WO2020204039A1 - Support member for aroma cartridge, and aroma cartridge provided with same - Google Patents

Abstract

This support member 300 for an aroma cartridge is provided with a flow channel (301) (flow channel 301A to flow channel 301D) for the throughflow of an aerosol that passes from an entrance end 300A toward an exit end 300B. In addition, an interchange space section 302 is provided at the entrance end of the flow channel 301 of the support member 300 for causing the interchange of the throughflow of the aerosol from a heated aroma generation source 110 illustrated in fig. 1 and 2(A), toward the support member 300. The interchange space section 302 equalizes differences in the flow rate and the flow speed of the aerosol from the heated aroma generation source 110 toward the support member 300 caused by the type of base material 110A or the filling amount, etc. of the heated aroma generation source 110, thereby causing a user to easily inhale the aroma component from the heated aroma generation source 110. Stabilization of the flow of the aerosol, stable support of the base material of the heated aroma generation source when inserting a heating element, and ease of operability when inserting the cartridge are improved by using ID chip information.

Description

Support member for fragrance cartridge and fragrance cartridge equipped with it

The present invention relates to a support member for an fragrance cartridge used by being attached to an fragrance tool, and an fragrance cartridge provided with the support member.

In recent years, in line with the tendency to quit smoking, air freshener products that vaporize tobacco components by heating an aromatic cartridge containing tobacco components without using a flame and suck the tobacco components have become widespread (for example, patent documents). 1, 2).

The fragrance tool of Patent Document 1 inserts a heating element into the heated fragrance source of the fragrance cartridge and heats the heated fragrance source to generate an aerosol containing a tobacco component. The fragrance cartridge has a hollow tubular support element that supports the heated fragrance source, which resists the force that the fragrance cartridge receives as the heating element is inserted into the heated fragrance source. The aerosol of the tobacco component released from the heated fragrance source by heating passes through the hollow portion of the support element, is transferred to the mouthpiece located downstream, and is sucked by the user.

Patent Document 2 discloses a device for heating a smoking material and an aerosol cooling member used for the device. The aerosol cooling member described in Patent Document 2 is, for example, a monolithic rod having first and second ends, and has a plurality of through holes extending between the first and second ends.

The above-mentioned "aerosol-forming base material" is inserted into a heating element and heated to volatilize not only the aerosol former that forms the aerosol but also the fragrance component of the fragrance source material and the fragrance agent, and the smoke of the aerosol and the fragrance source material. In the present invention, it is referred to as a "heated aerosol generating base material" because the scent of the air freshener and the fragrance can be enjoyed by smoking. Based on this, the "aerosol-forming body" filled with the aerosol-forming substrate is the "heated aroma generator", the "electronically compatible cigarette cartridge" and the "cartridge" equipped with the aerosol-forming body are the "fragrance cartridge", and "Electronic cigarette" is called "fragrance".

Japanese Patent No. 600451 Special Table 2017-518401

The fragrance tool of Patent Document 1 has a problem that it becomes difficult for the user to inhale the fragrance component due to non-uniformity due to clogging of the filler which is the base material in the heated fragrance source. For example, when the aerosol of the tobacco component released by heating moves to the support element due to the non-uniformity of the packing in the longitudinal direction or the non-uniformity in the cross section orthogonal to the non-uniformity, the flow rate and the flow velocity of the aerosol. In addition to the fact that the change over time causes non-uniformity or time difference over time, the flow rate of the aerosol is higher and the flow velocity is higher only in the through-hole region than in other parts, whereas it is It was difficult to suck in the aroma component uniformly with the flow rate and the flow velocity due to regional non-uniformity such as extremely low flow rate and low flow velocity and locational differences.

Similarly, in the aerosol cooling member described in Patent Document 2, since a plurality of through holes having the same diameter extend linearly between the first and second ends of the monolithic rod, the aerosol cooling member is also used. There is a problem that the flow of the aerosol inside tends to be unstable. In addition to the same time difference for a single flow path in each of the multiple through holes (flow paths), there is also a locational difference between the flow paths, so the aroma component should be sucked in in a stable state. Was difficult.

Further, in the fragrance tool of Patent Document 1, in addition to the difficulty of sucking, there is a problem that an excessive load is applied to the inside of the heated fragrance source when the heating element is inserted into the non-heated fragrance source. In this case, the excessive load not only makes the insertion difficult, but also causes the fragrance cartridge to bend at the time of insertion, and sometimes the heating element itself may be damaged.

On the other hand, there are many types of heated fragrance sources of fragrance cartridges. In addition, the components differ depending on the manufacturer. In addition, the aroma component at the time of inhalation may differ depending on the surrounding environment such as ambient temperature and humidity.
However, in Patent Document 1 and Patent Document 2, since heating is not controlled according to the type of the heated fragrance source and the surrounding environment, it is difficult to suck the fragrance component in a more stable state.

The present invention has been made 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 aromatic cartridge capable of stabilizing the flow of aerosol in the aromatic cartridge. It is in.

Another object of the present invention is to secure a flow path through which the aerosol is transferred in the fragrance cartridge of the fragrance, and to stably support the heating fragrance source when the heating element is inserted. It is an object of the present invention to provide a support member which does not cause a problem in the fragrance cartridge by insertion and does not cause a problem in the fragrance main body.

Further, an object of the present invention is to facilitate the insertion of the fragrance cartridge and improve the operability when using the fragrance tool.

Furthermore, an object of the present invention is to perform appropriate heating control according to the type of heated fragrance source of the fragrance cartridge, the surrounding environment, etc., so that the fragrance component at the time of suction is in an appropriate state.

The support member for the fragrance cartridge according to the first aspect of the present invention is arranged between the heated fragrance source and the filter member in the fragrance cartridge, and the filter member is arranged from one end surface on the heated fragrance source side. It is provided at least one of the flow path of the passing flow of the aerosol passing toward the other end surface on the side and the inlet end, the exit end and the middle part of the flow path, and exchanges the passing flow of the aerosol. It has an exchange space part.

In the first aspect, the support member for the fragrance cartridge according to the second aspect of the present invention has an inlet end position difference between the outer peripheral end of the support member on the one end surface side and the inlet end of the flow path. The AC space portion may include an entrance end space portion formed by the entrance end position difference.

In the support member for the fragrance cartridge according to the third aspect of the present invention, in the second aspect, the difference in the entrance end position is between the outer peripheral end on the one end surface side of the support member and the inlet end of the flow path. It may be formed by a step or slope between them.

In any one of the first to third aspects, the support member for the fragrance cartridge according to the fourth aspect of the present invention has the outer peripheral end on the other end surface side of the support member and the outlet end of the flow path. There is an outlet end position difference between them, and the AC space portion may include an outlet end space portion formed by the outlet end position difference.

In the support member for the fragrance cartridge according to the fifth aspect of the present invention, in the fourth aspect, the outlet end position difference is between the outer peripheral end on the other end surface side of the support member and the outlet end of the flow path. It may be formed by a step or slope between them.

In any one of the first to fifth aspects, the support member for the fragrance cartridge according to the sixth aspect of the present invention is connected to the flow path in the middle of the flow path and is connected to the flow path. There is an intermediate space portion having a wide cross-sectional area, and the AC space portion may include the intermediate space portion.

In the support member for the fragrance cartridge according to the seventh aspect of the present invention, in any one of the first to sixth aspects, the flow paths may have a plurality of flow paths having different cross-sectional areas from each other. Good.

In any one of the first to seventh aspects, the support member for the fragrance cartridge according to the eighth aspect of the present invention further includes an outer peripheral member constituting the outer periphery of the support member, the flow path and the said. The AC space portion may be formed by a space portion in the outer peripheral member in which a constituent member of the support member does not exist.

In the eighth aspect of the support member for the fragrance cartridge according to the ninth aspect of the present invention, the outer peripheral member may be integrally formed.

In the support member for the fragrance cartridge according to the tenth aspect of the present invention, in any one of the first to seventh aspects, the flow path may be a hollow through hole formed in the support member. Good.

The support member for the fragrance cartridge according to the eleventh aspect of the present invention is arranged between the heated fragrance source and the filter member in the fragrance cartridge, and is a support surface that directly or indirectly supports the aerosol-generating base material. And the flow path of the passing flow of the aerosol passing from one end surface on the heated aroma generation source side toward the other end surface on the filter member side, and the support surface is the first support surface. A second support surface may be provided on the downstream side of the first support surface.

In the eleventh aspect of the support member for the fragrance cartridge according to the twelfth aspect of the present invention, the second support surface may be connected to the first support surface.

In the eleventh or twelfth aspect of the support member for the fragrance cartridge according to the thirteenth aspect of the present invention, the second support surface may be formed through a step.

In the support member for the fragrance cartridge according to the fourteenth aspect of the present invention, in any one of the eleventh to thirteenth aspects, the first support surface or the second support surface is the source of the heated fragrance. It may be symmetrical about the central axis in the longitudinal direction.

In the support member for the fragrance cartridge according to the fifteenth aspect of the present invention, in any one of the eleventh to fourteenth aspects, the area ratio of the second support surface to the first support surface is 0. It may be .25 times or more and 4.0 times or less.

The support member for the fragrance cartridge according to the sixteenth aspect of the present invention is arranged between the heated fragrance source and the filter member in the fragrance cartridge, and is a support surface that directly or indirectly supports the heated fragrance source. And the flow path of the passing flow of the aerosol passing from one end surface of the heated fragrance generation source side toward the other end surface of the filter member side, and the support surface is the longitudinal length of the heated fragrance generation source. It has an inclined surface with respect to a surface perpendicular to the central axis of the direction.

The support member for the fragrance cartridge according to the seventeenth aspect of the present invention may include a hollow through hole formed in the support member in the sixteenth aspect.

In the fifteenth or seventeenth aspect of the support member for the fragrance cartridge according to the eighteenth aspect of the present invention, the flow path may include a flow path formed in the peripheral portion of the support element.

The support member for the fragrance cartridge according to the nineteenth aspect of the present invention may have the flow path on the downstream side of the inclined surface in any one of the eleventh to eighteenth aspects.

The support member for the fragrance cartridge according to the twentieth aspect of the present invention may have the inclined surface symmetrical about the central axis in any one of the sixteenth to nineteenth aspects.

In any of the 16th to 20th aspects, the support member for the fragrance cartridge according to the 21st aspect of the present invention has an inclination angle of the inclined surface with respect to the vertical surface of 4 degrees or more. Good.

The support member for the fragrance cartridge according to the 22nd aspect of the present invention has the inclined surface in any one of the 16th to 21st aspects when the heating element is inserted into the aerosol generating base material and heated. May include an inclined surface with respect to the insertion direction of the heating element.

The support member for an fragrance cartridge according to any one of claims 1 to 22 according to the 23rd aspect of the present invention is an ID cover capable of detecting ID information that can distinguish the fragrance cartridge from other types of different fragrance cartridges. It may have a detection unit.

The fragrance cartridge according to the 24th aspect of the present invention includes the heated fragrance source, the filter member, and a support member for the fragrance cartridge according to any one of the first to 23rd aspects.

The fragrance cartridge according to the 25th aspect of the present invention may further have a regulating member that limits the passage region of the aerosol from the heated fragrance source in the 23rd aspect.

In the fragrance cartridge according to the 26th aspect of the present invention, in the 24th aspect, the regulating member has an opening having a size that allows the passage of the aerosol and restricts the passage of the fragrance source to be heated. You may have.

The support member for the fragrance cartridge according to the 27th aspect of the present invention has an ID detected portion capable of detecting ID information that can distinguish the fragrance cartridge from other types of different fragrance cartridges.

In the support member for the fragrance cartridge according to the 28th aspect of the present invention, the ID detected unit has an ID storage means for storing the ID information.

The support member for an fragrance cartridge according to any one of claims 26 to 29 according to the 29th aspect of the present invention has an ID presenting unit for presenting the ID information.

The fragrance cartridge according to the thirtieth aspect of the present invention has a heated fragrance source, a filter member, and a support member for the fragrance cartridge.

The fragrance cartridge according to claim 30 according to the 31st aspect of the present invention further includes a regulating member that limits the passage region of the aerosol from the fragrance source to be heated.

The fragrance cartridge according to claim 31 of the 32nd aspect of the present invention has an opening of a size that allows the passage of the aerosol and restricts the passage of the fragrance source to be heated.

The 33rd fragrance tool of the present invention includes the fragrance cartridge according to any one of claims 30 to 32.
It includes an ID detection unit for detecting the ID information, a heating unit for applying heat to the heated fragrance generation source, and a control unit for controlling the ID detection unit and the heating unit.

In the 34th fragrance tool of the present invention, the ID detection unit is arranged around the mounting portion of the fragrance cartridge, and the control unit is based on the ID detection information from the ID detection unit. It has a distance detection function capable of detecting a distance, and further, the control unit acquires the ID information based on the ID detection information, and also from the distance between each unit around the mounting unit and the ID detected unit. Grasp the mounting state of the fragrance cartridge.

According to the 35th aspect of the present invention, the ID detection unit has a plurality of ID sub-detection units around the mounting unit, and the ID detected unit is the plurality of ID sub-detection units. It has a plurality of ID detected units corresponding to.

According to the fragrance tool of the 36th aspect of the present invention, the fragrance tool has a support member for the fragrance cartridge arranged between the heated fragrance source and the filter member in the fragrance cartridge.
The support member for the fragrance cartridge has an ID detected portion capable of detecting ID information that can distinguish the fragrance cartridge from other types of different fragrance cartridges.

According to the support member for the fragrance cartridge of the present invention, it is possible to stabilize the flow of the aerosol in the fragrance cartridge, and it is possible to obtain the effect that the user can easily inhale the fragrance component in the aerosol.

Further, when the AC space portion is provided at the inlet end of the flow path of the support member, the heating element is covered when the heating element provided inside the fragrance body is inserted into the heated fragrance generation source. The effect of being able to reduce the excessive load applied to the inside of the heated aroma generation source can be obtained.

According to the support member for the fragrance cartridge of the present invention, the aerosol-generating substrate is stably inserted when the heating element is inserted, while ensuring a flow path for the aerosol released from the aerosol-generating substrate to be transferred in the fragrance cartridge. It is possible to provide a support member that does not cause a defect in the aromatic cartridge by inserting the heating element while supporting it.

According to the support member for the fragrance cartridge of the present invention, it is possible to facilitate the insertion of the fragrance cartridge when using the fragrance main body and improve the operability.

Further, according to the fragrance tool of the present invention, by providing a plurality of sensors in the periphery and obtaining the distance from each sensor to the ID chip, the cartridge insertion state (distance to the final insertion position, cartridge central axis and insertion portion) is obtained. Detects deviation from the central axis: detection of tilt, etc.) and facilitates the insertion operation to the center position. Therefore, the IDs of the support member and the cartridge can be detected, the flow of the aerosol is stabilized, the base material for generating the aroma to be heated is stably supported when the heating element is inserted, and the easy operability when the cartridge is inserted is improved. The effect is obtained.

Further, according to the support member for the fragrance cartridge and the fragrance cartridge of the present invention, since the ID chip is provided, it is possible to inform the information of the heated fragrance generating base material of the fragrance cartridge. Furthermore, since it has an ID chip, it is possible to disable the use of fragrance cartridges when different types of fragrance cartridges (for example, different manufacturers) are read from the information stored in the ID chip. Become.

It is sectional drawing which shows an example of the usage form of the fragrance cartridge. It is sectional drawing which shows an example of the structure of the fragrance cartridge. It is a figure which shows an example of the base material manufactured as a source of aroma to be heated. It is a figure which shows an example of the manufacturing method of the fragrance cartridge. It is a figure explaining the support member for the fragrance cartridge which concerns on 1st Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 1st Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 1st Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 2nd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 2nd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 2nd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 3rd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 3rd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 3rd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 3rd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 3rd Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is a figure explaining the support member for the fragrance cartridge which concerns on 4th Embodiment. It is sectional drawing of the fragrance apparatus of 5th Embodiment. It is a perspective view when the ID chip 313 is provided in the support member 300 of FIG. 5 (B). It is a perspective view when the ID chip 313 is provided in the support members 400, 500. It is sectional drawing which shows another example of the usage form of the fragrance cartridge similar to FIG. 34. It is connection block diagram of the control part and each sensor of 5th Embodiment. It is a flowchart (1/2) explaining the processing of the CPU 90 based on the program of the memory 91 of the control unit 9. It is a flowchart (2/2) explaining the processing of the CPU 90 based on the program of the memory 91 of the control unit 9. It is sectional drawing of an example of a specific method for obtaining a distance (insertion distance). It is explanatory drawing of the insertion angle calculation process.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In the following, the range necessary for the explanation for achieving the object of the present invention will be schematically shown, and the range necessary for the explanation of the relevant part of the present invention will be mainly described. It shall be based on known technology.

FIG. 1 shows one usage pattern of the aromatic cartridge of the present embodiment. The fragrance cartridge 100 is attached to the fragrance tool 200 at the time of use by the user. The fragrance tool 200 is provided with an insertion port 210 for inserting the fragrance cartridge 100.

A heating element 211 is provided inside the air freshener 200. The heating element 211 has a pin-shaped or blade-shaped member having a sharp tip, and is inserted into the heated fragrance source 110 of the fragrance cartridge 100 to heat the heated fragrance source 110. More specifically, the heating element 211 is inserted into the substantially central portion of the heated fragrance source 110 when the fragrance cartridge 100 is inserted into the insertion port 210 of the fragrance tool 200. In the illustrated example, the heating element 211 has one pin-shaped or blade-shaped member with a sharp tip, but may be a plurality of members.

The heating element 211 directly or indirectly generates heat by the electric power supplied from the battery (not shown) built in the fragrance 200. The heat generated by the heating element 211 heats the aroma source 110 to be heated, so that an aerosol containing an aroma component is generated.

Then, the generated aerosol is transferred to the filter member 130 which also serves as a mouthpiece via the support member 300 and the transfer member 120 in the fragrance cartridge 100 described below, and the user sucks the aerosol from the filter member 130 side to fragrance. The ingredients will reach the user's mouth.

FIG. 2A shows an example of the structure of the fragrance cartridge 100 shown in FIG. Inside the fragrance cartridge 100, the fragrance source 110 to be heated, the support member 300, and the transfer members 120 and 130 are arranged in this order from the side where the heating element 211 (FIG. 1) is inserted.

The support member 300 arranged adjacent to the heated fragrance source 110 is a member that supports the heated fragrance source 110, and its side portion is in contact with the outer peripheral member 140 provided on the outer periphery of the fragrance cartridge 100. ing. The outer peripheral member 140 is a member for packaging the fragrance cartridge 100, and is integrally formed so as to cover the outer periphery of the fragrance cartridge 100.

The support member 300 can be preferably formed using, for example, silicone, but the support member 300 is not limited to silicone, and other materials having excellent heat resistance may be used.
The transfer member 120 is a member having a function of cooling the aerosol transferred from the support member 300 to the filter member 130.

As shown in FIG. 2B, instead of omitting the transfer member 120, the filter member 130 may be lengthened so that the filter member 130 has an aerosol cooling function. As a result, the air permeability in the fragrance cartridge 100 is improved, the fragrance component in the aerosol can be easily sucked, and the number of parts of the fragrance cartridge 100 can be reduced.

Further, as shown in FIG. 2C, by interposing the partition wall member 170 between the heated fragrance source 110 and the support member 300, the heated fragrance source 110 becomes the fragrance cartridge 100 due to vibration during transportation or the like. It is possible to avoid the problem of moving inside. Examples of the material of the partition wall member 170 include a material that is destroyed when the heating element 211 (FIG. 1) is inserted into the heated aroma generation source 110, such as paper having good air permeability and a filter.

Further, as shown in FIG. 2D, a cap 180 may be provided on the side where the heating element 211 (FIG. 1) of the fragrance generating source 110 to be heated is inserted. As a result, it is possible to suppress the dissipation of the fragrance component in the fragrance source 110 to be heated, and it is possible to avoid the problem that the fragrance source 110 to be heated falls off to the outside of the fragrance cartridge 100 due to vibration during transportation or the like. .. Examples of the material of the cap 180 include paper, a filter, a sponge, and the like. By making one or more cuts in a part of the cap 180 or providing a circular or polygonal guide hole, the heating element 211 (FIG. 1) can be easily inserted into the heated fragrance generation source 110. Become.

Further, as shown in FIG. 2 (E), the support member 300 may be lengthened in the structure of FIG. 2 (B) so that the support member 300 has an aerosol cooling function.

As shown in FIG. 3, as the base material 110A constituting the heated fragrance source 110, a rod-shaped or strip-shaped one is preferably filled along the longitudinal direction of the heated fragrance source 110. As a result, the air flow of the aerosol is stabilized, and the user can easily inhale the aromatic component.

FIG. 4 shows a rod formed by winding the side portion (outer peripheral portion) of the heated fragrance source 110, the support member 300, the transfer member 120, and the filter member 130 shown in FIG. 2A with an outer peripheral member 140 such as cigarette paper. It shows how to do it. The outer peripheral member 140 is fixed to each side of the heated fragrance source 110, the support member 300, the transfer member 120, and the filter member 130, for example, with an adhesive.

Further, as the base material 110A constituting the heated fragrance source 110, the non-tobacco plants illustrated below are used.

The non-tobacco plant used as the base material 110A is not particularly limited as long as it is a non-nicotine-containing plant other than tobacco. Examples of parts used by plants include roots (including scale roots (scales), tubers (potatoes), bulbs, etc.), stems, tubers, barks (including stem bark, bark, etc.), leaves, flowers (petals, petals, etc.). Various parts such as pistil, male tuber, etc.), tree trunks and branches can be used.

As bulbs, onion, higanbana, tulip, hyacinth, garlic, rakkyo, lily, as bulbs, crocus, gradiolas, freesia, iris, satoimo, konjak, as tubers, konjak, cyclamen, anemone, begonia, chologi, potato, Apios, rhizomes are canna, hass (renkon), ginger, tuberous roots are dalia, sweet potato, cassaba, and tuberous roots are yam (Yamanoimo, natural yam, yam, etc.), Other examples include cubs, yams, carrots, dioscorea japonica, and scraps. Examples of stems include asparagus, bamboo shoots, udo, radish, and yacon.

The potatoes mentioned above or the plants listed below contain carbohydrates and are preferably used as a material for at least a part of the base material 110A. For example, starch includes corn starch (corn), potato starch (potato), kansho starch (sweet potato), tapioca starch (tapioca), and the like, and there are examples of use as a thickener, stabilizer, and the like. These starches have improved acid resistance, heat resistance, share resistance, etc. by cross-linking, storage stability improvement by esterification, etherification, gelatinization promotion, etc., transparency improvement by oxidation, film property improvement, storage stability, etc. It is possible by improving it.

Obtain tamarind seed gum, guar gum, locust bean gum from plant seeds, gum arabic and karaya gum from sap, pectin from fruits, and konjac mannan and soybean polysaccharides mainly composed of cellulose and agarose from other plants. Can be done. Furthermore, it can be modified and used like cationized guar gum.

From seaweed, carrageenan, agar, and alginic acid classified into three types, kappa carrageenan, iota carrageenan, and lambda carrageenan, can be obtained, and they are also used as salts for carrageenan metal salt, sodium alginate, etc.

For example, plants used as herbs and spices include cumin nuts, humpper leaves, myoga, yomogi, wasabi, ajowan seed, anis, alfalfa, echinacea, eshalot, estragon, and everlasting flower. , Elder, All Spice, Oris Root, Oregano, Orange Peel, Orange Flower, Orange Leaf, Cayenne Pepper (Cayenne Pepper), Cayenne German, Cayenne Roman, Cardamon, Curry Leaf, Garlic (Niniku), Cat Nip, Caraway, Caraway Seed, Kinmokusei, Cumin, Cumin Seed, Clove, Green Cardamon, Green Pepper, Cornflower, Saffron, Cedar, Cinnamon, Jasmine, Juniper Berry, Jorokia, Ginger, Star Anis, Spare Mint, Smack, Sage, Seboli ( Cayenne), celery, celery seed, turmeric (cumin), thyme, tamarind, tarragon, charville (selfille), chives, dill, dill seed, tomato (dried tomato), tonka bean, dried pakuchi, nutmeg, hibiscus, habanero, cayenne pepper , Bird's Eye, Basil, Vanilla, Pakuchi (Coriander), Parsley, Paprika, Hisop, Piments Death Pellet, Pink Pepper, Fene Greek Seed, Fennell, Brown Mustard, Black Cardamon, Black Cumin, Black Pepper, Vetiba, Penny Royal, Peppermint ( Cumin), Horse Radish, White Pepper, White Mustard, Poppy Seed, Porcini, Majorum, Mustard Seed, Maniget, Marigold, Malva Flower, Mace, Yarrow Flower, Eucalyptus, Lavender, Licoris, Linden, Red Clover, Red Pepper, Lemon Glass, lemon verbena, lemon balm, lemon peel, rose (rose), rose buds (purple), rose hips, rose petal, rosemary, rose red, laurel (laurier), long pepper, sesame (raw sesame, roasted sesame), golden Peppers, Cayenne pepper, Mitaka, Sansho, Peppers, Yuzu, etc. can be used. In addition, mixed spices (for example, five-spice powder, Garam masala, Rasuel Hanuto, Baligur, chicken curry masala, tandoori masala, cattle epis, Herbes de Provence), and a mixture of various plants used as popli and the like can be used.

Also, for example, edible fruits such as peaches, blueberries, lemons, oranges, apples, bananas, pineapples, mangoes, grapes, kinkans, melons, plums, almonds, cacao, coffee beans, peanuts, sunflowers, olives, walnuts and other nuts. (Fruit part) and seeds can be used.

Also, tea can be used. Not only are the plants that make tea different, but even the same plants are different depending on the processing method. Specifically, for example, Japanese tea, tea, tomorrow's leaf tea, sweet tea, Amachazuru tea, aloe tea, ginkgo leaf tea, oolong tea, corn tea, urajirogashi tea, eleuthero tea, obaco tea, kakiodoshi tea, persimmon leaf tea, Chamomile tea, chamomile tea, Kawahara decision tea, karin tea, chrysanthemum tea, gymnema tea, guaba tea, kuko tea, mulberry leaf tea, black soybean tea, gennoshoko tea, brown rice tea, gobo tea, comfrey tea, kelp tea, Sakura tea, saffron tea, shiitake tea, shiso tea, jasmine tea, ginger tea, sugina tea, sekisho tea, senburi tea, buckwheat tea, taranoki tea, dandelion tea, jincha, dokudami tea, tochu tea, natamame tea, niwatoko tea, Examples include rat mochi tea, hatomugi tea, hub tea, biwa leaf tea, puer tea, red flower tea, pine needle tea, mate tea, wheat tea, megusurinoki tea, yomogi tea, eucalyptus tea, Rakan fruit tea, louis bosti, bitter gourd tea and the like. For these teas, tea leaves after drinking may be used. If tea leaves are used, expensive tea can be reused and effectively utilized.

In the above, kelp was mentioned as a specific example of plants that can be used, but other plants include sea lettuce, seaweed, red seaweed, seaweed, arame, seaweed (rock seaweed), egonori, ogonori, gagome kelp, kajime, ganiashi, and kubirezuta. , Kurome, Kombu, Susabinori, Darus, Chishimakuronori, Tsuruarame, Tengusa, Tororokonbu, Nekoashikonbu, Nori (Nori), Habanori, Hijiki, Hitoegusa, Hirome, Funori, Bowaonori, Makonbu, Mekabu, Mozuku, Wakame Can be done.

Brown rice was mentioned as a specific example of the plants that can be used above, but other varieties of rice include indica (Indica, continental, long grain), Graberima (African rice), Sativa (Asia rice), and Javanica. (Java type, tropical island type, large grain type), Japonica type (Japanese type, temperate island type, short grain type), Nerika (interspecies hybrid of Asian rice and African rice) can also be used naturally, and powder or bran. Can also be used as.

Furthermore, wheat was mentioned as a specific example of plants that can be used, but other examples of wheat include awa, oats (cultivated varieties of crow wheat, both oats), barley (barley), sorghum, sorghum, and sorghum. Cordonbie), wheat (wheat), sorghum, tef, sorghum, barley (variant of barley), sorghum (fruit, not seed), sorghum, phonio, makomo, mochimugi (barley mochi), sorghum (barley, sorghum) , Sorghum), corn, and barley (barley) can of course be used.

Furthermore, black beans were mentioned as a specific example of plants that can be used, but other examples as sword beans (legumes) include bean, sword bean, common bean, pea cluster bean graspy (English: Lathyrus sativus) ketsuru azuki, horse gram, Deer bear, Zeocalpamame, Soramame, Soybean, Takeazuki, Tachinatamame, Tamarind, Tepary bean, Sword bean, Hassho bean (English: Mucuna pruiens), Bambara groundnut, Hiyokomame, Fujimame, Benibanaingen, Horse gram Naturally, Ryokuto, Lupinus, bean, and bean (hento) can also be used.

Furthermore, buckwheat was mentioned as a specific example of plants that can be used, but as examples of other plants, amaranth (Amaranthus, Senninkoku), quinoa, and buckwheat can naturally be used.

Furthermore, shiitake mushrooms were mentioned as specific examples of plants that can be used, but mushrooms include matsutake mushrooms, shiitake mushrooms, hatsake mushrooms, shimeji mushrooms, shouro mushrooms, mushrooms, and agaricus mushrooms.

Also, sugar cane (may be molasses pomace), sugar beet, cypress, pine, cedar, hiba, camellia, ebony and other aromatic tree trunks and branches, their bark, leaves, roots, etc. can also be used. Ferns, mosses, etc. can also be used as non-tobacco plants. As a plant, for example, by-products and pomace (consisting of sake lees, grape pomace (consisting of grape skins, seeds, fruit stems, etc.)) in producing fermented sake such as sake and wine can also be used. Furthermore, the various plants described above may be mixed and used. Of course, plants other than those listed here can also be used.

Furthermore, what is known as a Chinese herbal medicine is also preferably used. For example: Indigo grass (Isou), Akane (Akanekon), Akame Kashiwa (Akamega wrinkle), Asenyaku (Asenyaku), Ansokukou (Ansokukou), Coptis chinensis (Ireisen), Akane Chenkou (Inchinkou), Akane (Uikyo), Turmeric ), Ubai, Uyaku, Urajirogashi, Uwaurushi, Agetsu, Engosaku, Coptis chinensis, Coptis chinensis, Coptis chinensis, Coptis chinensis (Osei), Coptis chinensis, Coptis chinensis, Coptis chinensis, Ohi, Otogirisou, Onji, Kaika, Gaihaku, Kagosou, Lycium chinense (Kashi), Coptis chinensis, Zedoary, Lycium chinense, Lycium chinense, Coptis chinensis, Coptis chinensis, Coptis chinensis, Coptis chinensis, Ginkgo biloba , Coptis chinensis, Coptis chinensis, Coptis chinensis, Coptis chinensis, Lycium chinense, Lycium chinense, Lycium chinense, Kikuka, Tachibana bark, Kyokatsu, Kyonin, Kinkan, Kinginka, Kinsensou, Kukoshi, Lycium chinense, Kujin, Coptis chinensis, Coptis chinensis (Coptis chinensis) , Black letters (Kuromoji), Baku (Kubaku), 荊芥 (Keigai), Katsura bark (Keihi), Ketsumeishi (Ketsumeishi), Coptis chinensis (Kengoshi), Coptis chinensis (Genjin), Coptis chinense (Kouika), Red flower (Kouka) Skin (gokanpi), fragrance (wolfberry), scented drum (wolfberry), scented demand (kouju), red ginseng (kojin), zedoary (kobushi), turmeric rice (koubei), koboku (koboku), straw book (kohon) ), Gokahi, Goshitsu, Goshuyu, Gojokon, Goboushi, Gomiko, Saiko, Saishin, Saffron, Sankirai, Sanzashi, Sanshishi, Sanshuyu, Sanzukon, Coptis chinensis, Sansho, Sanryo, Sanyaku (Sanryo) Sanyaku, Jiou, Zion, Jikoppi, Shikon, Shisoshi, Shisoyo, Shitsurishi, Shitei, Jifushi, Shakuyaku, Jashoushi, Shajin, Shazenshi, Shazensou, Shukusha , Juyaku, Ginger, Shurojitsu, Shiroyou, Shouma, Shobaku, Shobukon, Shini, Sadako (Joteishi), Qinpi, Shinkiku, Jingyo, Juuishi, Shokumoku, Seihi, Sekishokon, Ishibane (Sekiryujitsuhi), Ishibuki (Sekoku), Kawayumi (Senkyu), Maehu (Zenko), Riverbone (Senkotsu), Sempukuka, Osteopathic tree (Sekkotsuboku), Grass fruit (Soka), Soukakushi ), Mulberry parasite (Sokisei), Aoiko (Sojishi), Soujutsu, Side Kashiwaba (Sokuhakuyo), Sequel (Zokudan), Mulberry bark (Sohakuhi), Soki (Soboku), Souha (Souyou) , Soukyo, Daiou, Taisou, Daifukuhi, Takusha, Tanjin, Chikujo, Chikusetsu carrot, Bamboo Leaves (Chikuyo), Chimo (Chimo), Jiyu (Chiyu), Chome (Choudge), Tsurifuji (Choutokou), Chenpi (Chinpi), Tennansei (Tennansho), Tenma (Tenma), Tenmon Fuyu (Tenma) Tenmontou), Tougashi, Toki, Tougoma, Toujin, Toshinsou, Tounin, Tohi, Toshishi, Tochinomi, Tochu, Dokkatsu, Dokakon, Nikujuyo, Nikuzuku, Nindou, Carrot, Baimo, Bakuga ), Kashiwako Hitoshi (Hakushinin), Hakuhenzu, Mugimon Fuyu (Bakumontou), Hakoshi (Hakoshi), Light load (Hacka), Buddhist fruit (Banka), Half-summer (Hange), Anti-nose (Hambi) , Banlancon, Hansilen, Yurine, Byakushi, Shirahana Jazetsusou, Hyakubukon, Byakujutsu, Chenpi (Binrouji), Boui, Kayane (Boukon), Windbreak (Boufu), Gamo (Houou), Gamo Koeikon (Hoeikon), Peony bark (Buttonpi), Maou (Maou), Asakojin (Mashinin) Mankeishi, Matsuyani, Mokutsu, Mokka, Mokko, Motsuyaku, Mokuzoku, Yakan, Yakuchi, Night Koto (Yako) Uto, Luo Han Guo, Lansou, Longannik, Ryutan, Ryokyo, Ganoderma lucidum, Forsythia, Forsythia, Lotus Meat (lentian), lychee (locon).

Further, the extract of the non-tobacco plant exemplified above, the so-called extract, can also be used. Examples of the form of the extract include liquid, starch syrup, powder, granules, and solution.

Hereinafter, the detailed structure of the support member 300 of the fragrance cartridge 100 shown in FIGS. 1 and 2 (A) to 2 (E) will be described. In the following embodiment, an example in which the fragrance cartridge 100 has a structure as shown in FIG. 2 (A) will be described, but the structure of the support member 300 is such that the fragrance cartridge 100 has a structure of FIGS. 2 (B) to 2 (B). It can also be applied when the structure is as shown in (E).
(First Embodiment)

As shown in FIG. 5, the support member 300 of the present embodiment has the following features. The support member 300 has a plurality of side portions that are in contact with a central portion located along the central axis in the longitudinal direction of the support member 300 and an outer peripheral member 140 extending outward from the central portion and located at the peripheral edge of the support member 300. The inlet end 300A (see FIG. 5A) located on the heated aroma generation source 110 side shown in FIGS. 1 and 2 (A) and the outlet end 300B located on the transfer member 120 side (see FIG. 5A). (See FIG. 5 (B)).

A cylindrical side portion (outer peripheral portion) of the support member 300 is provided with a flow path 301 (flow path 301A to flow path 301D) for the passing flow of the aerosol passing from the inlet end 300A toward the outlet end 300B. .. The number of 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 composed of a plurality of types of flow paths having different cross-sectional areas from each other. In the illustrated example, the cross-sectional area of the flow path 301A and the flow path 301C is smaller than the cross-sectional area of the flow path 301B and the flow path 301D.

At the inlet end 300A of the flow path 301 of the support member 300, an alternating current space portion 302 for alternating the passing flow of the aerosol from the heated fragrance generation source 110 shown in FIGS. 1 and 2 (A) to the support member 300 is provided. It is provided. Specifically, a step (inlet end position difference) (see FIG. 5A) is provided between the inlet end 300A of the support member 300 and the inlet end of the flow path 301, and is formed by this step. The AC space portion 302 is formed by the entrance end space portion. On the other hand, between the outlet end 300B of the support member 300 and the outlet end of the flow path 301, there is a flat continuous surface with no step (outlet end position difference) (see FIG. 5B).

The flow path 301 and the AC space portion 302 are formed by a space portion in the outer peripheral member 140 (see FIG. 2A) in the fragrance cartridge 100 in which no constituent member of the support member 300 exists. The outer peripheral member that constitutes the outer circumference of only the portion of the support member 300 may be integrally formed with the support member 300.

As described above, by providing the AC space portion 302 for alternating the passing flow of the aerosol at the inlet end 300A of the flow path 301 of the support member 300, the aerosol directed from the heated fragrance generation source 110 to the support member 300 can be generated. After temporarily staying in the AC space section 302 in terms of time and space, it flows into the flow paths 301A to 301D.

As a result, there is a time difference in the cause of non-uniform flow rate and flow velocity of the aerosol from the heated aromatic source 110 to the support member 300 due to the type and filling amount of the base material 110A of the heated aromatic source 110. Even if there is a difference in location or location, the aerosol is made uniform in the AC space 302, so that the flow rate of the aerosol passing through the support member 300 becomes stable, and the user can use the aroma component from the aroma source 110 to be heated. The effect of making it easier to inhale is obtained.

Further, as described above, in the present embodiment, since the cross-sectional areas of the flow paths 301A to 301D are different, the flow rate and the flow velocity of the aerosol passing through the support member 300 are different for each of the flow paths 301A to 301D. Changes to. This also has the effect of further stabilizing the passing flow of the aerosol that has passed through the support member 300 and toward the transfer member 120.

Further, when the AC space portion 302 is provided at the inlet end of the flow path of the support member 300, the heating element 211 provided inside the fragrance tool 200 shown in FIG. 1 is inserted into the heated fragrance generation source 110. At the same time, it is possible to obtain the effect that the excessive load applied to the heated fragrance generation source 110 by the heating element 211 can be reduced.

In the present embodiment, the AC space portion 302 is formed by the inlet end space portion formed by the step between the inlet end 300A of the support member 300 and the inlet end of the flow path 301, but the outlet end of the support member 300. A step may be provided between the 300B and the outlet end of the flow path 301, and the AC space portion 302 may be formed by the outlet end space portion formed by the step. Further, the AC space portion 302 may be formed on both the inlet end 300A side and the outlet end 300B side of the support member 300.

FIG. 6 shows an example in which the inlet end 300A of the support member 300 is provided with the regulation member 150 that limits the passage region of the aerosol from the support member 300 to the transfer member 120 (see FIGS. 1 and 2A). There is.

The regulation member 150 is made of a thin plate provided with a large number of small-sized openings 151 that allow the passage of aerosol, and is fitted in the AC space portion 302 of the support member 300. When the regulating member 150 is fitted into the AC space portion 302, one or a plurality of protrusions 303 for supporting the regulating member 150 are provided on the inlet end 300A side of the supporting member 300, and the restricting member 150 and the inlet end of the flow path 301 are provided. The AC space portion 302 is formed between the two.

By providing this regulation member 150, it is possible to prevent a problem that a part of the base material 110A of the heated fragrance generation source 110 leaks to the support member 300 side and the user sucks it.

Further, the restricting member 150 may be provided so as to be 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 adjusting the heights of the plurality of protrusions 303. it can. In this case, it becomes easy to allow a slight protrusion (swelling) of the base material 110A of the base material heated fragrance source 110 generated when the heating element 211 is stabbed so as not to overload.

The regulation member 150 may be provided on the outlet end 300B side of the support member 300, but is preferably provided in the AC space portion 302 in consideration of ease of attachment.

In the example shown in FIG. 5, the AC space portion 302 is the inlet end space portion formed by the step (inlet end position difference) between the inlet end 300A of the support member 300 and the inlet end of the flow path 301. As shown in FIG. 7, an inclination may be provided between the inlet end 300A of the support member 300 and the entrance end of the flow path 301, and the entrance end space portion formed by this inclination may be used as the AC space portion 302.

FIG. 7A is an example in which the support member 300 is inclined in the central direction from the outermost peripheral portion of the inlet end 300A, and FIG. 7B is an example in which the outermost peripheral portion of the inlet end 300A is a flat surface. Although this is an example in which the inclination is provided from the inside toward the center, the same effect as the example shown in FIG. 5 can be obtained in any case. Although not shown, in the embodiment shown in FIG. 7, a restricting member 150 that limits the aerosol passage region may be provided at the inlet end 300A of the support member 300, as in the embodiment shown in FIG. In this case, since the inclination is used in FIGS. 17 and 19 as in the example described later, even if the protrusion 303 or the like in FIG. 6 is not provided, the space between the regulating member 150 and the inlet end of the flow path 301 is used. The AC space portion 302 can be generated. Further, since the inclination is used, it can be easily provided not only flush with the inlet end 300A but also at an intermediate position in the depth direction of the AC space portion 302.

Table 1 shows an example of the dimensions of the support member 300 shown in FIG. The dimensions of the support member 300 shown in Table 1 are an example of optimum dimensions, and in reality, they can be variously changed depending on the type and amount of the base material 110A of the heated fragrance generation source 110. Here, the material of the support member 300 is made of silicone, and the diameter is 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.

(Second Embodiment)

As shown in FIG. 8, the support member 400 of the present embodiment has the following features. The support member 400 has an inlet end 400A (see FIG. 8A) located on the heated fragrance source 110 side shown in FIGS. 1 and 2 (A) and an outlet end 400B located on the transfer member 120 side (FIG. 8A). 8 (B)) and.

Inside the support member 400, a flow path 401 (flow path 401A to flow path 401D) for the passing flow of the aerosol passing from the inlet end 400A to the outlet end 400B is provided. The number of flow paths 401 penetrating the inside of the support member 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 composed of a plurality of types of flow paths having different cross-sectional areas from each other. In the illustrated example, the cross-sectional area of the flow path 401A and the flow path 401C is smaller than the cross-sectional area of the flow path 401B and the flow path 401D.

At the inlet end of the flow path 401 of the support member 400, an alternating current space portion 402 for alternating the passing flow of the aerosol from the heated fragrance generation source 110 shown in FIGS. 1 and 2 (A) to the support member 400 is provided. Has been done. Specifically, a step (inlet end position difference) (see FIG. 8A) is provided between the inlet end 400A of the support member 400 and the inlet end of the flow path 401, and is formed by this step. The AC space portion 402 is formed by the entrance end space portion. On the other hand, between the outlet end 400B of the support member 400 and the outlet end of the flow path 401, there is a flat continuous surface with no step (outlet end position difference) (see FIG. 8B).

In this way, by providing the AC space portion 402 for alternating the passing flow of the aerosol at the inlet end of the flow path 401 of the support member 400, the passing flow of the aerosol passing through the support member 400 becomes stable, and the user However, it is possible to obtain the effect that the aromatic component from the heated aerosol source 110 is easily sucked.

In the present embodiment, the AC space portion 402 is formed by the inlet end space portion formed by the step between the inlet end 400A of the support member 400 and the inlet end of the flow path 401, but the outlet end of the support member 400. A step may be provided between the 400B and the outlet end of the flow path 401, and the AC space portion 402 may be formed by the outlet end space portion formed by the step. Further, the AC space portion 402 may be formed on both the inlet end 400A side and the outlet end 400B side of the support member 400.

FIG. 9 shows an example in which the inlet end 400A of the support member 400 is provided with a regulation member 160 that limits the passage region of the aerosol from the support member 400 to the transfer member 120 (see FIGS. 1 and 2A). There is.

The regulation member 160 is made of a thin plate provided with a large number of small-sized openings 161 that allow the passage of aerosol, and is fitted in the AC space portion 402 of the support member 400. When the regulating member 160 is fitted into the AC space portion 402, one or a plurality of protrusions 403 (FIG. 9B) for supporting the regulating member 160 are provided on the inlet end 400A side of the supporting member 400, and the regulating member 160 is provided. The AC space portion 402 is formed between the flow path 401 and the inlet end of the flow path 401. By providing the regulating member 160, it is possible to prevent a problem that a part of the base material 110A of the heated fragrance generation source 110 leaks to the support member 300 side.
Further, the regulating member 160 may be provided so as to be flush with the inlet end 400A, or may be provided at an intermediate position in the depth direction of the AC space portion 402, similarly to the regulating member 150 described above. In addition to preventing the base material 110A from falling off or moving, it becomes easier to allow a slight protrusion (swelling) of the base material 110A that occurs when the heating element 211 is stabbed.

The regulation member 160 may be provided on the outlet end 400B side of the support member 400, that is, on the side where the AC space portion 402 is not provided, but it is preferable to provide the regulation member 160 in the AC space portion 402 in consideration of ease of attachment.

In the example shown in FIG. 8, the AC space portion 402 is the inlet end space portion formed by the step (inlet end position difference) between the inlet end 400A of the support member 400 and the inlet end of the flow path 401. As shown in FIG. 10, an inclination may be provided between the inlet end 400A of the support member 400 and the inlet end of the flow path 401, and the inlet end space formed by this inclination may be the AC space portion 402.

Although not shown, in the embodiment shown in FIG. 10, the regulating member 160 may be provided at the inlet end 400A or the outlet end 400B of the support member 400 as in the embodiment shown in FIG. Since the inclination is also used in this case, the AC space portion 402 can be generated between the regulating member 160 and the inlet end of the flow path 401 without providing the protrusion 403 or the like in FIG. 9, and the inclination can be increased. Since it is used, it can be easily provided not only flush with the inlet end 400A but also at an intermediate position in the depth direction of the AC space portion 402.
(Third Embodiment)

As shown in FIG. 11, the support member 500 of the present embodiment has an inlet end 500A located on the heated aroma generation source 110 side shown in FIGS. 1 and 2 (A) and an outlet end located on the transfer member 120 side. It has 500B. Further, inside the support member 500, a flow path 501 for a passing flow of aerosol passing from the inlet end 500A toward the outlet end 500B is provided.

As shown in FIG. 11A, an AC space portion 502 that limits the passage region of the aerosol is provided in the middle portion of the flow path 501 of the support member 500. Specifically, a step is provided in the middle portion of the flow path 501, and the AC space portion 502 is formed by the middle space portion formed by the step.

By providing an alternating current space portion 502 for alternating the passing flow of the aerosol in the middle of the flow path 501 of the support member 500, the passing flow of the aerosol passing through the support member 500 becomes stable, and the user can use the fragrance to be heated. The effect of facilitating inhalation of the aromatic component from the source 110 can be obtained.

As shown in FIG. 11B, also in the support member 500 of the present embodiment, as in the first and second embodiments, the regulation member 160 provided with a large number of openings 161 inside the AC space portion 502. By providing the above, it is possible to prevent a problem that a part of the base material 110A of the heated fragrance generation source 110 leaks to the support member 500 side. The regulation member 160 may be provided adjacent to the heated fragrance generation source 110 (see FIGS. 1 and 2) on the inlet end 500A side of the support member 500.

In the example shown in FIG. 11, the space portion formed by the step in the middle portion of the flow path 501 is referred to as the AC space portion 502, but as shown in FIG. 12, the space formed by the inclination of the middle portion of the flow path 301. The unit may be an AC space unit 302.

In the case of the embodiment shown in FIG. 5 of the first embodiment, the outer peripheral side of the inlet end 300A of the support member 300 protrudes toward the heated fragrance source 110 side from the central side, as shown in FIG. 13 (A). The central side of the inlet end 300A of the support member 300 may protrude toward the heated fragrance source 110 side rather than the outer peripheral side.

Similarly, in the embodiment shown in FIG. 7 of the first embodiment, the outer peripheral side of the inlet end 300A of the support member 300 protrudes toward the heated fragrance source 110 side from the central side, as shown in FIG. The central side of the inlet end 300A of the support member 300 may protrude toward the heated fragrance source 110 side rather than the outer peripheral side.

The shapes of the support members 300, 400, and 500 are not limited to the above-mentioned examples, and various design changes can be made. For example, the support member 300 may have a spherical outer circumference at the inlet end 300A, as shown in FIGS. 14 and 15. The support member 300 shown in FIG. 14 has a mode in which the outer peripheral side of the inlet end 300A protrudes toward the heated fragrance generation source 110 side from the central side, and the support member 300 shown in FIG. 15 has the central side of the inlet end 300A on the outer peripheral side. This is a mode in which the fragrance to be heated is projected toward the source 110.
(Fourth Embodiment)

In the first to third embodiments, the mode in which the support member is provided with four flow paths has been described, but in the present embodiment, the support member is provided with one or two flow paths, and the support member is provided with one or two flow paths. A mode in which an AC space portion is provided at the entrance end will be described. Further, in all the drawings for explaining the following aspects, those having the same function are, in principle, given the same reference numerals, and the repeated description thereof will be omitted.

FIG. 16 shows a perspective view, a front view, a side view, and a bottom view of one aspect of the support member 600. In FIG. 16, a flow path 601 is provided at the center of a cylindrical support member 600, and an inclination is provided between the inlet end of the support member 600 and the inlet end of the flow path 601. The inlet end formed by this inclination is provided. This is an embodiment in which the space portion is an AC space portion 602.

FIG. 17 shows an embodiment in which a restricting member 190 is provided at the inlet end of the support member 600 shown in FIG. 16 to limit an aerosol passage region from the support member 600 to the transfer member 120 (see FIGS. 1 and 2A). Is shown. FIG. 17A shows an example in which the regulating member 190 is provided at the outermost peripheral portion of the inlet end of the support member 600, and FIG. 17B shows a central portion (between the outermost peripheral portion of the inlet end of the support member 600). An example in which the regulation member 190 is provided near the flow path 601) is shown.

The regulating member 190 may be a thin plate (FIG. 17 (C)) provided with a large number of micro-sized openings 191 that allow the passage of aerosol, or may be provided with a grid-like frame portion 192 (FIG. 17 (FIG. 17)). D)) may be used. In the case of the regulating member 190 shown in FIG. 17 (D), the function of limiting the passage region of the aerosol from the heated fragrance generation source 110 to the support member 600 is low, but it is provided inside the fragrance tool 200 shown in FIG. When the heated element 211 is inserted into the heated aerosol source 110, the effect of reducing the excessive load given by the heated element 211 to the heated aerosol source 110 can be obtained.

FIG. 18 shows a perspective view, a front view, a side view, a top view, and a bottom view of one aspect of the support member 600. FIG. 18 shows an embodiment in which the outermost peripheral portion of the inlet end of the cylindrical support member 600 is a flat surface, an inclination is provided from the inside toward the center, and the entrance end space portion formed by this inclination is an AC space portion 602. Is.

FIG. 19 shows a mode in which the regulating member 190 is provided at the inlet end of the support member 600 shown in FIG. FIG. 19 (A) shows an example in which the regulating member 190 is provided at the outermost peripheral portion of the inlet end of the support member 600, and FIG. 19 (B) shows a central portion (between the outermost peripheral portion of the inlet end of the support member 600). An example in which the regulation member 190 is provided near the flow path 601) is shown.

As shown in FIG. 19 (C), the regulating member 190 may be a thin plate provided with a large number of small-sized openings 191 that allow the passage of aerosol, and as shown in FIG. 19 (D), the regulating member 190 may have a grid pattern. The frame portion 192 may be provided.

FIG. 20 shows a front view, a side view, and a bottom view of one aspect of the support member 600. FIG. 20 shows an embodiment in which the inlet end of the cylindrical support member 600 is provided with an inclination toward the flow path 601 from two directions, and the entrance end space portion formed by this inclination is used as the AC space portion 602.

FIG. 21 shows a front view, a side view, and a bottom view of one aspect of the support member 600. FIG. 21 shows an embodiment in which a part of the inlet end of the cylindrical support member 600 is provided with an inclination from one direction toward the flow path 601 and the entrance end space portion formed by this inclination is used as an AC space portion 602. ..

FIG. 22 shows a perspective view, a front view, a side view, and a bottom view of one aspect of the support member 600. FIG. 22 shows the inlet end of the cylindrical support member 600 facing the flow path 601 from two directions, and the central portion side is closer to the heated fragrance source 110 (FIG. 1, FIG. 2A) than the outer peripheral portion side. In this embodiment, an inclination is provided so as to project, and the entrance end space portion formed by this inclination is used as the AC space portion 602.

FIG. 23 shows a front view, a side view, a top view, and a bottom view of one aspect of the support member 600. FIG. 23 shows an embodiment in which two flow paths 601 are provided in the cylindrical support member 600, the inlet end of the support member 600 is cut off diagonally, and the inlet end space formed by the two flow paths 601 is used as an AC space 602. is there.

FIG. 24 shows a perspective view, a front view, a side view, and a bottom view of one aspect of the support member 600. In FIG. 24, two flow paths 601 are provided in the cylindrical support member 600, and the inlet end of the support member 600 is provided with an inclination toward the flow path 601 from two directions, and the entrance end space formed by the inclination is provided. This is an embodiment in which the unit is an AC space unit 602.

FIG. 25 shows a perspective view, a front view, a side view, and a bottom view of one aspect of the support member 600. In FIG. 25, two flow paths 601 are provided in a cylindrical support member 600, and an inclination from one direction toward the flow path 601 is provided in a part of the inlet end of the support member 600, and the inclination is formed. This is an embodiment in which the entrance end space portion is used as the AC space portion 602.

FIG. 26 shows a perspective view, a front view, a side view, a top view, and a bottom view of one aspect of the support member 600. In FIG. 26, two flow paths 601 are provided in a cylindrical support member 600, and a mortar-shaped inclination toward the flow path 601 from two directions is provided at the inlet end of the support member 600, and the inclination is formed. This is an embodiment in which the entrance end space portion is used as the AC space portion 602.

FIG. 27 shows a front view, a side view, a top view, and a bottom view of one aspect of the support member 600. In FIG. 27, two flow paths 601 are provided in the cylindrical support member 600, and at the inlet end of the cylindrical support member 600, the central portion side is closer to the heated fragrance source 110 than the outer peripheral portion side (FIG. 1, FIG. In this embodiment, inclinations protruding toward the side (A) of FIG. 2 are provided from two directions, and the entrance end space portion formed by these inclinations is designated as an AC space portion 602.

FIG. 28 shows a perspective view, a front view, a side view, a top view, and a bottom view of one aspect of the support member 600. In FIG. 28, two flow paths 601 are provided in the cylindrical support member 600, and at the inlet end of the cylindrical support member 600, the central portion side is the heated fragrance generation source 110 (FIG. 1, FIG. In this embodiment, a conical slope protruding toward the side (A) of FIG. 2 is provided, and the entrance end space portion formed by this slope is used as the AC space portion 602.

FIG. 29 shows a front view, a side view, a top view, and a bottom view of one aspect of the support member 600. In FIG. 29, a flow path 601 is provided at the center of a cylindrical support member 600, and an inclination is provided at the entrance end of the support member 600 toward the flow path 601 from two directions, and an entrance end space formed by this inclination. This is an embodiment in which the unit is an AC space unit 602.

FIG. 30 shows a perspective view, a front view, a side view, and a bottom view of one aspect of the support member 600. In FIG. 30, a flow path 601 is provided in the central portion of the cylindrical support member 600, and the outer peripheral portion side is a part of the inlet end of the cylindrical support member 600, and the heated fragrance generation source 110 (heated fragrance generation source 110) is higher than the central portion side. A mortar-shaped inclination is provided on the side of FIGS. 1 and 2 (A), and the entrance end space formed by this inclination is used as an AC space portion 602. Further, the outermost peripheral portion of the inlet end of the support member 600 has a mortar-shaped inclination in which the central portion side protrudes toward the heated aroma generation source 110 side from the outer peripheral portion side.

FIG. 31 shows a perspective view, a front view, a side view, and a bottom view of one aspect of the support member 600. In FIG. 31, a flow path 601 is provided in the central portion of the cylindrical support member 600, and at the inlet end of the cylindrical support member 600, the central portion side is closer to the heated fragrance source 110 than the outer side (FIG. 1). , FIG. 2A) is provided with a conical inclination that protrudes toward the side, and the entrance end space portion formed by this inclination is used as the AC space portion 602.

FIG. 32 shows a partially broken perspective view of one aspect of the support member 600. In FIG. 32, one flow path 601 is provided in the central portion of the cylindrical support member 600, and the cylindrical central member 193 is inserted inside the flow path 601 to form the inlet end of the support member 600 and the central member 193. This is an embodiment in which the AC space portion 602 is formed by the entrance end space portion formed by the step between the end portion and the end portion.

The central member 193 is fixed inside the flow path 601 by a fixing portion 194 integrally formed with the central member 193, and the gap between the inner peripheral surface of the support member 600 and the central member 193 forms the flow path 601. There is.

In the embodiment shown in FIG. 32, the inlet end of the support member 600 projects toward the heated fragrance source 110 (FIGS. 1 and 2 (A)) from the end of the central member 193, but the embodiment shown in FIG. 33. As described above, the end portion of the central member 193 may protrude toward the heated aroma generation source 110 side from the inlet end of the support member 600.

Also in this embodiment, by providing an alternating current space portion 602 for alternating current of the passing flow of the aerosol at the inlet end of the flow path 601 of the support member 600, the aerosol from the heated fragrance generation source 110 to the support member 300 can be generated. After temporarily staying in the AC space section 302 in terms of time and space, it flows into the flow path 601.

As a result, the existing non-uniformity over time caused by changes in the flow rate and flow velocity of the aerosol over time due to non-uniformity due to the degree of clogging of the filler that is the base material in the heated aroma generation source, etc. The temporal difference or regional non-uniformity will be homogenized by the AC space section 602. As a result, the passing flow of the aerosol passing through the support member 600 is stabilized, and it is easy for the user to suck in the fragrance component from the heated fragrance source 110.

In addition to the difficulty of suction, the aerosol is also an aromatic cartridge for air fresheners to address existing problems such as overloading the heated air freshener source when the heating element is inserted into the heated air freshener source. By stably supporting the aerosol-generating base material when inserting the heating element and preventing overload while securing the flow path to be transferred inside, the insertion of the heating element is facilitated and the operability is improved. The effect of being able to do is obtained.

(Fifth Embodiment)
Next, a fifth fragrance tool has an ID chip (also referred to as an IC chip) in the fragrance cartridge 1 of various aspects described above, and has a reader (hereinafter, referred to as an ID detection unit) for reading the information of the ID chip in the member. It will be described as an embodiment.

In the fragrance tool of the fifth embodiment, the ID detection unit provided on the member reads the information of the ID chip provided on the fragrance cartridge 1, and this information (for example, the type of the heated fragrance source of the cartridge, the ambient environment). Etc.), the control unit described later performs appropriate heating control to bring the aroma component at the time of suction into an appropriate state.

FIG. 34 is a cross-sectional view of the fragrance appliance of the fifth embodiment. However, the description of the same reference numerals as those in the above figure will be omitted. Note that FIG. 34 is a cross-sectional view in the longitudinal direction. In the fragrance tool of the embodiment, the fragrance cartridge 1 having an ID chip is referred to as an fragrance cartridge 700 with an ID chip, and the member having an ID detection unit is referred to as a member 800 with an ID detection unit. Further, an fragrance tool including an fragrance cartridge 700 with an ID chip and a member 800 with an ID detection unit is referred to as an fragrance tool 900 with an ID detection function.

The fragrance tool 900 with an ID detection function of FIG. 34 is an example of the usage pattern of the fragrance cartridge corresponding to FIG. 1 shown by the support member 301B2 represented by the support members of various modes described above.

The fragrance cartridge 1 here has, for example, an ID chip 313 as an ID detected portion in the peripheral portion of the support member. In the embodiment, the support member having the ID chip 313 is referred to as a support member with an ID chip 313B2.

Further, the fragrance tool 900 with an ID detection function has ID information stored in the ID chip 313 at a position corresponding to the ID chip 313 in the outer wall portion of the member 800 with the ID detection unit to which (insert) the fragrance cartridge 1 is mounted. The sensor 906 is provided as an ID detection unit for detecting the above.

In this case, the ID chip 313 and the sensor 906 can send and receive various kinds of information by NFC (Near Field Communication). Here, the ID information of the support member 301B2 and the fragrance cartridge 100, for example, the ID information such as the type, the manufacturer, the serial number, and the manufacturing time is stored in the ID chip 313 side, and can be detected by the sensor 906 side. .. If the information is as simple as this, for example, on the ID detection unit 313 side, an ID tag or the like showing a predetermined pattern or the like can be used as a substitute, and RFID (radio frequency identifier) or the like can be used via electromagnetic waves or radio waves. The short-range wireless communication may be used, or the pattern indicated by the ID tag may be detected by, for example, a transmission type or reflection type optical sensor on the ID detection unit 906 side.

It is unknown in what state (for example, rotation) the fragrance cartridge 700 with an ID chip is inserted into the member 800 with an ID detection unit. Therefore, a plurality of ID chips 313 are provided around the support member 303B2 with an ID chip (for example, in silicone). Alternatively, if the sensor 906 (ID detection unit) is ultra-small like the ID chip 313, the sensor 906 (ID detection unit) is connected around the member 800 with the ID detection unit (or is connected at predetermined intervals). The ID chip 313 of the fragrance cartridge 700 with an ID chip is circulated at a predetermined position.

In FIG. 34, a plurality of ID chips 313 are provided around a predetermined position of the ID chip-attached support member 301B2 of the ID chip-attached fragrance cartridge 700, and the periphery of the ID detection unit-attached member 800 (the inner wall side is preferable). This is an example in which the sensor 906 (ID detection unit) is continuously provided around the surface. For example, a sensor 906 (ID detection unit) is provided around each position at intervals of 5 mm, 10 mm, ..., Or 30 mm. However, the connection line of the sensor 906 (ID detection unit) with the control unit described later is not shown.

If the position of the predetermined position of the support member 301B2 with the ID chip is one, it is set to the heated fragrance generation source 110 side.

However, FIG. 34 shows an example in which the support member 301B2 with an ID chip is also provided around the filter member 130 side so that the insertion angle of the fragrance cartridge 700 with an ID chip can be detected. When it is not necessary to obtain the insertion angle, the filter member 130 side is unnecessary.

The ID chips 313 of the ID chip-attached support member 301B2 on the heated fragrance source 110 side are located on a straight line parallel to the central axis (not shown) of the ID chip-attached fragrance cartridge 700.

That is, the fragrance tool 900 with an ID detection function can calculate the insertion position, distance, angle, etc. of the member 800 with the ID detection unit of the fragrance cartridge 700 with an ID chip, and also has ID information (for example, type, manufacturer, serial number, etc.). It is possible to read the manufacturing time, etc.). However, the connection line with the control unit, which will be described later, is not shown. The specific calculation process of the insertion position, the distance, the angle, etc. will be described using a flowchart in the description of the control unit described later.

FIG. 34 will be described in more detail. The shape of the support member 301B2 with an ID chip, which is a constituent member of the fragrance cartridge 700 with an ID chip, may be the shape shown in FIGS. 5 to 33.

Among these figures, the figure when the support member 300 of FIG. 5B, the support member 400 of FIG. 10, and the support member 500 of FIG. 11 are used is shown below.

FIG. 35 is a perspective view when the ID chip 313 is provided on the support member 300 of FIG. 5 (B). However, although the ID chip 313 is provided in each of the members 302A, 302B, 302C, and 302D, FIG. 35 shows an example in which the ID chip 313 is provided only in the member 302A. Further, the ID chip 313 may be provided on the inlet end 300A side and the exit end 300B side.

FIG. 36 (A) is a perspective view when the ID chip 313 is provided on the support member 400 of FIG. However, in FIG. 36A, the ID chip 313 provided at the outlet end 400B is not shown.

FIG. 36B is a perspective view when the ID chip 313 is provided on the support member 500 of FIG. However, FIG. 36B is a cross-sectional perspective view of the support member 500 of FIG. 10 at a predetermined position from the center to the entrance side.

The ID chip 313 provided at the exit end 400B is not shown. However, FIGS. 36 (A) and 36 (B) show only the upper and lower two ID chips 313.

That is, since a plurality of ID chips 313 are arranged around the periphery, any ID chip 313 faces the ID detection unit 53 no matter what rotation is inserted into the member with the ID detection unit 800. The ID information will always be detected.

Further, a cross-sectional view of a case where the ID chip 313 is provided on the support member 300 in the fragrance cartridge 100 of FIGS. 2 (A) to 2 (E) and the sensor 906 (ID detection unit) is provided on the fragrance tool 200 is shown. It is shown in FIGS. 37 (A) to 37 (E).

That is, FIGS. 37 (A) to 37 (E) show another example of the usage pattern of the fragrance cartridge similar to that of FIG. 34. However, here, a plurality of ID chips 313 are provided in the peripheral portion of the support member 300. Further, the fragrance tool 200 fragrance appliance 5 has ID detection units (hereinafter, referred to as sensors 906) at a plurality of positions corresponding to the plurality of ID chips 313.

Therefore, as shown in FIG. 37 (A), the aerosol transferred from the support member 300 to the filter member 130 can be cooled, the insertion position, distance, angle, etc. can be detected, and the ID information (for example, type, manufacturer, etc.) can be detected. (Production number, production time, etc.) can be detected to facilitate optimum overheat control and optimum suction operation.

As shown in FIG. 37 (B), instead of omitting the transfer member 120, the filter member 130 is lengthened and the filter member 130 is provided with an aerosol cooling function to improve the air permeability in the fragrance cartridge 100 and to improve the air permeability in the aerosol. In addition to making it easier to suck the fragrance component of the fragrance cartridge 100 and reducing the number of parts of the fragrance cartridge 100, it is possible to detect the insertion position, distance, angle, etc., and ID information (for example, type, manufacturer, serial number, manufacturing). The timing, etc.) can be detected to facilitate the optimum overheating control and the optimum operation of suction.

Further, as shown in FIG. 37C, by interposing the partition wall member 170 between the heated fragrance source 110 and the support member 300, the heated fragrance source 110 becomes the fragrance cartridge 100 due to vibration during transportation or the like. In addition to being able to avoid the problem of moving inside, it is possible to detect the insertion position, distance, angle, etc., and also detect ID information (for example, type, manufacturer, serial number, manufacturing time, etc.), which is optimal. Optimal operation of overheating control and suction can be facilitated.

Further, as shown in FIG. 37 (D), the dissipation of the fragrance component in the heated fragrance source 110 can be suppressed, and the heated fragrance source 110 is moved to the outside of the fragrance cartridge 100 due to vibration during transportation or the like. In addition to avoiding the problem of falling off and facilitating the insertion of the heating element 211 (FIG. 1) into the heated fragrance source 110, the insertion position, distance, angle, etc. can be detected, and the ID information (ID information (FIG. 1)). For example, the type, manufacturer, serial number, manufacturing time, etc.) can be detected to facilitate the optimum overheating control and the optimum operation of suction.

Further, as shown in FIG. 37 (E), the support member 300 may be lengthened in the structure of FIG. 37 (B) so that the support member 300 has an aerosol cooling function.

Next, the connection configuration of the control unit and each sensor and the like will be described with reference to FIG. 38. The control unit is often provided on the lower side of the fragrance.

As shown in FIG. 38, the control unit 9 includes a CPU 900A as a central control unit, a memory 901 composed of ROM, RAM, SD, HDD, etc., a power supply 902, and a heating control unit 903 that controls a heater, etc. It is configured to include a detection control unit 904 that controls various sensors to detect various information, and a system bus 99 or the like for exchanging data or the like between them. Further, an LED group or a display unit for prompting the operator of the air freshener 900 with an ID detection function to perform an appropriate operation is connected. The LED group and the display unit are collectively referred to as a user guidance unit 905 in the present embodiment.

The heating control unit 903 controls the heating element 211 while referring to the detection information from the sensor (sensor Z) 94z that detects the calorific value of the heating element 211, the heating temperature, and the like. Further, the detection control unit 904 exchanges control information with the heating control unit 903 via the system bus 99 or the like in cooperation with the CPU 900A based on the detection information from the sensor 94z described above.

Further, the detection control unit 904 includes a power supply sensor (sensor A) 94a for detecting the state of the power supply 902 such as output voltage / current and residual storage amount, a sensor (sensor B) 94b for detecting environmental temperature / humidity, etc. Various detection information is acquired from the sensor (sensor C) 94c that performs various detections, and a signal for controlling each sensor is output in cooperation with the CPU 900A.

Then, in addition to these, the detection control unit 904 acquires various information including the ID information from the ID chip 313 of the fragrance cartridge 1 via the sensor (ID detection unit 906), and cooperates with the CPU 900A to fragrance. It outputs a signal for inducing operations related to the cartridge, for example, user guidance such as blinking an LED (not shown) indicating various situations.

Here, a plurality of ID chips 313 are provided in the peripheral portion of the support member. Further, the air freshener 200 has an ID detection unit 906 (hereinafter, referred to as a sensor 906) at a plurality of positions corresponding to the plurality of ID chips 313. In this case, the sensor 906 detects the distance from each ID chip 313 to each corresponding sensor 906 together with the above-mentioned ID information. This can be realized by various sensors for detecting minute distances (proximity sensor / displacement sensor / length measurement sensor that can detect even μm order). Information on the inserted state of the fragrance cartridge 1 can be obtained from the distance between each ID chip 313 and the sensor 906. This process will be described in detail in the flowchart of the control unit 9.

For example, the distance to the final insertion position can be obtained from the magnitude of the distance value, and the inclination of insertion can be detected via the deviation value between the central axis of the fragrance cartridge 1 and the central axis of the insertion portion due to the difference in each sensor value. it can. By showing these detection results with an LED or display panel (not shown), various user guidance can be performed, and not only the type of aromatic cartridge can be grasped, but also the insertion operation to the center position can be facilitated. Operability can be obtained in line with the objectives such as "stabilization of aerosol flow", "stable support of the heating aroma generation source when the heating element is inserted", and "improvement of easy operability when the cartridge is inserted".

In the above example, both the ID chip 313 and the sensor 906 are used as a plurality, but the distances from the plurality of sensors can be obtained for a single ID chip.

Further, the sensor 906 does not have to be a plurality of separated sensors, and may be in a continuous form. Further, the ID detection unit can be realized in another form, for example, by processing a specific shape at a specific position on the fragrance cartridge 1 side without providing a specific part such as the above-mentioned ID chip or ID tag. Is also possible.

Next, the processing of the CPU 900 and the memory 901 that issue predetermined commands to the detection control unit 904, the heating control unit 903, and the like will be described with reference to the flowchart.

39 and 40 are flowcharts illustrating the processing of the CPU 900A based on the program of the memory 901 of the control unit 9. Further, a number is assigned to the ID detection unit 906.

It is preferable that the ID information stored in the ID chip 313 includes the optimum heating temperature of the type in addition to the type of material, the manufacturer, the serial number, the production time, and the like.

When the power on button (not shown) is pressed, the CPU 900A performs the following processing based on the program of the memory 901.

A command to activate all sensors is output to the detection control unit 904 when the power is turned on (S10). As a result, the detection control unit 904 can acquire various sensor information. At this time, a command for blinking the LED group (user guidance unit 905) is output to the detection control unit 904 in order to prompt the detection control unit 904 to insert the fragrance cartridge into the member 800 with the ID detection unit. Alternatively, an instruction to display a message is output to the display unit (user guidance unit 905). As a result, the operator of the fragrance tool 900 with the ID detection function inserts the fragrance cartridge 700 with the ID chip into the chamber 800 with the ID detection unit.

Next, it is determined whether or not there is an output of ID detection information (material type, manufacturer, serial number, manufacturing time, optimum heating temperature, sensor (906) number) from the sensor 906 (ID detection unit) (S20). ).

If it is determined that the ID detection information is in step S20, the ID detection information is stored in the memory 901 (S30).

Then, the number of the sensor (906) included in the ID detection information is read, and the distance (insertion distance) from the heated fragrance generation source 110 is obtained from this number (S40). This calculation is possible because the memory 901 is associated with the sensor number and the distance value to the bottom of the member 800 with the ID detection unit.

An example of a specific method will be described with reference to FIGS. 41 (A) and 41 (B). FIG. 41 (A) is a cross-sectional view of the air freshener 900 with an ID detection function of FIG. 34 in a state in which the air freshener cartridge 700 with an ID chip is inserted slightly in front of the heating unit 211. FIG. 41 (B) is a cross-sectional view of the fragrance cartridge 700 with an ID chip completely inserted into the heating unit 211.

Since the sensor 906 is provided around the inner wall of the member 800 with the ID detection unit at predetermined intervals over a range slightly inside the insertion port from the insertion port side of the heating unit 211. , The ID chip 313 provided on the support member 301B2 with an ID chip faces any of the sensors 906 as it is inserted. That is, with the insertion, the sensor 906 sequentially detects the ID detection information from the vicinity of the insertion port. A number is assigned to the sensor 906, and it can be calculated by the control unit 9 reading the distance from the number of the sensor 906 to the bottom of the member 800 with the ID detection unit associated with this number.

Further, when the heated fragrance source 110 of the fragrance cartridge 700 with an ID chip is completely inserted into the heating unit 211, the state shown in FIG. 41B is shown, but the fragrance to be heated of the support member 1000 with an ID chip is obtained. The ID chip 313 on the source 110 side faces the sensor 906 farthest from the insertion port. When the sensor 906 detects the ID detection information, it is determined to be the optimum insertion position.

Then, it is determined whether the insertion distance is optimal (S50). For example, when the insertion distance is several μm or less (for example, 5 μm) to several millimeters (for example, 1. mm) from the heated fragrance source 110, it is determined to be the optimum insertion distance.

If it is determined in step S50 that the insertion distance is not the optimum, the LED group of the user guidance unit 95 is blinked (for example, red and blue), and the process is returned to step S40 (S60).
Further, when it is determined in step S50 that the optimum insertion distance is determined, the LED group notifying the insertion completion is blinked (for example, blue and blue), and the control data notifying the optimum insertion completion is output to the detection control unit 94 (S70). ). Then, the availability determination process is performed (S80, S90). (Availability determination processing S80, S90)

The usability determination processes S80 and S90 are stored in advance in the memory together with the ID detection information (material type, manufacturer, manufacturing number, manufacturing time, optimum heating temperature, sensor (906) number, etc.) stored in step S30. It is compared with the license information (material type, manufacturer, serial number, manufacturing time) to determine whether or not it can be used (S80, S90). The ID detection information does not have to include the type of material, the manufacturer, the serial number, the manufacturing time, the optimum heating temperature, and the heating time. In this case, it is simply an ID number, and the memory 901 stores the material type, manufacturer, serial number, manufacturing time, optimum heating temperature, and heating time in association with this ID number, and ID detection information (simply ID number). When the type, manufacturer, serial number, and manufacturing time of the material associated with the ID number from the memory 901 exist, it may be determined that the license is used.

ID detection information (material type, manufacturer, serial number, manufacturing time, optimum heating temperature, sensor (906) number, etc.) and license information (material type, manufacturer, serial number, etc.) stored in the memory in advance. If it matches the manufacturing time), it is judged as a license.

When it is determined that the usage permission is granted, the control data for blinking the LED group notifying the usage permission (for example, yellow and blue) or displaying a message is output to the detection control unit 904 (S110).

Then, as shown in FIG. 40, a heating control process is performed according to the type of material (S120).
(Heat control process S120)

The heating control process S120 reads the optimum heating temperature and heating time included in the ID detection information (material type, manufacturer, serial number, manufacturing time, optimum heating temperature, heating time), and controls data based on the optimum heating temperature and heating time. Is output to the heating control unit 903 to heat it. The heating control unit 903 supplies heating power to the heating unit 211 while monitoring the output of the sensor Z (94z). At this time, control data for blinking the LED group (for example, yellow and red) or displaying a message indicating that heating has started is output to the detection control unit 904.

Note that the ID detection information does not have to include the material type, manufacturer, serial number, manufacturing time, optimum heating temperature, and heating time. In this case, it is simply an ID number, and the memory 901 stores the material type, manufacturer, serial number, manufacturing time, optimum heating temperature, and heating time in association with this ID number, and ID detection information (simply ID number). When the memory 901 is received, the heat treatment may be performed at the optimum heating temperature and heating time associated with the ID number from the memory 901.

Then, it is determined whether or not the overheating is completed (S130), and if not, the process is returned to step S120 to heat.

On the other hand, when it is determined in step S90 that the LED group cannot be used, the control data for blinking the LED group notifying the unavailability (for example, red and red) or displaying a message is output to the detection control unit 904 (S100).

Further, the heating control process S120 outputs the external temperature and humidity from the sensor B (94b) from the detection control unit 904. When the external temperature and humidity are lower than the reference value, the superheat temperature and the superheat time are controlled according to the parameters stored in the memory 901 in advance. Therefore, the suction can be performed with the optimum taste without affecting the external temperature and humidity.

(Other Embodiment 1)
Although the insertion distance is determined by the sensor number in step S40 of FIG. 39, the process of obtaining the insertion angle may be performed before this. That is, the above-mentioned "distance from each ID chip 313 to each corresponding sensor 906 is detected. Various sensors for detecting a minute distance (proximity sensor / displacement sensor / length measurement sensor capable of detecting even μm order) and the like. The information (insertion angle) of the inserted state of the fragrance cartridge 1 can be obtained from the distance between each ID chip 313 and the sensor 906. ”(Insert angle calculation process) is performed.

FIG. 42 (A) is an explanatory diagram for explaining that the insertion angle can be calculated. FIG. 42B is a distance di (d1, d2, ...) Between the sensor 906 stored in the memory 901 and the ID chip 313 accompanying the insertion.

(Insert angle calculation process)
The insertion angle calculation process reads the reception intensity of the ID detection information from the detection control unit 904 detected by the sensor 906. Then, the distance value di corresponding to the reception strength is obtained by referring to a table (not shown) of the reception strength stored in the memory 901 in advance and the distance value between the ID chip 313 and the reception strength.

Then, each time the distance value di is obtained, it is associated with the number of the sensor 906 that outputs the ID detection information (see FIG. 42 (B)). Generally, when the distance value of two points is obtained, the insertion angle θi near the insertion port can be calculated. When the insertion angle θi exceeds a preset angle, the LED blinks or the display unit displays a message that the insertion angle is deviated.

(Other Embodiment 2)
Although it has been described that the support member 301B2 with an ID chip of the above embodiment is provided with an AC space, the ID chip is provided as described above on a general support member without an AC space. It doesn't matter.

The above-mentioned ID tag or the like detects an ID by a transmission type or a reflection type light detection. The ID tag receives radio waves from the reader / writer for a certain period of time, converts them into electric power, operates the IC chip, and sends the information back to the reader / writer. Generally, electricity is received by radio waves, so no batteries are required. The non-contact distance can be selected from 1 cm to 200 cm depending on the application. A reader / writer is a device that integrates a signal processing unit required for communication with an ID tag and an RF module. It sends radio waves to the ID tag from an antenna and receives the data sent back from the ID tag. You can also write data to the ID. It emits radio waves for a certain period of time and receives ID tag data for a certain period of time. You can connect to a reader / writer with a personal computer via RS232C, USB, etc., control it, and process / execute data.

Although the invention made by the present inventor has been specifically described above based on the embodiment, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist thereof. Needless to say.

100 Fragrance cartridge 110 Heated fragrance source 110A Base material 120 Transfer member 130 Filter member 140 Outer peripheral member 150 Regulatory member 151 Opening 160 Regulatory member 161 Opening 170 Partition 180 Cap 190 Regulatory member 191 Opening 192 Frame part 193 Central member 194 Fixed part 200 Air freshener 210 Insertion port 211 Heating element 300 Support member 300A Inlet end 300B Outlet end 301 Flow path 301A Flow path 301B Flow path 301C Flow path 301D Flow path 302 AC space part 303 Projection 303B2 Support member with ID chip 313 ID chip 400 Support member 400A Inlet end 400B Outlet end 401 Flow path 401A Flow path 401B Flow path 401C Flow path 401D Flow path 402 AC space 403 Protrusion 500 Support member 500A Inlet end 500B Outlet end 501 Flow path 600 Support member 601 Flow path 602 AC Space 700 Fragrance cartridge with ID chip 800 Member with ID detection unit 900 Fragrance with ID detection function 9 Control unit 900A CPU
901 Memory 902 Power supply 903 Heating control unit 904 Detection control unit 94a Sensor A
94b sensor B
94c sensor C
94z sensor Z
905 User guidance unit 906 Sensor

Claims (37)

1. Placed between the heated fragrance source and the filter member in the fragrance cartridge,
   The flow path of the passing flow of the aerosol passing from one end surface on the heated aroma generation source side toward the other end surface on the filter member side.
   An AC space portion provided at at least one of the inlet end, the outlet end, and the middle portion of the flow path to exchange the passing flow of the aerosol.
   Support member for air freshener cartridges.
2. There is an inlet end position difference between the outer peripheral end on the one end surface side of the support member and the inlet end of the flow path.
   The support member for an fragrance cartridge according to claim 1, wherein the AC space portion includes an inlet end space portion formed by the difference in the position of the inlet end.
3. The support member for an fragrance cartridge according to 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 path. ..
4. 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.
   The support member for an fragrance cartridge according to any one of claims 1 to 3, wherein the AC space portion includes an outlet end space portion formed by the outlet end positional difference.
5. The support member for an fragrance cartridge according to claim 4, wherein the outlet end position difference is formed by a step or inclination between the outer peripheral end of the support member on the other end surface side and the outlet end of the flow path. ..
6. In the middle part of the flow path, there is an intermediate space part connected to the flow path and having a cross-sectional area wider than that of the flow path.
   The support member for an fragrance cartridge according to any one of claims 1 to 5, wherein the AC space portion includes the intermediate space portion.
7. The support member for an fragrance cartridge according to any one of claims 1 to 6, wherein the flow path has a plurality of flow paths having different cross-sectional areas from each other.
8. Further having an outer peripheral member constituting the outer peripheral portion of the support member,
   The support member for an fragrance cartridge according to any one of claims 1 to 7, wherein the flow path and the AC space portion are formed by a space portion in the outer peripheral member in which a constituent member of the support member does not exist.
9. The support member for an fragrance cartridge according to claim 8, wherein the outer peripheral member is integrally formed.
10. The support member for an fragrance cartridge according to any one of claims 1 to 7, wherein the flow path is a hollow through hole formed in the support member.
11. Placed between the heated fragrance source and the filter member in the fragrance cartridge,
    A support surface that directly or indirectly supports the aerosol-forming substrate,
    The flow path of the passing flow of the aerosol passing from one end surface on the heated aroma generation source side toward the other end surface on the filter member side.
    Have,
    The support surface is
    The first support surface and
    A second support surface on the downstream side of the first support surface,
    A support member for an air freshener cartridge having.
12. The support member for an fragrance cartridge according to claim 11, wherein the second support surface is connected to the first support surface.
13. The support member for an fragrance cartridge according to claim 11 or 12, wherein the second support surface is formed through a step.
14. The support member for an fragrance cartridge according to any one of claims 11 to 13, wherein the first support surface or the second support surface is symmetrical about a central axis in the longitudinal direction of the heated fragrance source.
15. The support member for an fragrance cartridge according to any one of claims 11 to 14, wherein the area ratio of the second support surface to the first support surface is 0.25 times or more and 4.0 times or less. ..
16. Placed between the heated fragrance source and the filter member in the fragrance cartridge,
    A support surface that directly or indirectly supports the heated fragrance source,
    The flow path of the passing flow of the aerosol passing from one end surface on the heated aroma generation source side toward the other end surface on the filter member side.
    Have,
    The support surface is a support member for an fragrance cartridge having an inclined surface with respect to a surface perpendicular to the central axis in the longitudinal direction of the heated fragrance source.
17. The support member for an fragrance cartridge according to claim 16, wherein the flow path includes a hollow through hole formed in the support member.
18. The support member for an fragrance cartridge according to claim 16 or 17, wherein the flow path includes a flow path formed on the peripheral edge of the support element.
19. The support member for an fragrance cartridge according to any one of claims 16 to 18, which has the flow path on the downstream side of the inclined surface.
20. The support member for an fragrance cartridge according to any one of claims 16 to 19, wherein the inclined surface is symmetrical around the central axis.
21. The support member for an fragrance cartridge according to any one of claims 16 to 20, wherein the inclination angle of the inclined surface with respect to the vertical surface is 4 degrees or more.
22. The support member for an aromatic cartridge according to any one of claims 16 to 21, wherein the inclined surface includes an inclined surface with respect to the insertion direction of the heating element when the heating element is inserted into the aerosol generating base material and heated. ..
23. The support member for an fragrance cartridge according to any one of claims 1 to 22, which has an ID detected portion capable of detecting ID information that can distinguish the fragrance cartridge from other types of different fragrance cartridges.
24. The heated fragrance source and
    With the filter member
    The support member for the fragrance cartridge according to any one of claims 1 to 22,
    Aroma cartridge with.
25. The fragrance cartridge according to claim 24, further comprising a regulating member that limits the passage region of the aerosol from the heated fragrance source.
26. The fragrance cartridge according to claim 25, wherein the restricting member has an opening having a size that allows the passage of the aerosol and restricts the passage of the fragrance source to be heated.
27. A support member for an fragrance cartridge having an ID detected portion capable of detecting ID information that can distinguish the fragrance cartridge from other types of different fragrance cartridges.
28. The support member for an fragrance cartridge according to any one of claims 1 to 22, which has an ID detected portion capable of detecting ID information that can distinguish the fragrance cartridge from other types of different fragrance cartridges.
29. The support member for an fragrance cartridge according to claim 27 or 28, wherein the ID detection unit has an ID storage means for storing the ID information.
30. The support member for an fragrance cartridge according to claim 27 or 28, wherein the ID detected unit presents the ID information.
31. Heated fragrance source and
    With the filter member
    An fragrance cartridge comprising the support member for the fragrance cartridge according to any one of claims 26 to 29.
32. The fragrance cartridge according to claim 31, further comprising a regulatory member that limits the passage region of the aerosol from the heated fragrance source.
33. The fragrance cartridge according to claim 32, wherein the regulating member has an opening having a size that allows the passage of the aerosol and restricts the passage of the fragrance source to be heated.
34. The fragrance cartridge according to any one of claims 31 to 33,
    An ID detection unit for detecting the ID information and
    A heating unit for applying heat to the heated fragrance source,
    An air freshener comprising the ID detection unit and a control unit for controlling the heating unit.
35. The ID detection unit is arranged around the mounting portion of the fragrance cartridge, and the control unit has a distance detection function capable of detecting a distance based on ID detection information from the ID detection unit. And
    Further, the control unit acquires the ID information based on the ID detection information, and grasps the mounting state of the fragrance cartridge from the distance between each portion around the mounting portion and the ID detected portion. 34. Air freshener Aroma device.
36. The ID detection unit has a plurality of ID sub-detection units around the mounting unit.
    The air freshener fragrance device according to claim 35, wherein the ID detected unit has a plurality of ID detected units corresponding to the plurality of ID sub-detecting units.
37. An fragrance tool having a support member for an fragrance cartridge arranged between a heated fragrance source and a filter member in the fragrance cartridge.
    The support member for the air freshener is
    An fragrance tool comprising an ID detected portion capable of detecting ID information that distinguishes the fragrance cartridge from other types of different fragrance cartridges.

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