CN211672458U

CN211672458U - Support member for incense core and incense core having the same

Info

Publication number: CN211672458U
Application number: CN201921507659.0U
Authority: CN
Inventors: 渡边龙志
Original assignee: Toa Industry Co Ltd.
Current assignee: MI RAE TECHNOLOGY Co.,Ltd.
Priority date: 2019-03-31
Filing date: 2019-09-10
Publication date: 2020-10-16
Anticipated expiration: 2029-09-10
Also published as: US20220192263A1; EP3949767A1; WO2020204039A1; TWI752451B; TW202042666A; CN110680018A; EP3949767A4

Abstract

A support for a wick and a wick having the same are provided, wherein the support for a wick stabilizes the flow of aerosol in the wick. A flow channel (301) (flow channel 301A-flow channel 301D) for the through-flow of aerosol passing from the inlet end (300A) toward the outlet end (300B) is provided in the wick support (300). Further, an alternating current space (302) for causing the flow of the aerosol from the aerosol-generating member (110) shown in fig. 1 and 2(a) to the support member (300) to be alternating current is provided at the inlet end of the flow passage (301) of the support member (300). The alternating current space section (302) uniformizes the flow rate and flow velocity of the aerosol from the aerosol generating member (110) toward the support member (300) due to the type and filling amount of the base material (110A) of the aerosol generating member (110), and facilitates the inhalation of the fragrance component from the aerosol generating member (110) by the user.

Description

Support member for incense core and incense core having the same

Technical Field

The utility model relates to a support piece for incense core and incense core with the support piece, which are installed on a heating type incense device.

Background

In recent years, electronic smoking articles are becoming popular (for example, patent documents 1 and 2), which are in line with the smoke suppression tendency and which vaporize tobacco components to inhale them by heating a cartridge containing the tobacco components without a flame.

The electronic cigarette of patent document 1 generates an aerosol containing a tobacco component by inserting a heating element into an aerosol-forming substrate of a cartridge and heating the aerosol-forming substrate. The cartridge has a hollow tubular support supporting the aerosol-forming substrate, the support being subjected to a force to which the cartridge is subjected when the heating element is inserted into the aerosol-forming substrate. Aerosols of tobacco components released from the aerosol-forming substrate by heating pass through the hollow of the support and are sent to a downstream located mouthpiece for inhalation by a user.

Patent document 2 discloses a device for heating a smoking material and an aerosol-cooling member used therefor. The aerosol-cooling member described in patent document 2 is, for example, a one-piece rod having a first end portion and a second end portion, and having a plurality of through holes extending between the first and second end portions.

Documents of the prior art

Patent document

Patent document 1: specification of patent 6000451

Patent document 2: patent publication No. 2017-518041

SUMMERY OF THE UTILITY MODEL

Problem to be solved by utility model

The electronic cigarette of patent document 1 has a problem that it is difficult for a user to inhale a fragrance component due to, for example, unevenness in clogging of a filler as a base material in an aerosol-forming base material. For example, due to the unevenness of clogging in the longitudinal direction of the filler and the unevenness in the cross section perpendicular thereto, the flow rate and the flow velocity of the aerosol of the tobacco component released by heating change with time when the aerosol moves toward the support member, and therefore, in addition to the unevenness with time or the time difference, the aerosol has a large flow rate and a high flow velocity only in the through hole region as compared with other portions, and the flow rate from the other regions is small and the flow velocity is low, so that it is difficult to inhale the aromatic component at a uniform flow rate and flow velocity.

Similarly, the aerosol cooler described in patent document 2 has a problem that since a plurality of through holes having the same diameter extend straight between the first end and the second end of the monolith rod, the flow of aerosol in the aerosol cooler tends to become unstable. In the respective plural through holes (flow channels), there is a similar time difference with respect to the individual flow channels, and in addition, there is a difference in place between the flow channels, so that it is difficult to suck the aromatic components in a stable state.

Further, in the electronic cigarette of patent document 1, in addition to being difficult to inhale, there is a problem that the inside of the aerosol-forming substrate is subjected to an excessively high load when the heating element is inserted into the aerosol-forming substrate. In this case, too high a load may make the insertion difficult, and the cartridge may be bent during the insertion, and the heating element itself may be broken.

The present invention has been made in order to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a support member for an electronic cigarette replaceable cartridge, which can stabilize the flow of aerosol in the electronic cigarette replaceable cartridge.

In addition, another object of the present invention is to provide a support member which, while ensuring a flow path for transporting aerosol in an electronic cigarette cartridge, also stably supports an aerosol-forming substrate when a heating element is inserted, and which, while not causing a problem in the electronic cigarette itself due to the defective insertion of the heating element, does not cause a defect in the cartridge.

Moreover, a further object of the present invention is to make it easy to insert a cartridge when the electronic cigarette is used, and to improve operability.

Means for solving the problems

Hereinafter, the electronic cigarette and the electronic cigarette replaceable cartridge are referred to as a heating type incense burner and an incense core, respectively. This is not to be limited to the smoking in the present invention, which is based on the smoking of an aerosol generated by heating an aerosol-forming substrate containing a tobacco component and an aerosol molded body formed by rolling the aerosol-forming substrate with the paper, but is also based on the enjoyment of the aerosol aroma generated by heating an aerosol-forming substrate containing no tobacco component and an aerosol molded body (however, an article called an "electronic cigarette replaceable cartridge" is simply defined as an "electronic cigarette cartridge containing a tobacco component and a core that can be used interchangeably (has interchangeability)" regardless of whether or not the tobacco component is contained). That is, although "smoking" generally means smoking containing nicotine, tar, and the like generated by burning or heating leaves of tobacco of the genus nicotiana of the family solanaceae or a material containing a tobacco component, the meaning of "enjoying smoke", "tasting smoke", and "enjoying smoke" in the present invention is not limited to tobacco leaves or a material containing a tobacco component, and may be used for only a material other than a tobacco material or a material other than a tobacco component. The "smoke" of the present invention includes "visible smoke" and "smoke-like substances" such as droplets dispersed in air, for example, aerosol. The term "aroma" as used herein means "good aroma", and includes a floating aroma (aroma) derived from the raw material itself, a spatial floating aroma (aroma) when heated, a full-bodied floating aroma (aroma) when inhaled, and the like.

According to the present invention, the support member for a incense core is disposed between an aerosol generating member and a filter member in the incense core, and has a flow passage through which an aerosol passes from one end surface of the aerosol generating member side toward the other end surface of the filter member side, and an alternating current space portion which is provided in at least one of an inlet end, an outlet end, and a middle portion of the flow passage and communicates the flow of the aerosol.

In the second embodiment of the present invention, it is also possible that the incense core support has an inlet end space formed by an inlet end position difference between the outer peripheral end of the support on the one end surface side and the inlet end of the flow path.

The support for a wick according to the third embodiment of the present invention may also be such that in the second embodiment, the inlet end position difference is formed by a step difference or inclination between the outer peripheral end of the one end face side of the support and the inlet end of the flow passage.

According to a fourth embodiment of the present invention, in one of the first to third embodiments, it is also possible that the support for a incense core has an outlet end position difference between an outer peripheral end of the other end face side of the support and an outlet end of the flow passage, and the alternating current space portion includes an outlet end space portion formed by the outlet end position difference.

In the fourth embodiment, the support for incense core according to the fifth embodiment of the present invention may be such that the outlet end position difference is formed by a step difference or inclination between the outer peripheral end of the other end face side of the support and the outlet end of the flow passage.

In the incense core support according to the sixth embodiment of the present invention, in one of the first to fifth embodiments, a midway space portion that is continuous with the flow path and has a larger cross-sectional area than the flow path may be present midway in the flow path, and the alternating current space portion may include the midway space portion.

In the incense core support according to the seventh embodiment of the present invention, it is also possible in one of the first to sixth embodiments that the flow path has a plurality of flow paths having different cross-sectional areas from each other.

In the incense core support according to the eighth embodiment of the present invention, in one of the first to seventh embodiments, it is possible that an outer peripheral member for forming an outer periphery of the support is further provided, and the flow path and the alternating current space portion are formed by a space portion in which no support forming material exists in the outer peripheral member.

In the eighth embodiment, the outer peripheral member may be integrally formed with the incense core support member according to the ninth embodiment of the present invention.

The support for incense core according to the tenth embodiment of the present invention may be one of the first to seventh embodiments, wherein the flow passage is a hollow through hole formed in the support.

A support for a incense core according to an eleventh embodiment of the present invention is arranged between an aerosol-generating member and a filter member in the incense core, and has a support surface for directly or indirectly supporting the aerosol-generating substrate and a flow passage through which an aerosol passes from one end surface on the aerosol-generating member side toward the other end surface on the filter member side, and the support surface may also have a first support surface and a second support surface downstream of the first support surface.

In the eleventh embodiment, the incense core support according to the twelfth embodiment of the present invention may be configured such that the second support surface is contiguous to the first support surface.

In the eleventh or twelfth embodiment, the incense core support according to the thirteenth embodiment of the present invention may be such that the second support surface is a support surface formed by a step difference.

In the incense core support according to the fourteenth embodiment of the present invention, it is also possible that in one of the eleventh to thirteenth embodiments, the first support surface or the second support surface is symmetrical about a central axis in the longitudinal direction of the aerosol-forming substrate.

In the incense core support according to the fifteenth embodiment of the present invention, in one of the eleventh to fourteenth embodiments, the area ratio of the second support surface to the first support surface may be 0.25 times or more and 4.0 times or less.

According to a sixteenth embodiment of the present invention, the support for a incense core is disposed between the aerosol-generating member and the filter member in the incense core, and has a support surface for directly or indirectly supporting the aerosol-forming base material and a flow passage through which the aerosol passes from one end surface of the aerosol-generating member side toward the other end surface of the filter member side, the support surface having an inclined surface with respect to a surface perpendicular to a central axis in a longitudinal direction of the aerosol-forming base material.

The support for incense core according to the seventeenth embodiment of the present invention may be arranged in the sixteenth embodiment such that the flow passage includes a hollow through hole formed in the support.

In the fifteenth or seventeenth embodiment, the incense core support according to the eighteenth embodiment of the present invention may be configured such that the flow path includes a flow path formed in a peripheral portion of the support member.

In the incense core support according to the nineteenth embodiment of the present invention, it is also possible that the flow path is provided on the downstream side of the inclined surface in one of the eleventh to eighteenth embodiments.

The support for incense core according to the twentieth embodiment of the present invention is also applicable to the sixteenth to nineteenth embodiments, wherein the inclined surface is symmetrical about the central axis.

In the support for incense core according to the twenty-first embodiment of the present invention, it is also possible that in one of the sixteenth to twentieth embodiments, an inclination angle of the inclined surface with respect to the vertical surface is 4 degrees or more.

The support for a incense core according to a twenty-second embodiment of the present invention may be applied to one of the sixteenth to twenty-first embodiments, wherein the inclined surface includes an inclined surface with respect to an insertion direction of the heating element when the heating element is inserted into the aerosol-generating substrate for heating.

A incense core according to a twenty-third embodiment of the present invention has the aerosol-generating member, the filter member, and the support member for incense core of one form of the first to twenty-second embodiments.

A incense core according to a twenty-fourth embodiment of the present invention in the twenty-third embodiment is also possible to provide a restriction member for restricting a passage area of the aerosol from the aerosol-generating member.

A incense wick according to a twenty-fifth embodiment of the present invention is also possible in the twenty-fourth embodiment, wherein the restriction member has an opening sized to allow the aerosol to pass through but restrict the aerosol generating member from passing through.

Effect of the utility model

According to the utility model discloses a support for incense core obtains following effect, can realize the stabilization of the aerosol flow in the incense core, and the aromatic composition that the user inhales in the aerosol becomes easy.

Further, in the case where the alternating-current space portion is provided at the inlet end of the flow passage of the support, there is obtained an effect that, when the heating element provided in the heating type fumigator main body is inserted into the aerosol-generating member, an excessive load applied to the inside of the aerosol-generating member by the heating element can be reduced.

The support for a wick according to the present invention can provide a support that stably supports an aerosol-generating substrate when a heating element is inserted, while ensuring a flow path for transporting aerosol released by the aerosol-generating substrate in the wick, but that does not cause a bad defect on the wick due to the insertion of the heating element.

According to the utility model discloses a support for incense core can make the core insert easily when adding hot type incenses utensil main part and use, further improves the operability.

Drawings

Fig. 1 is a sectional view showing an example of a usage form of the incense core.

FIG. 2 is a sectional view showing an example of a structure of a incense core.

Fig. 3 is a view showing one example of a substrate manufactured as an aerosol-generating member.

Fig. 4 is a view showing an example of a method of manufacturing the incense core.

Fig. 5A and 5B are views illustrating a support for a incense core according to the first embodiment.

Fig. 6 is a view illustrating a support for a wick according to the first embodiment.

Fig. 7 is a view illustrating a support for a wick according to the first embodiment.

FIG. 8 is a view illustrating a support for incense cores according to the second embodiment.

FIG. 9 is a view illustrating a support for incense cores according to the second embodiment.

FIG. 10 is a view illustrating a support for incense cores according to the second embodiment.

Fig. 11 is a view illustrating a support for a wick according to a third embodiment.

Fig. 12 is a view illustrating a support for a wick according to a third embodiment.

Fig. 13 is a view illustrating a support for a wick according to a third embodiment.

Fig. 14 is a view illustrating a support for a wick according to a third embodiment.

Fig. 15 is a view illustrating a support for a wick according to a third embodiment.

Fig. 16 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 17 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 18 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 19 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 20 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 21 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 22 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 23 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 24 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 25 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 26 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 27 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 28 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 29 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 30 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 31 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 32 is a view illustrating a support for a wick according to a fourth embodiment.

Fig. 33 is a view illustrating a support for a wick according to a fourth embodiment.

Detailed Description

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In addition, the following description will be made mainly of the range necessary for explaining the object of the present invention in terms of modes, and the range necessary for explaining the above-described portions of the present invention will be described, and the description will be omitted based on the known art.

Fig. 1 shows one usage form of the incense core of the present embodiment. The wick 100 is mounted to the heating type fumigator main body 200 when the user uses it. The heating type incense device main body 200 is provided with an insertion port 210 into which the incense core 100 is inserted.

A heating element 211 is provided in the heating type fumigator main body 200. The heating element 211 has a needle-like or blade-like member with a sharpened front end, and is inserted into the aerosol-generating member 110 of the incense wick 100 and heats the aerosol-generating member 110. Specifically, the heating element 211 pierces a substantially central portion of the aerosol generating member 110 when the wick 100 is inserted into the insertion port 210 of the heated fumigator main body 200. In the illustrated example, the heating element 211 may have one or more pointed or blade-like portions.

The heating element 211 directly generates heat or indirectly generates heat by electric power supplied from a battery (not shown) built in the heating type fumigator main body 200. The aerosol-generating member 110 is heated by the heat generation of the heating element 211, thereby generating an aerosol containing a fragrant component.

The generated aerosol is then sent to the filter 130 also serving as a mouthpiece through the support member 300 and the transport member 120 in the incense core 100 described below, and is inhaled from the filter 130 side by the user, whereby the aromatic components reach the oral cavity of the user.

FIG. 2(A) shows an example of the structure of the incense core 100 shown in FIG. 1. In the incense core 100, the aerosol-generating member 110, the support member 300, the conveying member 120, and the filter member 130 are arranged in this order from the side where the heating element 211 (fig. 1) is inserted.

The support 300, which is arranged adjacent to the aerosol-generating member 110, is a member that supports the aerosol-generating member 110, with its sides meeting the peripheral member 140 provided at the periphery of the incense wick 100. The outer peripheral member 140 is a member for packing the incense core 100, and is integrally formed so as to cover the outer periphery of the incense core 100.

The support 300 is suitably made of, for example, silicone, but is not limited to silicone, and other materials excellent in heat resistance may be used. The transport element 120 is a member having a function for cooling the aerosol sent from the support 300 to the filter element 130.

As shown in fig. 2(B), instead of extending the filter member 130 without the delivery member 120, the filter member 130 may have an aerosol cooling function. Thus, the ventilation property in the incense core 100 is improved, the aromatic components in the aerosol can be easily absorbed, and the number of parts of the incense core 100 can be reduced.

Further, as shown in fig. 2(C), by providing the baffle 170 between the aerosol-generating member 110 and the support member 300, it is possible to avoid a problem that the aerosol-generating member 110 moves in the incense core 100 due to vibration during transportation or the like. The material of the barrier 170 is, for example, a material that is damaged when the heating element is inserted into the aerosol-generating device 110 (fig. 1), such as paper or a filter material having good air permeability.

As shown in fig. 2(D), a cap 180 may be provided on the side of the aerosol generating member 110 into which the heating element 211 (fig. 1) is inserted. Accordingly, while the escape of the aromatic component in the aerosol-generating member 110 can be suppressed, the disadvantage that the aerosol-generating member 110 falls off the incense core 100 due to vibration during transportation or the like can be avoided. Examples of the material of the cap 180 include paper, filter material, and sponge. Furthermore, by providing one or more cut-outs in a portion of the cover 180, insertion of the heating element 211 into the aerosol generating member 110 (fig. 1) is facilitated by providing circular or polygonal guide holes. As shown in fig. 2(E), the aerosol-cooling function may be provided to the support 300 by extending the support 300 in the configuration of fig. 2 (B).

As shown in fig. 3, it is preferable that the base material 110A constituting the aerosol-generating member 110 is filled with a material having a rod-like or rectangular shape along the longitudinal direction of the aerosol-generating member 110, so that the aerosol airflow is stabilized and the inhalation of the fragrant component by the user is facilitated.

Fig. 4 shows a state in which the side portions (outer circumferential portions) of the aerosol-generating material 110, the carrier 300, the conveyor 120, and the filter 130 shown in fig. 2 a are wound into a rod shape by an outer circumferential material 140 such as cigarette paper. The outer peripheral member 140 is fixed to the respective sides of the aerosol-generating member 110, the support member 300, the transport member 120, and the filter member 130, for example, by an adhesive. As the base material 110A constituting the aerosol-generating member 110, the following non-tobacco plants were used.

The non-tobacco plant to be the substrate 110A is not particularly limited if it is a nicotine-free plant other than tobacco. As the site to be used for the plant, various sites such as roots (including scale roots (bulbs), tuberous roots (tubers), bulbous roots, etc.), stems, tubers, barks (including bark, etc.), leaves, flowers (including flowers, pistils, stamens, etc.), trunks, branches, etc. can be used.

Examples of bulbs include onion, lycoris radiata, tulip, hyacinth, garlic, shallot, lily, examples of bulbs include saffron, gladiolus, oriental iris, taro, and konjac, examples of tubers include konjac, cyclamen, anemone, begonia, mannan, potato, and koelreuteria paniculata, examples of rhizomes include canna, nelumbo nucifera, and ginger, examples of tuberous roots include dahlia, sweet potato, and sweet potato, examples of jerusalem tubers include dioscorea (yams, natural potatoes, and yams), and examples of tubers include turnip, burdock, carrot, radish, and arrowroot. Examples of the stem include asparagus, bamboo shoot, udo, radish, and yacon.

In the above-mentioned potatoes or plants as exemplified below, a carbohydrate is contained, which is preferably used as a material for at least a part of the base material 110A. Examples of the starch include corn starch, potato starch, sweet potato starch, tapioca starch, and the like, and the starch is used as a thickener, a stabilizer, and the like. These starches can improve acid resistance, heat resistance, shear resistance, etc. by crosslinking, improve esterification, improve storage stability by esterification, promote gelatinization, etc., and improve transparency, film forming property, and storage stability by acidification.

Tamarind gum, guar gum, and locust bean gum can be obtained from plant seeds, gum arabic and karaya gum can be obtained from sap, pectin can be obtained from fruits, cellulose, konjac polysaccharides containing agarose as main ingredient, and soybean polysaccharides can be obtained from other plants. In addition, it can be used as a modified product like a cationized guar gum.

Three kinds of carrageenan, i-carrageenan and lambda-carrageenan, agar and alginic acid, can be obtained from seaweed, and can also be used as carrageenan metal salt and sodium alginate.

Specific examples of the plants used as herbs and spices include gardenia fruit, leaf of hornet orange, zingiber mioga, mugwort, behenic, caraway seed, aniseed, alfalfa, echinacea, allium subagirardium, artemisia selengensis, withered flower, elder, jamaica pepper, orris root, mentha, orange peel, orange flower, orange leaf, cayenne pepper, chamomile german, chamomile, cardamom, curry leaf, garlic, camphor grass, fennel, caraway seed, cumin, fennel seed, clove, cardamom, green pepper, corn flour, saffron, cedar, cinnamon bark, jasmine, juniper berry, cardamom, ginger, fennel, spearmint, sumac, sage, savory, celery seed, turmeric, thyme, tamarind, tarragon, shallot, chives, and spice, Cumin, cumin seed, tomato (dried tomato), canary bean, dried caraway, nutmeg, hibiscus, kawasabi, (mexico) paprika, bird eye pepper, basil, vanilla, caraway, parsley, paprika powder, hyssop, esperage pepper, pink pepper, fenugreek, fennel, palmetto, black cardamom, black cumin, black pepper, vetiver, pulegone, peppermint, horseradish, white pepper, white mustard, poppy seed, boletus edulis, oregano mustard seed, cantaloupe pepper, calendula, chamomile, nutmeg bark, yarrow flower, eucalyptus, lavender, licorice, linden, red clover, red pepper, lemon grass, lemongrass, lemon verbena, lemon peel, rose bud (purple), rose hip, rosemary, red rose, bay, sesame (raw sesame), long pepper, sesame (raw sesame), and sesame, Fried sesame), yellow pepper, prickly ash, Sanying pepper, Japanese pepper, hot pepper, orange, etc. Further, a mixture of various plants used as a mixed spice (for example, five spice powder, Indian spicy spice powder, Morocco mixed spice, artichoke flavor seasoning, curry chicken mixed spice, swallow curry powder, tetra spice, and purowax vanilla) and a bouquet, etc. may be used.

Furthermore, for example, peach, blueberry, lemon, orange, apple, banana, pineapple, mango, grape, kumquat, melon, plum, almond, cocoa, coffee bean, peanut, sunflower, olive, walnut, other edible nut fruits (flesh portions) and seeds can be used.

Tea can also be used. Tea is not only different in tea plant but also different in processing method even for the same plant. Specifically, for example, japanese tea, black tea, angelica keiskei koidzumi, gancha, gynostemma pentaphylla tea, aloe tea, ginkgo leaf tea, oolong tea, turmeric tea, quercus robur tea, acanthopanax tea, plantain tea, desmodium tea, persimmon leaf tea, chamomile tea, cassia tora tea, rose tea, chrysanthemum tea, gymnema sylvestre tea, guava tea, wolfberry tea, mulberry leaf tea, black bean tea, geranium nepalense tea, brown rice tea, burdock tea, broomrape tea, queen tea, kumquat tea, saffron tea, shiitake tea, perilla tea, jasmine tea, ginger tea, field horsetail tea, grassleaf sweelflag rhizome tea, coptis chinensis tea, buckwheat tea, aralia tea, dandelion tea, sweet tea, suaeda tea, eucommia tea, sword bean tea, elderberry tea, japanese hairy deerhorn tea, coix tea, cassia seed, loquat leaf, pu's tea, pine needle, yerba mate tea, sun tea, maple tea, sun tea, ginseng tea, japanese hairy antler tea, japanese green tea, japanese white fungus tea, japanese green tea, etc., kombu, Eucalyptus globulus tea, fructus Momordicae tea, Aspalathus linearis, and fructus Momordicae Charantiae tea. The tea shell after drinking can also be used in these teas. If a tea shell or the like is used, it is effective to reuse expensive tea or the like.

Examples of the plants usable in the above description include kelp, and other plants may of course be ulva, hypnea, horny seaweed, porphyra, gelidium, gracilaria, laminaria japonica, ecklonia cava, laminaria japonica, charomida tenuifolia, botrytis longipedicularis, swamp crassus, porphyra yezoensis, palmaria palmata, norops japonica, melaleuca, gelidium amansii, laminaria tomentosa, wakame, pellaginella, carrageen, green laver, euglena japonica, wakame roots, nemacystus, and undaria pinnatifida.

Specific examples of plants that can be used as described above include brown rice, and as other varieties of rice, the imprinted elite rice (indian type, continental type, long grain type), the palea rice (african rice), the asian rice (asian rice), the java rice (java type, tropical island type, large grain type), the japanese rice (japanese type, temperate island type, short grain type), and the african new rice (hybrid of asian rice and african rice) can be used as well as powder or bran.

Further, specific examples of usable plants include barley, and it is needless to say that millet, oat (cultivar of wild oat), barley, wild oat, millet, duck grass, wheat, barley, oats, rye, oats,

seed, teff, yugu, rye (barley variety), coix seed (not fruit), barnyard grass, fonio rice, wild rice stem, waxy wheat (waxy seed of barley), sorghum (sorghum bicolor, milo), corn, rye.

Examples of plants that can be used include black beans, and as other examples of the soybean hulls (leguminosae), red beans, carob beans, peas, pigeon peas, guar beans, lathyrium sativum, black beans, cowpeas, winged beans, hard underground beans, broad beans, soybeans, phaseolus calcaratus, jack beans, tamarind beans, broad beans, sword beans, lathyrium sativum, bambara peanuts, chickpeas, lentils, red beans, lentils, black beans, groundnuts, mung beans, lupines, lentils, and lentils can be used.

In addition, buckwheat is given as a specific example of a usable plant, and amaranth (amaranth, millettia paniculata), quinoa, and tartary buckwheat can be used as an example of other plants.

In addition, specific examples of usable plants include shiitake mushrooms, and specific examples of mushrooms include matsutake, shiitake mushroom, tricholoma matsutake, truffle, mushroom, and shiitake mushroom.

In addition, aromatic trunks and branches such as sugarcane (sugar cane), beet, cypress, pine, cedar, cypress, camellia, and sandalwood, and barks, leaves, and roots thereof can also be used. Ferns, moss, etc. may also be used as non-tobacco plants. As the plant, for example, a byproduct and squeezed residue (lees and squeezed residue of grapes (composed of grape skin, seeds, fruit stalks, etc.)) in the production of fermented wine such as japanese wine and wine can be used. Further, the above plants may be used in combination. It goes without saying that plants other than those exemplified herein can also be used.

In addition, what is known as a Chinese medicine is also preferably used. For example, the following: bluegrass, madder root, mallotus tree, oriental stephania root, benzoin, clematis root, artemisia capillaris thumb, fennel, turmeric, dark plum fruit, combined spicebush root, sea cucumber, bearberry, fruit of Chinese camphol, corydalis tuber, fortune's-tenuifolia herb, astragalus root, scutellaria root, sealwort, phellodendron bark, coptis root, cherry skin, small forsythia fruit, polygala root, sophora flower, longstamen onion bulb, selfheal, myrobalan fruit, polygonum multiflorum, zedoary, wrinkled gianthyssop herb, kudzu vine root, chrysanthemum flower, snakegourd root, snakegourd seed, dried ginger, licorice, coltsfoot flower, Chinese mugwort leaf, platycodon root, trifoliate orange fruit, bitter orange fruit, chrysanthemum, tangerine peel, notopterygium root, almond, kumquat, honeysuckle flower, longhairy antenoron herb, medlar, boxthorn leaf, lightyellow sophora root, walnut tree bark, chinaberry bark, pink herb, mustard spike, bay, cassia seed, kaladana, figwort root, acacia bark, rosewood, rose, Great burdock achene, Chinese magnoliavine fruit, Chinese thorowax root, manchurian wildginger, crocus sativus, glabrous greenbrier rhizome, wild hawthorn fruit, gardenia jasminoides fruit, dogwood, subprostrate sophora, spina date seed, pricklyash peel, common burreed rhizome, common yam rhizome, rehmannia root, aster, Chinese wolfberry root-bark, sinkiang arnebia root, perilla fruit, perilla leaf, tribulus fruit, kaki calyx, belvedere fruit, white paeony root, common cnidium fruit, straight ladybell root, plantain seed, villous amomum fruit, heartleaf houttuynia herb, ginger, palm fruit, palm leaf, largetrifoliolious bugbane rhizome, wheat, calamus root, biond magnolia flower, glossy privet fruit, ash bark, large-leaved gentian, motherwort fruit, pricklyash peel, green tangerine peel, grassleaf sweetflag rhizome, pomegranate bark, dendrobium, szechuan lovage rhizome, peucedanum root, common nux herb, inula flower, elderberry fruit, tsaoko-ko fruit, Chinese honeylocust spine, parasitic bamboo leaf, sib, Uncaria, dried orange peel, arisaema consanguineum, gastrodia elata, cochinchnese asparagus root, Chinese waxgourd seed, Chinese angelica, castor bean, codonopsis pilosula, rush, peach kernel, orange peel, Chinese dodder seed, seed, eucommia ulmoides, pubescent angelica root, radix trichosanthis, desertliving cistanche, nutmeg, honeysuckle, ginseng, fritillaria, malt, platycladi seed, white hyacinth bean, dwarf lilyturf tuber, fructus psoraleae, mint, guava, pinellia ternate, fructus nasutus, isatis root, barbed skullcap herb, lily root, angelica dahurica, oldenlandia diffusa, radix stemonae, bighead atractylodes rhizome, betel nut, radix stephaniae tetrandrae, lalang grass rhizome, divaricate saposhnikovia root, cattail pollen, dandelion root, moutan bark, ephedra, fructus cannabis, fructus viticis, pine resin, akebia stem, papaya, elecampane, alpinia japonica, tuber fleeceflower, momordica grosvenori, bluebear.

Further, the extract of the non-tobacco plant exemplified above, that is, the so-called extract, may be used, and the form of the extract may be, for example, liquid, syrup, powder, granule, solution, or the like.

The detailed structure of the support member 300 of the incense core 100 shown in FIGS. 1 and 2(A) to 2(E) will be described below. Although the following embodiment describes an example in which the incense core 100 has the structure shown in fig. 2(a), the structure of the support member 300 can be applied to the case where the incense core 100 has the structure shown in fig. 2(B) to 2 (E).

First embodiment

The support 300 of the present embodiment has the following features as shown in fig. 5A and 5B. The support member 300 has an inlet end 300A (see fig. 5(a)) on the aerosol-generating member 110 side as shown in fig. 1 and 2(a) and an outlet end 300B (see fig. 5(B)) on the transport member 120 side.

A flow passage 301 (flow passage 301A to flow passage 301D) through which the aerosol passing from the inlet end 300A to the outlet end 300B flows is provided in the cylindrical side portion (outer circumferential portion) of the support 300. The number of the flow paths 301 is four in the illustrated example, but may be three or less or five or more.

The four flow paths 301A to 301D are constituted by a plurality of flow paths having different cross-sectional areas from each other. In the illustrated example, the cross-sectional areas of the

flow channels

301A and 301C are smaller than the cross-sectional areas of the

flow channels

301B and 301D.

At an inlet end 300A of the flow passage 301 of the holder 300, an alternating current space portion 302 for allowing an aerosol to flow through and communicate from the aerosol-generating member 110 toward the holder 300 as shown in fig. 1 and 2(a) is provided. Specifically, a step (inlet end position difference) is provided between the inlet end 300A of the support 300 and the inlet end of the flow channel 301 (see fig. 5 a), and the ac space 302 is formed by an inlet end space formed by the step. On the other hand, a flat continuous surface having no step (outlet end position difference) is formed between the outlet end 300B of the support 300 and the outlet end of the flow channel 301 (see fig. 5B).

The flow path 301 and the ac space 302 are formed in the incense core 100 by a space portion where the outer peripheral member 140 (see fig. 2 a) does not contain the constituent material of the support member 300. Further, an outer peripheral member forming only a part of the outer periphery of the support member 300 may be formed integrally with the support member 300.

In this way, by providing the alternating-current space section 302 for allowing the aerosol to flow through alternating current at the inlet end 300A of the flow passage 301 of the support 300, the aerosol from the aerosol-generating member 110 toward the support 300 temporarily stays in the alternating-current space section 302 in terms of time and space, and then flows into the flow passages 301A to 301D.

This provides an effect that the aerosol is uniformized in the ac space portion 302 even when the time and place are different due to the unevenness in the flow rate and the flow velocity of the aerosol from the aerosol-generating member 110 toward the support member 300 caused by the type, the filling amount, and the like of the base material 110A of the aerosol-generating member 110, and thereby the aerosol flow through the support member 300 is stabilized, and the user can easily inhale the fragrant component from the aerosol-generating member 110.

As described above, in the present embodiment, since the cross-sectional areas of the flow passages 301A to 301D are made different from each other, the flow rate and the flow velocity of the aerosol flowing through the support 300 vary for each of the flow passages 301A to 301D. This has the effect that the through-flow of aerosol through the support 300 and towards the transport element 120 becomes more stable.

Also, in the case where the ac space portion 302 is provided at the inlet end of the flow path of the supporter 300, when the heating element 211 provided in the heating type fumigator main body 200 shown in fig. 1 is inserted into the aerosol-generating member 110, an excessive load applied to the aerosol-generating member 110 by the heating element 211 can be reduced.

In the present embodiment, the ac space 302 is formed by an inlet end space formed by a step difference between the inlet end 300A of the support 300 and the inlet end of the flow channel 301, but the ac space 302 may be formed by an outlet end space formed by a step difference provided between the outlet end 300B of the support 300 and the outlet end of the flow channel 301. Further, the ac space portion 302 may be formed at both the inlet end 300A side and the outlet end 300B side of the supporter 300.

Fig. 6 shows an example in which a restricting member 150 for restricting the passage region of aerosol from the support member 300 toward the transport member 120 (refer to fig. 1 and 2(a)) is provided at the inlet end 300A of the support member 300.

The stopper 150 is formed of a thin plate having a plurality of small-sized openings 151 for allowing the aerosol to pass therethrough, and is fitted into the ac space 302 of the holder 300. When the restriction member 150 is fitted into the ac space portion 302, one or more protrusions 303 supporting the restriction member 150 are provided on the inlet end 300A side of the support member 300, and the ac space portion 302 occurs between the restriction member 150 and the inlet end of the flow passage 301.

By providing the stopper 150, it is possible to prevent a defect that a part of the base material 110A of the aerosol-generating member 110 leaks out on the side of the support 300 and is inhaled by the user.

Further, the stopper 150 may be provided flush with the inlet end 300A, but may be provided at an intermediate position in the depth direction of the ac space portion 302 by height adjustment of the plurality of protrusions 303. At this time, slight protrusion (bulging) of the base material 110A of the aerosol-generating member 110 which occurs when the heating element 211 penetrates is easily allowed without becoming overloaded.

Although the restriction member 150 may be provided on the outlet end 300B side of the support member 300, it is preferably provided in the ac space portion 302 in view of easy attachment.

In the example shown in fig. 5A and 5B, the inlet-end space formed by the step difference (inlet-end position difference) between the inlet end 300A of the support 300 and the inlet end of the flow channel 301 is taken as the alternating-current space section 302, but it is also possible to provide an inclination between the inlet end 300A of the support 300 and the inlet end of the flow channel 301 as shown in fig. 7, and the inlet-end space formed by the inclination is taken as the alternating-current space section 302.

Fig. 7(a) shows an example in which the outermost periphery of the inlet end 300A of the support member 300 is inclined toward the center, and fig. 7(B) shows an example in which the outermost periphery of the inlet end 300A is formed in a flat surface and is inclined toward the center from the inner side thereof, but in any case, the same effects as those of the example shown in fig. 5A and 5B can be obtained. Here, although illustration is omitted, in the form shown in fig. 7, the restricting member 150 that restricts the aerosol passage region may be provided at the inlet end 300A of the support member 300 as in the form shown in fig. 6. In this case, by using the inclination in fig. 17 and 19 as in the following example, the protrusion 303 in fig. 6 may not be provided, and the alternating-current space portion 302 may also occur between the restriction member 150 and the inlet end of the flow passage 301. Further, by using the inclination, it is possible to easily set the ac space portion 302 at the middle position in the depth direction as well as flush with the entrance end 300A.

An example of the dimensions of the support 300 shown in fig. 5A and 5B is shown in table 1. The dimensions of the support member 300 shown in table 1 are an example of the optimum dimensions, but are actually obtained as a function of the type and number of the substrates 110A of the aerosol-generating member 110, and the like. Here, the material of the support 300 is composed of silicone and has a diameter of 6.93 mm. The diameters of the

flow paths

301B and 301D are 2.50 mm, respectively, and the diameters of the

flow paths

301A and 301C are 2.20 mm, respectively.

TABLE 1

Second embodiment

The support member 400 of the present embodiment has the following features as shown in fig. 8. The support member 400 has an inlet end 400A (see fig. 8 a) on the aerosol-generating member 110 side as shown in fig. 1 and 2 a and an outlet end 400B (see fig. 8B) on the transport member 120 side.

A flow passage 401 (flow passage 401A-flow passage 401D) through which aerosol flows from the inlet end 400A toward the outlet end 400B is provided in the support 400. The number of the flow passages 401 penetrating the support 400 is four in the illustrated example, but may be three or less or five or more.

The four flow paths 401A to 401D are constituted by a plurality of flow paths having different cross-sectional areas from each other. In the illustrated example, the cross-sectional areas of the

flow channels

401A and 401C are smaller than the cross-sectional areas of the

flow channels

401B and 401D.

At the inlet end of the flow channel 401 of the holder 400, an alternating current space 402 is provided for allowing an aerosol to flow through and communicate from the aerosol-generating member 110 to the holder 400 as shown in fig. 1 and 2 (a). Specifically, a step (inlet end position difference) is provided between the inlet end 400A of the support 400 and the inlet end of the flow channel 401 (see fig. 8 a), and the ac space 402 is formed by an inlet end space formed by the step. On the other hand, a flat continuous surface having no step (outlet end position difference) is formed between the outlet end 400B of the support 400 and the outlet end of the flow channel 401 (see fig. 8B).

This provides an effect that the aerosol flow-through is stabilized by providing the alternating-current space 402 for allowing the aerosol to flow through the alternating-current space at the inlet end of the flow passage 401 of the holder 400, and the user can easily inhale the fragrant components from the aerosol-generating member 110.

In the present embodiment, the alternating-current space portion 402 is formed by an inlet end space portion formed by a step difference between the inlet end 400A of the support 400 and the inlet end of the flow channel 401, but the alternating-current space portion 402 may be formed by an outlet end space portion formed by a step difference provided between the outlet end 400B of the support 400 and the outlet end of the flow channel 401. In addition, the ac space 402 may be formed on both the inlet end 400A side and the outlet end 400B side of the support 400.

Fig. 9 shows an example in which a restricting member 160 for restricting a passage area of aerosol from the support member 400 toward the transport member 120 (refer to fig. 1 and 2(a)) is provided at the inlet end 400A of the support member 400.

The restricting member 160 is formed of a thin plate having a minute-sized opening 161 that allows the aerosol to pass therethrough, and is fitted into the ac space portion 402 of the holder 400. When the restriction member 160 is fitted into the ac space part 402, one or more protrusions 403 (fig. 9(B)) supporting the restriction member 160 are provided on the inlet end 400A side of the support member 400, and the ac space part 402 is present between the restriction member 160 and the inlet end of the flow passage 401. By providing the restriction member 160, a defect that a part of the base material 110A of the aerosol-generating member 110 leaks out to the support member 300 side can be prevented.

The stoppers 160 may be provided flush with the inlet end 400A, as with the stoppers 150, or may be provided at an intermediate position in the depth direction of the ac space 402, so that the slight protrusion (bulge) of the base material 110A generated when the heating element 211 penetrates can be easily allowed, in addition to preventing the base material 110A from coming off and moving.

The stopper 160 may be provided on the outlet end 400B side of the support member 400, that is, on the ac void part 402 side, but is preferably provided in the ac void part 402 in view of easy attachment.

In the example shown in fig. 8, the inlet-end space formed by the step difference (inlet-end position difference) between the inlet end 400A of the support 400 and the inlet end of the flow channel 401 is the ac space 402, but as shown in fig. 10, an inclination may be provided between the inlet end 400A of the support 400 and the inlet end of the flow channel 401, and the inlet-end space formed by the inclination may be the ac space 402. Although not shown, the restricting member 160 may be provided at the inlet end 400A or the outlet end 400B of the support member 400 in the embodiment shown in fig. 10, as in the embodiment shown in fig. 9. In this case, since the inclination is used, the alternating current space 402 can be generated between the stopper 160 and the inlet end of the flow path 401 without providing the protrusion 403 in fig. 9, and since the inclination is used, the alternating current space can be easily provided not only flush with the inlet end 400A but also at an intermediate position in the depth direction of the alternating current space 402.

Third embodiment

As shown in fig. 11, the support member 500 of the present embodiment has an inlet end 500A on the aerosol-generating member 110 side as shown in fig. 1 and 2(a) and an outlet end 500B on the transport member 120 side. Further, a flow passage 501 through which the aerosol passes from the inlet end 500A to the outlet end 500B is provided in the support 500.

As shown in fig. 11(a), an alternating-current space 502 for restricting an aerosol passage region is provided in the middle of the flow channel 501 of the support 500. Specifically, a step is provided in the middle of the flow channel 501, and the ac space 502 is formed by a middle space formed by the step.

By providing the alternating-current space portion 502 for allowing the aerosol to flow in alternating current in the middle of the flow passage 501 of the holder 500, the aerosol flow through the holder 500 is stabilized, and the user can easily inhale the fragrant components from the aerosol-generating member 110.

As shown in fig. 11(B), in the supporter 500 of the present embodiment as well, similarly to the first and second embodiments, by providing the stopper 160 having the plurality of openings 161 in the ac space portion 502, it is possible to prevent a defect that a part of the base material 110A of the aerosol-generating material 110 leaks out to the supporter 500 side. The restricting member 160 may also be disposed adjacent to the aerosol-generating member 110 (refer to fig. 1 and 2) on the inlet end 500A side of the supporting member 500.

In the example shown in fig. 11, the alternating current space 502 is defined as a space formed by a step in the middle of the flow path 501, but as shown in fig. 12, the alternating current space 302 may be defined as a space formed by an inclination in the middle of the flow path 301.

In the case of the form of the first embodiment shown in fig. 5A and 5B, the outer peripheral side of the inlet end 300A of the support member 300 protrudes further on the aerosol-generating member 110 side than on the center side, but as shown in fig. 13(a), a structure is also possible in which the center side of the inlet end 300A of the support member 300 protrudes further on the aerosol-generating member 110 side than on the outer peripheral side.

Similarly, in the case of the form shown in fig. 7 of the first embodiment, the outer peripheral side of the inlet end 300A of the holder 300 protrudes further toward the aerosol-generating member 110 than toward the center, but as shown in fig. 13, a structure is also possible in which the center of the inlet end 300A of the holder 300 protrudes further toward the aerosol-generating member 110 than toward the outer peripheral side.

The shape of the

support

300, 400, 500 is not limited to the shape defined in the above example, and various design changes are possible. For example, as shown in fig. 14 and 15, the support member 300 may have a spherical outer periphery of the inlet end 300A. The outer peripheral side of the inlet end 300A protrudes more toward the aerosol-generating member 110 than toward the center in the support 300 shown in fig. 14, and the center of the inlet end 300A protrudes more toward the aerosol-generating member 110 than toward the outer peripheral side in the support 300 shown in fig. 15.

Fourth embodiment

In the first to third embodiments, the form in which four flow paths are provided on the support member is explained, but in the present embodiment, the form in which 1 or 2 flow paths are provided on the support member while an alternating-current space portion is provided at the inlet end of the support member is described. In all the drawings for describing the following embodiments, components having the same functions are denoted by the same reference numerals in principle, and redundant description thereof will be omitted.

In fig. 16, there are shown oblique, front, side and bottom views of one form of the support 600. Fig. 16 is a form in which a flow channel 601 is provided at the center of a cylindrical bearing member 600, an inclination is provided between the inlet end of the bearing member 600 and the inlet end of the flow channel 601, and an inlet end space portion formed by the inclination is an alternating current space portion 602.

Fig. 17 shows a form in which a restricting member 190 for restricting a passage region of aerosol from the support member 600 toward the transport member 120 (refer to fig. 1 and 2(a)) is provided at the inlet end of the support member 600 shown in fig. 16. Fig. 17(a) shows an example in which the regulating member 190 is provided at the outermost periphery of the inlet end of the support member 600, and fig. 17(B) shows an example in which the regulating member 190 is provided at a position closer to the central portion (the flow passage 601) than the outermost periphery of the inlet end of the support member 600.

The stopper 190 may be a thin plate provided with a plurality of small-sized openings 191 that allow the aerosol to pass therethrough (fig. 17C), or may be a member having a lattice-shaped frame 192 (fig. 17D). In the case of the restricting member 190 shown in fig. 17(D), the function for restricting the passing region of the aerosol from the aerosol-generating member 110 toward the support member 600 is weak, so that an effect of reducing the excessive load that the heating element 211 gives to the aerosol-generating member 110 when the heating element 211 provided in the heated fumigator main body 200 shown in fig. 1 is inserted into the aerosol-generating member 110 is obtained.

In fig. 18, oblique, front, side, top and bottom views of one form of the support 600 are shown. Fig. 18 shows a configuration in which the outermost peripheral portion of the inlet end of the cylindrical bearing member 600 is formed as a flat surface, and an inclination is provided from the inner side thereof toward the center direction, so that the inlet end space portion formed by the inclination is an alternating-current space portion 602.

Fig. 19 shows a form of providing the restricting member 190 at the inlet end of the supporting member 600 shown in fig. 18. Fig. 19 a shows an example in which the stopper 190 is provided at the outermost periphery of the inlet end of the bearing member 600, and fig. 19B shows an example in which the stopper 190 is provided at a portion closer to the central portion (the flow path 601) than the outermost periphery of the inlet end of the bearing member 600.

The stopper 190 may be a thin plate having a plurality of small-sized openings 191 that allow the passage of aerosol, as shown in fig. 19(C), or may be a member having a lattice-shaped frame 192, as shown in fig. 19 (D).

In fig. 20, there is shown a front, side and bottom view of one form of supportable member 600. Fig. 20 shows a configuration in which an inlet end of a cylindrical support 600 is provided with an inclination from two directions toward a flow channel 601, and an inlet end space formed by the inclination is an alternating-current space 602.

In fig. 21, a front, side and bottom view of one form of the support 600 is shown. Fig. 21 shows a configuration in which a part of the inlet end of the cylindrical bearing 600 is provided with an inclination from one direction toward the flow path 601, and the inlet end space formed by the inclination is an alternating-current space 602.

In fig. 22, there are shown oblique, front, side and bottom views of one form of the support 600. Fig. 22 shows a configuration in which an inlet end of the cylindrical support 600 is provided with an inclination that extends from two directions toward the flow channel 601 and protrudes from the aerosol-generating member 110 (fig. 1 and 2 a) toward the center side than toward the outer peripheral side, and an inlet end space formed by the inclination is an alternating-current space 602.

In fig. 23, there are shown front, side, top and bottom views of one form of the support 600. Fig. 23 is a form in which 2 flow paths 601 are provided on a cylindrical support member 600 while an inlet end of the support member 600 is cut into an inclined surface, and an inlet end space portion thus formed is an alternating-current space portion 602.

In fig. 24, there are shown oblique, front, side and bottom views of one form of the support 600. Fig. 24 shows a configuration in which 2 flow paths 601 are provided in a cylindrical support member 600, and an inclination from two directions toward the flow paths 601 is provided at the inlet end of the support member 600, and the inlet end space formed by the inclination is an alternating-current space portion 602.

In fig. 25, oblique, front, side and bottom views of one form of the support 600 are shown. Fig. 25 shows a configuration in which 2 flow paths 601 are provided in a cylindrical support member 600, and an inclination from one direction toward the flow paths 601 is provided in a part of an inlet end of the support member 600, and an inlet end space formed by the inclination is used as an alternating current space 602.

In fig. 26, oblique, front, side, top and bottom views of one form of the support 600 are shown. Fig. 26 shows a configuration in which 2 flow paths 601 are provided in a cylindrical support member 600, and a basin-like inclination from two directions toward the flow paths 601 is provided at the inlet end of the support member 600, and an inlet end space formed by the inclination is used as an alternating current space portion 602.

A front, side, top and bottom view of one form of the support 600 is shown in fig. 27. Fig. 27 shows a configuration in which 2 flow channels 601 are provided in the cylindrical support member 600, and the inlet end of the cylindrical support member 600 is provided with slopes in two directions, the center portion side of which protrudes further toward the aerosol-generating member 110 (fig. 1 and 2 a) than toward the outer peripheral portion side, and the inlet end space formed by these slopes is an alternating-current space 602.

One form of the support 600 is shown in oblique, front, side, top and bottom views in fig. 28. Fig. 28 shows an embodiment in which 2 flow paths 601 are provided in the cylindrical holder 600, and a conical inclination is provided at the inlet end of the cylindrical holder 600 such that the center portion side protrudes further toward the aerosol-generating member 110 (fig. 1 and 2 a) than the outer peripheral portion side, and the inlet end space formed by the inclination is an alternating-current space 602.

A front, side, top and bottom view of one form of the support 600 is shown in fig. 29. Fig. 29 shows a configuration in which a flow channel 601 is provided at the center of a cylindrical bearing member 600, and an inclination from two directions toward the flow channel 601 is provided at the inlet end of the bearing member 600, and the inlet end space formed by the inclination is an alternating-current space 602.

In fig. 30, there are shown oblique, front, side and bottom views of one form of the support 600. Fig. 30 shows a configuration in which a flow channel 601 is provided in the center of a cylindrical holder 600, and a basin-like inclination is provided in a part of the inlet end of the cylindrical holder 600 such that the outer peripheral portion side protrudes from the center portion side toward the aerosol-generating member 110 (fig. 1 and 2 a), and the inlet end space formed by the inclination is used as an alternating-current space 602. The outermost peripheral portion of the inlet end of the holder 600 is inclined like a basin, and the central portion protrudes further toward the aerosol-generating member 110 than toward the outer peripheral portion.

In fig. 31, one form of the support 600 is shown in oblique, front, side, and bottom views. Fig. 31 is a form in which a flow passage 601 is provided in the center of a cylindrical holder 600, and a conical inclination in which the center side protrudes further toward the aerosol-generating member 110 (fig. 1 and 2(a)) than toward the outside is provided at the inlet end of the cylindrical holder 600, and the inlet end space formed by the inclination is used as an alternating-current space 602.

A partial cutaway oblique view of one form of the bearing 600 is shown in fig. 32. Fig. 32 is a form in which 1 flow channel 601 is provided at the center of the cylindrical bearing 600, the cylindrical center part 193 is inserted into the flow channel 601, and an alternating current space part 602 is formed by an inlet end space part formed by a step difference between the inlet end of the bearing 600 and the end of the center part 193.

The central portion 193 is fixed in the flow path 601 by a fixing portion 194 formed integrally with the central portion 193, and the flow path 601 is formed in a gap between the inner peripheral surface of the bearing 600 and the central portion 193.

In the embodiment shown in fig. 32, the inlet end of the support 600 protrudes further on the aerosol-generating member 110 (fig. 1 and 2(a)) side than the end of the central portion 193, but like the form shown in fig. 33, the end of the central portion 193 may also protrude further on the aerosol-generating member 110 side than the inlet end of the support 600.

In the present embodiment, an alternating-current space portion 602 for allowing aerosol to flow through alternating current is provided at the inlet end of the flow channel 601 of the support 600, and thus aerosol heading from the aerosol-generating member 110 to the support 300 temporarily stays in the alternating-current space portion 302 for a certain time and space and then flows into the flow channel 601.

Accordingly, the conventional time-varying unevenness, time difference, or area unevenness caused by the time-varying changes in the flow rate and flow velocity of the aerosol due to the unevenness caused by the clogging state of the filler as the base material in the aerosol-forming base material is uniformized by the ac space portion 602. This achieves the effect that the aerosol through-flow through the support 600 becomes stable and it becomes easy for the user to inhale the fragrance composition from the aerosol generating member 110.

In addition, in order to solve the conventional problem that the aerosol-forming substrate is subjected to an excessive load when the heating element is inserted into the aerosol-forming substrate, in addition to the difficulty in inhalation, the flow path for transporting the aerosol in the heating type incense core is ensured, and the excessive load is prevented by stably supporting the aerosol-forming substrate when the heating element is inserted, thereby achieving the effect that the insertion of the heating element becomes easy and the operability can be improved.

The present invention has been described above based on embodiments thereof, but the present invention is not limited to the embodiments, and it goes without saying that various modifications are possible without departing from the gist thereof.

Description of the reference numerals

100 incense core

110 an aerosol-generating member

110A base material

120 conveying member

130 filter element

140 outer peripheral member

150 limiting piece

151 opening

160 limiting piece

161 opening

170 baffle

180 cap

190 limiting piece

191 opening

192 frame portion

193 center part

194 fixed part

200 heating type fumigator main body

210 insertion opening

211 heating element

300 support

300A inlet end

300B outlet end

301 flow passage

301A flow passage

301B flow channel

301C flow passage

301D flow channel

302 alternating current space part

303 of protrusion

400 support

400A inlet end

400B outlet end

401 flow channel

401A flow channel

401B flow channel

401C flow channel

401D flow channel

402 alternating current space part

403 protrusion

500 support member

500A inlet end

500B outlet end

501 flow channel

600 bearing

601 flow channel

602 alternating current space section.

Claims

1. A support member for a wick, characterized in that it is disposed between an aerosol-generating member and a filter member in the wick, and has a flow passage through which an aerosol flows, which passes from one end surface on the side of the aerosol-generating member toward the other end surface on the side of the filter member, and an AC space portion which is provided at least one of an inlet end, an outlet end and a middle portion of the flow passage and through which the aerosol flows in AC.

2. The incense core support member of claim 1, wherein an inlet end position difference exists between the outer peripheral end of the support member on the one end surface side and the inlet end of the flow path, and the ac space portion includes an inlet end space portion formed by the inlet end position difference.

3. The incense core support member of claim 2, wherein the inlet end position difference is formed by a step or inclination between the outer peripheral end of the support member on the one end surface side and the inlet end of the flow channel.

4. The incense core support member according to any one of claims 1 to 3, wherein there is an outlet end position difference between the outer peripheral end of the support member on the other end surface side and the outlet end of the flow path, and the alternating current space portion includes an outlet end space portion formed by the outlet end position difference.

5. The incense core support member of claim 4, wherein the outlet end position difference is formed by a step difference or inclination between an outer peripheral end of the support member on the other end surface side and an outlet end of the flow passage.

6. The incense core supporter as claimed in claim 1, wherein a middle space portion which is connected to the flow path and has a larger cross-sectional area than the flow path is present in the middle of the flow path, and the alternating current space portion includes the middle space portion.

7. The wick support of claim 1, wherein the flow channel has a plurality of flow channels having different cross-sectional areas.

8. The incense core supporter according to claim 1, further comprising an outer peripheral member forming an outer periphery of the supporter, wherein the flow path and the ac space portion are formed by a space portion in the outer peripheral member where the supporter forming material is absent.

9. The wick support of claim 8, wherein the peripheral member is integrally formed.

10. The support for incense cores of claim 1 wherein the flow channel is a hollow through hole formed in the support.

11. A support member for a wick, characterized in that it is arranged between an aerosol-generating member and a filter member in the wick, and has a support surface for directly or indirectly supporting the aerosol-generating substrate and a flow path for through-flow of the aerosol passing from one end surface on the side of the aerosol-generating member toward the other end surface on the side of the filter member, and the support surface has a first support surface and has a second support surface downstream of the first support surface.

12. The wick support of claim 11, wherein the second support surface is contiguous with the first support surface.

13. The wick support of claim 11 or claim 12, wherein the second support surface is formed by a step difference.

14. The wick support of claim 11, wherein the first or second support surface is symmetrical about a longitudinal center axis of the aerosol-forming substrate.

15. The incense core supporter of claim 11 wherein the area of the second supporting surface is 0.25 to 4.0 times larger than the area of the first supporting surface.

16. A support member for a wick, characterized in that it is disposed between an aerosol-generating member and a filter member in the wick, and has a support surface for directly or indirectly supporting the aerosol-forming base material and a flow passage for through-flow of the aerosol passing from one end surface on the side of the aerosol-generating member toward the other end surface on the side of the filter member, the support surface having an inclined surface with respect to a surface perpendicular to a central axis in a longitudinal direction of the aerosol-forming base material.

17. The wick support of claim 16, wherein the flow channel comprises a hollow bore formed therein.

18. The wick support of claim 16 or claim 17, wherein the flow channel comprises a flow channel formed in a peripheral portion of the support.

19. The wick support of claim 16, wherein the flow channel is provided on a downstream side of the ramp.

20. The wick support of claim 16, wherein the inclined surface is symmetrical about the central axis.

21. The incense core supporter of claim 16, wherein the inclined surface is inclined at an angle of 4 degrees or more with respect to the plane perpendicular to the central axis of the aerosol-forming substrate in the longitudinal direction.

22. The wick support of claim 16, wherein the ramp comprises a ramp surface opposite the direction of insertion of the heating element into the aerosol-forming substrate when heated by insertion of the heating element.

23. A incense core comprising an aerosol generating member, a filter member and a support member for an incense core according to any one of claims 1 to 22.

24. The incense core of claim 23 further comprising a restriction member for restricting the area through which the aerosol from the aerosol generating member passes.

25. The incense core of claim 24 wherein the restriction member has an opening sized to allow the aerosol to pass through but restrict the aerosol generating member from passing through.