mouthpiece connecting portion includes at least a support member and a cooling member, and the support member and the cooling member are provided from the side of the heating aroma generation source connecting portion. The heated fragrance cartridge according to claim 44 or 46, wherein is arranged in the longitudinal direction. The mouthpiece connecting portion or the mouthpiece mounted in the mouthpiece connecting portion includes at least a support member and a filter member, and the support member and the filter member are provided from the side of the heating aroma generation source connecting portion. The heated fragrance cartridge according to claim 44 or 46, wherein the mouthpiece is arranged in the longitudinal direction. The mouthpiece connecting portion or the mouthpiece incorporated in the mouthpiece connecting portion includes at least a cooling member and a filter member.
The fragrance to be heated cartridge according to claim 44 or 46, wherein the cooling member and the filter member are arranged in the longitudinal direction from the connecting portion side of the fragrance generation source to be heated. The mouthpiece connecting portion or the mouthpiece mounted in the mouthpiece connecting portion includes at least a support member, a cooling member, and a filter member, and the support member, from the side of the heating aroma generation source connecting portion, The heated fragrance cartridge according to claim 44 or 46, wherein the cooling member and the filter member are arranged in the longitudinal direction. According to any one of claims 47 to 53, at least one selected from the support member, the cooling member, and the filter member is wound with a mouthpiece wrapping member which is a tubular scroll. The described fragrance to be heated cartridge. The subject according to claim 47 to 53, wherein the support member, the cooling member, and the filter member constituting the mouthpiece are individually wound with a mouthpiece wrapping member which is a tubular scroll. Heated fragrance cartridge. The mouthpiece connecting portion is from a support member connecting portion into which the support member is charged, a cooling member connecting portion into which the cooling member is charged, and a filter member connecting portion into which the filter member is inserted. The invention according to any one of claims 50 to 53, or claim 55, which comprises at least two connecting portions to be selected, and the at least two connecting portions are arranged in the longitudinal direction and are detachably connected to each other. Heated fragrance cartridge. When the heated fragrance source connecting unit connects the heated fragrance source connecting unit and the mouthpiece connecting unit, the mouthpiece connecting between the heated fragrance source and the mouthpiece. Any of claims 44 to 56, comprising a base material for generating aroma to be heated, a collapsed material of the base material for generating aroma to be heated, and a mesh for preventing the dust generated by the collapsed material from falling off and scattering. The heated fragrance cartridge according to item 1. On the surface of the opposite end of the mouthpiece connecting portion of the heating aroma generating source connecting portion, the heated aroma generating base material, the collapsed material of the heated aroma generating base material, and the dust generated by the collapsed material. The heated fragrance cartridge according to any one of claims 44 to 57, which is provided with a cover for preventing the heat-not-burn smoking device from falling off and scattering into the chamber. The heated fragrance cartridge according to claim 58, wherein the cover is provided with a heat source insertion hole for the heat-not-burn smoking device. The subject according to any one of claims 43 to 59, wherein the detachable connection is any one of fitting, screwing, meshing, and hooking. Heated fragrance cartridge. The heated fragrance cartridge according to any one of claims 43 to 60, wherein the detachable connection is a magnetic force. Mixed powder manufacturing process (AI), in which an aroma source material and / or an aroma agent and a heat-melting substance are mixed.
Cellulose fiber manufacturing process (B) for producing cellulose fibers from fiber plants, and
A material preparation step (CI) that prepares the desired material selected from aerosol formers, air fresheners, molding agents, binders, preservatives, and water.
Aroma generation to be heated is produced from the materials produced in the mixed powder production step (AI), the cellulose fiber production step (B), and the material preparation step (CI). Substrate manufacturing process (D) and
A method for producing a base material for generating aroma to be heated. The mixed powder manufacturing step (AI)
The drying / insecticidal step (A-1) of drying / killing the aroma source material and
A crushing step (A-2) for crushing the aroma source material produced in the drying / insecticidal step (A-1), and a crushing step (A-2).
A crushing step (A-5) for crushing the heat-melting substance and
A compression / shear mixing step (compression / shear mixing step) in which the pulverized product produced in the pulverization step (A-2) and / or the fragrance and the pulverized product produced in the pulverization step (A-5) are compressed / sheared and mixed. A-6) and
A cooling step (A-7) for cooling the mixture produced in the compression / shear mixing step (A-6) to 0 ° C. or lower, and a cooling step (A-7).
A pulverization step (A-8) for pulverizing the mixture cooled in the cooling step (A-7), and a pulverization step (A-8).
With
The cellulose fiber manufacturing step (B)
The squeezing step (B-1) for squeezing the fiber plant and
A crushing step (B-2) for crushing the fiber plant that has undergone the squeezing step (B-1), and a crushing step (B-2).
A boiling step (B-3) of boiling the crushed product produced in the crushing step (B-2), and a boiling step (B-3).
The dehydration / drying step (B-4), in which the boiled product produced in the boiling step (B-3) is dehydrated / dried,
A crushing step (B-5) for crushing the dried product produced in the dehydration / drying step (B-4) is provided.
The step (D) for producing a base material for generating aroma to be heated is
A mixing step (D-1) of mixing the materials produced in the mixed powder manufacturing step (AI), the cellulose fiber manufacturing step (B), and the material preparation step (CI).
The compression / shearing step (D-2) of compressing / shearing the mixture produced in the mixing step (D-1) to form a sheet, and the compression / shearing step (D-2).
A cutting step (D-3) for cutting the sheet produced in the compression / shearing step (D-2), and a cutting step (D-3).
62. The method for producing a heated aroma generating base material according to claim 62. A mixed powder manufacturing process (A-II) in which an aroma source material, an aroma agent, and a heat-melting substance are mixed, and
Cellulose fiber manufacturing process (B) for producing cellulose fibers from fiber plants, and
A material preparation step (C-II) that prepares the desired material selected from aerosol formers, molding agents, binders, preservatives, and water.
Aroma generating group to be heated for producing a heated aroma generating base material from the materials produced in the mixed powder manufacturing step (A-II), the cellulose fiber manufacturing step (B), and the material preparation step (C-II). Material manufacturing process (D) and
A method for producing a base material for generating aroma to be heated. The mixed powder manufacturing step (A-II)
The drying / insecticidal step (A-1) of drying / killing the aroma source material and
A crushing step (A-2) for crushing the aroma source material produced in the drying / insecticidal step (A-1), and a crushing step (A-2).
A mixing step (A-3) in which the heat-melting substance and the fragrance are mixed at a temperature equal to or higher than the melting temperature of the heat-melting substance.
A cooling step (A-4) for cooling the mixture produced in the mixing step (A-3) to 0 ° C. or lower, and a cooling step (A-4).
A pulverization step (A-5) for pulverizing the mixture cooled in the cooling step (A-4), and a pulverization step (A-5).
A compression / shear mixing step (A-6) in which the pulverized product produced in the pulverization step (A-2) and the pulverized product produced in the pulverization step (A-5) are compressed / sheared and mixed.
A cooling step (A-7) for cooling the mixture produced in the compression / shear mixing step (A-6) to 0 ° C. or lower, and a cooling step (A-7).
A pulverization step (A-8) for pulverizing the mixture cooled in the cooling step (A-7) is provided.
The cellulose fiber manufacturing step (B)
The squeezing step (B-1) for squeezing the fiber plant and
A crushing step (B-2) for crushing the fiber plant that has undergone the squeezing step (B-1), and a crushing step (B-2).
A boiling step (B-3) of boiling the crushed product produced in the crushing step (B-2), and a boiling step (B-3).
The dehydration / drying step (B-4), in which the boiled product produced in the boiling step (B-3) is dehydrated / dried,
A crushing step (B-5) for crushing the dried product produced in the dehydration / drying step (B-4) is provided.
The step (D) for producing a base material for generating aroma to be heated is
A mixing step (D-1) of mixing the materials produced in the mixed powder manufacturing step (A-II), the cellulose fiber manufacturing step (B), and the material preparation step (C-II).
The compression / shearing step (D-2) of compressing / shearing the mixture produced in the mixing step (D-1) to form a sheet, and the compression / shearing step (D-2).
A cutting step (D-3) for cutting the sheet produced in the compression / shearing step (D-2), and a cutting step (D-3).
The method for producing an inhomogeneous aroma-generating base material according to claim 64. The step (D) for producing a base material for generating aroma to be heated is
The materials produced in the mixed powder production step (AI) or (A-II), the cellulose fiber production step (B), and the material preparation step (CI) or (C-II) are mixed. Slurry manufacturing process (D'-1) to manufacture slurry
A casting process (D'-2) in which the slurry produced in the slurry manufacturing step (D'-1) is made into a sheet by papermaking, compression, and drying, and
A cutting step (D-3) for cutting the sheet manufactured in the casting process (D'-2), and a cutting step (D-3).
The method for producing a heated aroma generating base material according to claim 63 or 65. Heated aroma generation in which aromatic heat-melted powder containing at least one of the aromatic plant and the air freshener contained in the heat-melting substance produced by the production method according to claims 62 to 66 is uniformly dispersed and present. Base material. The base material for generating aroma to be heated according to claim 67, wherein the minimum outer diameter of the aromatic heat-melted powder is 125 to 355 μm.

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