RU2772449C1 - Heating unit and an aromatic inhaler equipped with it - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: invention relates to heating units and devices equipped with them for inhaling fragrance. A heating unit containing a first cylindrical element is presented, equipped at one end with a first hole into which an aerosol-generating product can be inserted, and at the other end with a second hole that forms an air inlet; a heating element and a thermal insulation material. The heating unit additionally includes a second cylindrical element placed with the coverage of the first cylindrical element. A sealed zone is provided between the first cylindrical element and the second cylindrical element. The heating element and the thermal insulation element are placed in a sealed area.

EFFECT: purpose of the invention is to create a heating unit and a device for inhaling fragrance, which have a new design.

23 cl, 9 dwg

Description

FIELD OF TECHNOLOGY TO WHICH THE INVENTION RELATES

[0001] The present invention relates to heating units and devices for inhaling aroma provided therewith.

BACKGROUND OF THE INVENTION

[0002] Aroma inhalation devices or the like that function as aroma inhalers without combustible material are well known. Aroma inhalation devices are also known, which include, for example, a smoking material heating device that generates an aerosol by heating a smoking material composed of tobacco that contains volatile components (see Patent Document 1). The smoking material heating device described in Patent Document 1 includes a hollow cylindrical heater.

LIST OF CITATIONS

PATENT LITERATURE

[0003] Patent Document (PTL) 1: Japanese Patent Application Pending (Kohyo) Publication No. 2018-522551

SUMMARY OF THE INVENTION

TECHNICAL PROBLEM

[0004] The object of the invention is to provide a heating unit and an aroma inhalation device which are of novel design.

THE SOLUTION OF THE PROBLEM

[0005] One embodiment of the invention is a heating assembly comprising a first cylindrical element provided at one end with a first opening into which an aroma-generating article can be inserted and at the other end with a second opening that forms an air inlet; a heating element; and thermal insulation material. The heating unit additionally includes a second cylindrical element placed around the first cylindrical element. A sealed zone is provided between the first cylindrical element and the second cylindrical element. The heating element and the heat-insulating element are placed in a sealed area.

[0006] Another embodiment of the invention is an aroma inhalation device including the aforementioned heating unit.

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] FIG. 1A is a perspective perspective view of an aroma inhalation device according to the present embodiment.

Fig. 1B is a perspective perspective view of a flavor inhalation device according to the present embodiment which holds a smoking article.

Fig. 2 is a sectional view of a smoking article.

Fig. 3 is a sectional view as seen along the direction of the arrow 3-3 shown in FIG. 1A.

Fig. 4 is a sectional view of the heating unit.

Fig. 5 is a side view of the heating unit.

Fig. 6 is an enlarged sectional view of the connecting part between the heating unit and the outer spacer.

Fig. 7 is an enlarged schematic sectional view of the heating assembly.

Fig. 8 schematically shows the axial relationship between the base material portion of the smoking article, on the one hand, and the heating element and the inner tube of the aroma inhalation device, on the other hand, in the aroma inhalation device according to the present embodiment.

DESCRIPTION OF EMBODIMENTS

[0008] Embodiments of the invention will be discussed with reference to the accompanying drawings. With regard to the drawings discussed below, the same or equivalent sub-parts will be provided with the same reference numerals, and the matching discussion will be omitted.

[0009] FIG. 1A is a perspective perspective view of an aroma inhalation device according to one embodiment. Fig. 1B is a perspective perspective view of an embodiment of an aroma inhalation device into which a smoking article is inserted. The aroma inhalation device 10 according to the present embodiment is configured to generate an aroma-containing aerosol, for example, by heating a smoking article 110 (which is one example of an aroma-generating article) having an aroma source (which is an example of an aerosol-forming base material) that includes an aerosol source .

[0010] As illustrated in Figures 1A and 1B, the aroma inhalation device 10 includes an upper case 11A, a lower case 11B, a cap 12, a switch 13, and a cap portion 14. The upper case 11A and the lower case 11B are connected to each other to form a case 11 (second body) located on the outermost side of the device 10 for inhaling aroma. The body 11 is sized to fit the user's hand. By using the aroma inhalation device 10, the user can hold the aroma inhalation device 10 in his hand and inhale the aroma.

[0011] The upper body 11A has an opening, not shown. A cap 12 is attached to the upper body 11A to cover the opening. As illustrated in FIG. 1B, the cap 12 has an opening 12a into which the smoking article 110 can be inserted. The cap portion 14 is provided for opening/closing the cap 12 opening 12a. a position for closing the opening 12a and a second position for opening the opening 12a. Thus, the cap portion 14 may allow or restrict access of the smoking article 110 to the interior of the inhalation device 10 (the opening in the outer spacer 17 or the opening in the top cap 48, which will be discussed later).

[0012] The switch 13 is used to turn on and off the operation of the device 10 for inhaling the aroma. For example, if the user operates the switch 13 with the smoking article 110 inserted into the opening 12a, as illustrated in FIG. 1B, electrical power is supplied from a power source, not shown, to a heating element, not shown, allowing smoking article 110 to be heated without smoking article 110 being burned. the source of the aroma is carried away by the aerosol. The user can inhale the flavor-containing aerosol by puffing from the portion (which is illustrated in FIG. 1B) of the smoking article 110 that protrudes from the flavor inhalation device 10. In the present description, the longitudinal direction of the aroma inhaling device 10 is the direction in which the smoking article 110 is inserted into the opening 12a.

[0013] The following discussion explains the configuration of the smoking article 110 used in the flavor inhalation device 10 according to the present embodiment. Fig. 2 is a sectional view of a smoking article 110. According to one embodiment shown in FIG. 2, the smoking article 110 includes a base material portion 110A containing a filler 111 (which is an example of a flavor-generating base material) and a first wrapping paper 112 that wraps the filler 111, and a mouthpiece portion 110B that forms an end portion opposed to the base material portion 110A. material. The base material part 110A and the mouthpiece part 110B are connected to each other by the second wrapping paper 113, which is separate from the first wrapping paper 112. However, to connect the base material part 110A and the mouthpiece part 110B, it is possible to use the first wrapping paper 112 instead of the second wrapping paper 113.

[0014] Mouthpiece 110B in FIG. 2 includes a paper tubular section 114, a filter section 115, and a hollow segmental section 116 placed between the paper tubular section 114 and the filter section 115. The hollow segmented section 116 includes, for example, a fill layer having one or more hollow channels, and a plug wrap that surrounds the placeholder. The filler layer has a high fiber packing density. Therefore, during inhalation, air and aerosol flow only through the hollow channel and hardly flow through the fill layer. If it is desired to prevent the reduction of the aerosol component that is due to filtration through the filter portion 115 in the smoking article 110, the length of the filter portion 115 is reduced and the reduction is offset by the hollow segment portion 116, which is effective to increase the amount of aerosol delivered.

[0015] Mouthpiece 110B in FIG. 2 includes three segments. However, according to the present embodiment, the mouthpiece 110B may include one or two segments, or may include four or more segments. For example, the hollow segmented portion 116 may be omitted and the paper tubular portion 114 and the filter portion 115 may be placed adjacent to each other to form the mouthpiece 110B.

[0016] According to the embodiment illustrated in FIG. 2, the smoking article 110 in the longitudinal direction preferably has a length in the range of 40 mm to 90 mm, more preferably 50 mm to 75 mm, and even more preferably 50 mm to 60 mm. The smoking article 110 preferably has a circumference in the range of 15 mm to 25 mm, more preferably 17 mm to 24 mm, and even more preferably 20 mm to 23 mm. The smoking article 110 may include a base material portion 110A having a length of 20 mm, a first wrapping paper 112 having a length of 20 mm, a hollow segment portion 116 having a length of 8 mm, and a filter portion 115 having a length of 7 mm. However, the length of each of the above segments can be appropriately changed according to the production feasibility, the required quality, and the like.

[0017] According to the present embodiment, the filler 111 of the smoking article 110 may comprise an aerosol source that is heated at a predetermined temperature and releases the aerosol. The aerosol source may be of any type. Materials extracted from various natural products and/or their components may be selected depending on the intended use. Examples of the aerosol source include glycerin, propylene glycol, triacetin, 1,3-butanediol, and mixtures thereof. The amount of the contained aerosol source in the filler 111 is not particularly limited as long as the aerosol source generates the aerosol sufficiently. For reasons of good flavor when smoking, the amount of aerosol source contained is generally 5% by weight or more, preferably 10% by weight or more, and generally 50% by weight or less, preferably 20% by weight or less.

[0018] The filler 111 of the smoking article 110 according to the present embodiment may contain cut tobacco as a flavor source. The cut tobacco may be formed from any material, and commonly known materials such as laminae and stems may be used. If the circumference of the smoking article 110 is 22 mm and the length is 20 mm, the content range of the filler 111 in the smoking article 110 varies, for example, from 200 mg to 400 mg, preferably from 250 mg to 320 mg. The filler 111 has a moisture content of, for example, 8% by weight to 18% by weight, preferably 10% by weight to 16% by weight. The above moisture content prevents staining of the wrapping paper, and improves the reelability in the manufacture of the base material portion 110A. There is no particular limitation on the size and production method of the shredded tobacco used as the filler 111. For example, dried tobacco leaves that are cut into pieces each having a width in the range of 0.8 mm to 1.2 mm can be used. It is also possible to use dried tobacco leaves that are ground to particles having an average particle diameter of about 20 µm to about 200 µm, and shaped and processed to form a sheet, and cut into fragments, each of which has a width in the range of 0.8 mm. up to 1.2 mm. Leaves processed into a sheet may be processed in the assembly process without cutting, for use as filler 111. Filler 111 may contain one or more flavored chemical compounds. Flavor-bearing chemical compounds can be of any type. However, for reasons of good smoking flavor, menthol is the preferred flavor.

[0019] According to the present embodiment, the first wrapping paper 112 and the second wrapping paper 113 of the smoking article 110 may be made from a base paper having a basis weight in the range of 20 g/m ² to 65 g/m ² , for example, and preferably from 25 g/m ² to 45 g/m ² . The thickness of the first wrapping paper 112 and the second wrapping paper 113 is not particularly limited. However, for reasons of stiffness, air permeability and ease of control during papermaking, the first wrapping paper 112 and the second wrapping paper 113 have a thickness in the range of 10 µm to 100 µm, preferably 20 µm to 75 µm, and more preferably 30 µm to 50 µm.

[0020] According to the present embodiment, the first wrapping paper 112 and the second wrapping paper 113 of the smoking article 110 may contain a filler. The amount of filler contained may range from 10% by weight to 60% by weight, based on the combined weight of the first wrapping paper 112 and the second wrapping paper 113, and preferably from 15% by weight to 45% by weight. According to the present embodiment, the amount of filler contained is preferably in the range of 15% by weight to 45% by weight, relative to the preferred range of basis weight (25 g/m ² to 45 g/m ² ). As the filler, for example, calcium carbonate, titanium dioxide, kaolin, or the like can be used. Paper containing such a filler exhibits a light whitish color, which is preferable in terms of the appearance of the wrapping paper of the smoking article 110, and can permanently retain whiteness. If the wrapping paper contains a large amount of such a filler, for example, the whiteness percentage of the wrapping paper according to International ISO Standards can be adjusted to 83% or more. For reasons of practical application of the first wrapping paper 112 and the second wrapping paper 113 as the wrapping paper of the smoking article 110, it is preferable that the first wrapping paper 112 and the second wrapping paper 113 have a tear strength of 8 N/15 mm or higher. Tensile strength can be increased by reducing the amount of filler content. More specifically, the tensile strength can be improved by reducing the amount of filler content to less than the upper limit of the amount of filler content, relative to each of the above-mentioned basis weight ranges.

[0021] The following discussion explains the internal construction of the aroma inhalation device 10 illustrated in Figures 1A and 1B. Fig. 3 is a sectional view as seen along the direction of the arrow 3-3 shown in FIG. 1A. As illustrated in FIG. 3, the fragrance inhaler 10 includes a power supply 20, a circuit block 30, and a heating block 40, in the interior of the case 11. The circuit block 30 includes a first printed circuit board 31 and a second printed circuit board 32 which is electrically connected to the first printed circuit board 31. The first circuit board 31 is arranged extended in the longitudinal direction, for example, as illustrated in the figure. Thereby, the power supply unit 20 and the heating unit 40 are separated from each other by the first circuit board 31. As a result, the heat generated in the heating unit 40 can be prevented from being transferred to the power supply unit 20.

[0022] The second circuit board 32 is placed between the power supply 20 and the switch 13, and is extended in a direction perpendicular to the extension direction of the first circuit board 31. The switch 13 is placed adjacent to the second circuit board 32. When the user presses the switch 13, the switch 13 can come in partial contact with the second printed circuit board 32.

[0023] The first circuit board 31 and the second circuit board 32 include, for example, a microprocessor or the like, and are capable of controlling the power supply from the power supply 20 to the heating unit 40. Thereby, the first circuit board 31 and the second circuit board 32 can control the heating of the smoking article 110, which is produced by the heating unit 40.

[0024] The power supply 20 includes a power supply 21 that is electrically connected to the first printed circuit board 31 and the second printed circuit board 32. The power supply 21 may be a rechargeable battery or a non-rechargeable battery, for example. The power supply 21 is electrically connected to the heating block 40 through at least one of the first circuit board 31 and the second circuit board 32. Thereby, the power supply 21 can supply power to the heating block 40 to properly heat the smoking article 110. As illustrated in the figure, the power supply 21 the power supply unit is placed near the heating unit 41 in a direction perpendicular to the longitudinal direction of the heating block 40. Thus, it is possible to prevent the aroma inhaling device 10 from elongating in the longitudinal direction even if the size of the power supply 21 is increased.

[0025] The fragrance inhalation device 10 further includes a terminal 22 that can be connected to an external power source. Pin 22 may be connected to the cable, for example via a micro USB connector or the like. If the power supply 21 is a rechargeable battery, the power supply 21 can be charged by connecting to an external power supply via the output 22 for supplying current from the external power supply to the power supply 21. It is also possible to connect a data cable to terminal 22 via a micro USB connector or the like, so that data pertaining to the operation of the inhaling device 10 and the like can be transmitted to an external device.

[0026] The heating unit 40 includes a heating unit 41 extended in the longitudinal direction as illustrated in the figure. The heating unit 41 includes numerous cylindrical elements, and as a whole forms a cylindrical body. The heating unit 41 is configured so that a portion of the smoking article 110 can be inserted inside it.

[0027] The lower case 11B is provided with a vent 15 (which is an example of an air inlet) through which air can enter the heating unit 41. More specifically, the vent 15 is in fluid communication with one end portion (the end portion on the left side in Fig. 3) of the heating unit 41. The aroma inhaling device 10 includes an attachable/detachable cover 16 on the vent 15. The cover 16 is formed so that air can flow into the heating unit 41 through the vent 15 even in a state where the cover 16 attached to the vent 15. The cover 16 may include, for example, a through hole, slot, or the like, not shown. When the cover 16 is attached to the vent 15, the substance generated from the smoking article 11 inserted into the heating unit 41 can be prevented from escaping from the vent 15 to the outside of the case 11.

[0028] The other end (the end on the right side in FIG. 3) of the heating unit 41 is in fluid communication with the opening 12a (which is an example of an air outlet) illustrated in FIG. 1B. A substantially cylindrical outer spacer 17 is provided between the cap 12 with opening 12a and the other end of the heating unit 41. The outer spacer 17 mates with the downstream end of the upper cap 48, mentioned later. When the smoking article 110 is inserted into the opening 12a of the cap 12 in the inhaling device 10, as illustrated in FIG. 1B, the smoking article 110 passes through the outer spacer 17, and at least a portion of the filler 111 (see FIG. 2) of the smoking article 110 is placed within the heating assembly 41. In other words, the outer spacer 17 forms part of the open area for receiving the smoking article 110. the spacer 17 is preferably formed such that the opening adjacent to the cap 12 (right side in FIG. 3) is larger than the opening adjacent to the heating unit 41 (left side in FIG. 3). This facilitates insertion of the smoking article 110 into the outer spacer 17 through the opening 12a. When the smoking article 110 is not inserted inside the heating unit 41, the user can clean the inside of the heating unit 41 by inserting a tool such as a brush from the hole 12a into the heating unit 41. The cleaning tool can be inserted from one end portion (the end portion on the left side into Fig. 3) heating unit 41. In this case, the cover 16 is removed from the ventilation hole 15 of the device 10 for inhaling aroma.

[0029] If the user takes a puff from the part of the smoking article 110 that protrudes from the aroma inhalation device 10, that is, from the filter unit 115 illustrated in FIG. 2, with the smoking article 110 inserted into the inhaling device 10 through the opening 12a, as illustrated in FIG. 1B, air enters the heating unit 41 through the vent 15. After entering the heating unit 41, the air passes through the heating unit 41 and reaches the user's mouth along with the aerosol generated from the smoking article 110. Accordingly, the end of the heating unit 41, which is the closest towards the vent 15 is referred to as the upstream side, while the end of the heater assembly 41 that is adjacent to the vent 12a (the end close to the outer spacer 17) is referred to as the downstream side.

[0030] The configuration of the heating unit 41 illustrated in FIG. 3. FIG. 4 is a sectional view of the heating unit 41. FIG. 5 is a side view of the heating unit 41. The heating unit 41 includes an inner tube 42 (which is an example of the first cylindrical element), a heating element 43, an airgel 44 (which is an example of a thermal insulation material), and an outer tube 45 (which is an example of the second cylindrical element). The inner tube 42 is provided at one end with a first hole 42a into which the smoking article 110 can be inserted, and at the other end is further provided with a second hole 42b which forms an air inlet. According to the present embodiment, the inner tube 42 has a cylindrical shape and is designed to be brought into contact with at least a portion of the smoking article 110 inserted through the first hole 42a. The second hole 42b is upstream in the direction of air flow, and the first hole 42a is downstream in the direction of air flow.

[0031] Outer tube 45 is positioned to enclose inner tube 42 which creates a predetermined space between inner tube 42 and outer tube 45. Heating element 43 may be a flexible film heater that is fabricated, for example, by sandwiching a heat generating resistive element between two polyimide (PI) films or other similar films. The heating element 43 is placed so as to bear against the inner tube 42. More specifically, in the example illustrated in the figure, the heating element 43 is placed on the outer circumferential surface of the inner tube 42, and the inner surface of the heating element 43 is in contact with the outer surface of the inner tube 42. Since the heating the element 43 is placed along the outer circumferential surface of the inner tube 42, the heating element 43 is generally deformed into a substantially cylindrical shape.

[0032] The heating unit 41 further includes a first annular member 46 that is circumferentially extended between the downstream end portion of the inner tube 42 (the end portion on the side of the first opening 42a) and the downstream end portion of the outer tube 45 (the end portion close to the first opening 42a of the inner tube 42). The heating unit 41 includes a second annular member 47 which is circumferentially extended between the upstream end portion of the inner tube 42 (the end portion on the side of the second opening 42b) and the upstream end portion of the outer tube 45 (the end portion close to the second opening 42b of the inner tube 42). The first annular element 46 is tightly connected to the downstream end of the inner tube 42 through the top cap 48 and heat shrink tubing 52, which will be discussed later. The second annular element 47 is tightly connected to the upstream end of the inner tube 42 through the lower cap 50 and heat shrink tubing 52, which will be discussed later. The first annular element 46 and the second annular element 47 are tightly connected to the outer tube 45. A sealed zone 54 is thus created between the inner tube 42 and the outer tube 45. The sealed zone 54 encloses the heating element 43 and the airgel 44.

[0033] A heat shrink tube 52 is placed between the heating element 43 and the airgel 44. The heat shrink tube 52 is cylindrical in shape and holds the heating element 43 in contact with the inner tube 42. More specifically, the heat shrink tube 52 is tucked in to heat shrink by applying heat thereto when it is placed on the outer peripheral side of the heating element 43. Thereby, the heat shrink tube 52 exerts a voltage on the heating element 43, pressing the heating element 43 against the inner tube 42. The heat shrink tube 52 may be made of a thermoplastic resin such as perfluoroalkoxylated fluoroplastics (PFA). According to the present embodiment, the heat shrink tube 52 is used for the purpose of maintaining the state where the heating element 43 is in contact with the inner tube 42. However, any element that achieves the same purpose can be used instead of the heat shrink tube 52. For example, an elastic tube or the like may be used instead of the heat shrink tube 52.

[0034] The inner tube 42 is preferably made from a metallic material such as stainless steel (SUS), which has a high thermal conductivity. This facilitates heat transfer from the heating element 43 to the entire inner tube 42, ensuring that the inner tube 42 functions fully as a heater. The outer tube 45 may be made of the same metallic material as the inner tube 42, for example. In an embodiment, airgel 44 is used to insulate heat generated by heating element 43. Airgel 44 may be formed from various kinds of airgel materials, including silica airgel, carbon airgel, alumina airgel, and the like. Other insulating materials may also be used instead of airgel. Such insulation materials include, for example, fiber-based thermal insulation material such as glass wool and mineral wool, foamed thermal insulation material such as polyurethane foam and phenolic foam. It is also possible for the sealed zone 54 to be evacuated to form a vacuum insulating region. If airgel 44 is used as the heat insulating material, then airgel 44 preferably occupies a cubic volume in the range of 85% to 100% of the volume of the sealed area 54. This suppresses the penetration of air bubbles into the sealed area 54, and thereby prevents heat transfer from the heating element 43, the inner tube 42 and the like onto the outer tube 45 by air bubbles. If air bubbles enter the sealed area 54, they move freely depending on the position of the heating unit 41, and could transfer heat.

[0035] The heating assembly 41 further includes an upper cap 48 and a lower cap 50. The upper cap 48 and the lower cap 50 may be made of a resin material, for example. The top cap 48 is a cylindrical member having an internal volume in communication with the first opening 42a of the inner tube 42. The top cap 48 is configured to receive a smoking article 110. As illustrated in Figures 4 and 5, the top cap 48 is connected to the downstream end of the inner tube 42 (the end part on the side of the first hole 42a). The top cap 48 is provided with one or more raised portions 48a on its inner peripheral surface. The raised portions 48a are arranged circumferentially spaced from each other at regular intervals. The present embodiment includes four raised portions 48a which are placed on the inner peripheral surface of the top cap 48. The raised portions 48a create frictional resistance for the smoking article 110 inserted into the top cap 48 in close contact with the smoking article 10. The raised portions 48a thereby prevent accidental slipping of the smoking article 110 from the inhalation device 10 .

[0036] The bottom cap 50 is an elongated cylindrical member that includes a downstream end 50a connected to an upstream end (an end portion on the side of the second opening 42b) of the inner tube 42, and an upstream end 50b on the opposite side relative to the downstream end 50a. The bottom cap 50 defines an internal passage that introduces air towards the second opening 42b of the inner tube 42. The upstream end 50b (end portion on the bottom side in the figure) of the bottom cap 50 is positioned against or adjacent to the vent 15 illustrated in FIG. 3. Air from vent 15 can flow from upstream end 50b to downstream end 50a of bottom cap 50, pass through inner tube 42 and top cap 48, and reach the user's mouth. In other words, the lower cap 50, the inner tube 42 and the upper cap 48 form an air passage 70 which brings the vent hole 15 and the hole 12a of the cap 12 into air communication with each other.

[0037] The connecting part between the heating unit 41 and the outer spacer 17 will now be discussed in detail. FIG. 6 is an enlarged sectional view of the connecting part between the heating unit 41 and the outer spacer 17. As illustrated in FIG. 6, a hollow rubber material 24 is disposed in the connecting part between the outer spacer 17 and the top cap 48. More specifically, the upstream end (the end portion on the side of the first opening 42) of the outer spacer 17 encloses at least partially the outer periphery of the top cap. 48, or more specifically, the outer periphery of the downstream end of the top cap 48. The upstream end of the outer spacer 17 has a larger internal diameter than the outer diameter of the downstream end of the inner tube 42 to accommodate the downstream end of the top cap 48. The outer spacer 17 includes a seat 17a for receiving the rubber material 24. More specifically, a predetermined space is provided between the seat 17a of the outer spacer 17 and the outer surface of the top cap 48. The rubber material 24 has an annular shape and runs circumferentially between the outer peripheral surface of the top cap 48 and the inner peripheral surface of the outer spacer 17. The space between the top cap 48 and the outer spacer 17 is thus sealed. The rubber material 24 may have a solid structure instead of a hollow structure.

[0038] The following discussion explains the relative positions of inner tube 42, heating element 43, airgel 44, outer tube 45, top cap 48, bottom cap 50, and heat shrink tube 52. FIG. 7 is an enlarged sectional view of the heating unit 41. FIG. 7 is a view for explaining the relative positional relationship of the constituent elements of the heating unit 41, so that the specific shapes, sizes, and the like of the constituent elements may differ from the actual ones. In FIG. 7, the upstream side (lower side in the figure) of the bottom cap 50 is not shown.

[0039] As illustrated, the upstream end (the end portion on the side closer to the first opening 42a) of the upper cap 48 encloses the outer periphery of the downstream end (the end portion on the side of the first opening 42a) of the inner tube 42. In other words, located the upstream end of the top cap 48 has a larger inner diameter than the outer diameter of the downstream end of the inner tube 42 to accommodate the downstream end of the inner tube 42. The connecting portion of the inner surface of the upper cap 48 and the connecting portion of the outer surface of the inner tube 42 sealed relative to each other, for example, by means of an adhesive or the like. The connecting parts are thus designed to prevent the leakage of gas or aerosol from the gap between the upper cap 48 and the inner tube 42. top cap 48. Heat shrink tubing 52 is in intimate contact with the upstream end of top cap 48. As mentioned, heating assembly 41 includes axially overlapping regions between top cap 48 and inner tube 42, and between top cap 48 and heat shrink tube 52. The overlapping regions are in close contact with each other or compacted with each other. This improves the seal between the top cap 48 and the inner tube 42 and between the top cap 48 and the heat shrink tube 52.

[0040] The downstream end 50a (end portion on the side near the second opening 42b) of the lower cap 50 encloses the outer periphery of the upstream end (end portion on the side of the second opening 42b) of the inner tube 42. That is, downstream the end 50a of the lower cap 50 has a larger inner diameter than the outer diameter of the upstream end of the inner tube 42 to accommodate the upstream end of the inner tube 42. The connecting part of the inner surface of the lower cap 50 and the connecting part of the outer surface of the inner tube 42 are connected to each other with a friend, for example, by means of an adhesive. The connecting parts are designed to prevent gas or aerosol from flowing through the gap between the bottom cap 50 and the inner tube 42. cap 50. Heat shrink tubing 52 is in intimate contact with downstream end 50a of bottom cap 50. As mentioned, heating assembly 41 includes axially overlapping regions between bottom cap 50 and inner tube 42, and between bottom cap 50 and heat shrink tube 52. The overlapping regions are in close contact with each other or compacted with each other. This improves the seal between the bottom cap 50 and the inner tube 42 and between the bottom cap 50 and the heat shrink tube 52.

[0041] As illustrated, the top cap 48, the inner tube 42, and the bottom cap 50 are placed in the axial direction, and each two adjacent members are airtightly connected to form a tubular structure having a sealed structure. The interface between the upper cap 48 and the inner tubular cap and the interface between the inner tube 42 and the lower cap 50 in the tubular structure may have a sealed structure that creates a negative pressure in the range of 40 kPa to 60 kPa, based on atmospheric air pressure. More specifically, each of the interface sections preferably has a sealed structure that maintains a negative pressure in the range of 45 kPa to 55 kPa. Preferably, each of the interface sections should typically provide a negative pressure of 50 kPa.

[0042] Whether each of the interface portions has the desired sealing structure can be tested, for example, by the following method. First, the opening of either the top cap 48 or the bottom cap 50 is closed and air is evacuated from the opening on the other cap using a vacuum pump to apply negative pressure to the tubular structure. Pumping is stopped at the point in time when the negative pressure in the tubular structure reaches the desired value (eg 50 kPa). Then, the tubular structure is allowed to stand for a predetermined period of time, and thereafter, the pressure change in the tubular structure is measured. If the change in pressure during this measurement is less than a predetermined threshold value, then it is concluded that each of the interface sections has the desired tightness. The length of time the tubular structure is left to stand after pumping is stopped is, for example, 3 seconds, and the pressure change threshold is 2.3 kPa.

[0043] The lower cap 50 includes a small diameter portion 50c having a smaller inner diameter than the inner tube 42. The portion of the lower cap 50 that encloses the outer periphery of the upstream end of the inner tube 42 and the small diameter portion 50c forms the portion 50d conjugation, having a stepped shape. In other words, the mating portion 50d creates a surface substantially perpendicular to the axial direction of the inner tube 42. As illustrated, the upstream end of the inner tube 42 is placed adjacent to the mating portion 50d. The small diameter portion 50c is formed to have a diameter such that the end portion of the smoking article 110 abuts against the interface portion 50d when the smoking article 110 is inserted through the first hole 42a. Thereby, the smoking article 110 can be positioned.

[0044] As illustrated, the downstream end (the end part on the side of the first hole 42a) and the upstream end (the end part on the side of the second hole 42b) of the inner tube 42 are made protruding beyond the outer tube 45. As illustrated, the heating element 43 is inserted between the upstream and downstream ends of the outer tube 45 in the axial direction. In other words, the heating element 43 is configured not to contact the upstream end of the inner tube 42 that protrudes outward from the outer tube 45. This makes the upstream end of the inner tube 42 at a lower temperature than the axially central end. part of the inner tube 42. Thus, it is possible to prevent the end portion of the smoking article 110 in the state where the smoking article 110 is inserted from the first hole 42a from abutting the interface portion 50d from heating. This prevents inadvertent release of aerosol from the end portion of the smoking article. The end portion of the smoking article 110 has a relatively low temperature, which encourages condensation and accumulation of aerosol in the end portion of the smoking article 110. This makes it possible to prevent the aerosol generated on the downstream side from flowing back through the air passage 70.

[0045] The heat shrink tube 52 has an axial length substantially equal to the length of the inner tube 42. The heat shrink tube 52 is longer than the heating element 43 in the axial direction, and the heating element 43 is placed between the upstream and downstream ends of the heat shrink sleeve. tube 52. Thus, heat shrink tube 52 can cover the entire heating element 43 and provide uniform contact of the heating element 43 with the inner tube 42. Airgel 44 in the axial direction lies at least between the upstream end and the downstream end of the heating element 43 This makes it possible to effectively isolate the heat generated by the heating element 43.

[0046] The upstream end (end on the side closer to the first hole 42a) of the top cap 48 is upstream (lower side in the figure) relative to the downstream end (end on the side closer to the first hole 42a) of the outer tube 45. The downstream end 50a of the bottom cap 50 is outside the outer tube 45. The upstream end (end portion on the side closer to the second hole 42b) of the heat shrink tube 52 protrudes outward from the outer tube 45 and surrounds the outer periphery of the bottom cap 50 as described above.

[0047] The first annular element 46 and the second annular element 47 are in direct contact with the inner tube 42 and the outer tube 45. Therefore, if the first annular element 46 and the second annular element 47 were made of a material having a high thermal conductivity, most of the heat the inner tube 42 could be transmitted through the first ring 46 and the second ring 47 to the outer tube 45. According to the present embodiment, the first annular 46 and the second annular 47 may be made of a material having a lower thermal conductivity than the inner tube 42 and an outer tube 45. More specifically, the first annular member 46 and the second annular member 47 may be formed from a resin such as a UV curable resin or a UV curable resin, for example. This prevents heat transfer from the inner tube 42 to the outer tube 45.

[0048] The heating assembly 41 includes a heater shank 56 that electrically connects the heating element 43 to the circuit block 30 (which is an example of a control block) illustrated in FIG. 3. As illustrated in FIG. 7, at least a portion of the heater shank 56 extends along the outer surface of the inner tube 42 and the outer surface of the lower cap 50, extending beyond the sealed zone 54.

[0049] The inner diameter of the bottom cap 50 may be constant from the downstream end 50a to the upstream end 50b. The bottom cap 50 may have a tapered inner surface, and the inner diameter of the bottom cap 50 may accordingly increase from the downstream end 50a towards the upstream end 50b. The ratio of Dc to Dmax (Dc/Dmax) varies from 1.4 to 2.34, for example, where the largest inner diameter of the bottom cap 50 is Dmax and the inner diameter of the inner tube 42 is Dc. The ratio of Dc to Dmax is preferably in the range of 1.56 to 2.01, and is typically 1.75. Therefore, if the inner diameter Dc of the inner tube 42 is 7.00 mm, the largest diameter Dmax of the lower cap 50 varies, for example, from 2.99 mm to 4.99 m, preferably from 3.49 mm to 4.49 m, and usually is 3.99 mm. When the smoking article 110 has a diameter close to the inner diameter of the inner tube 42, and if the largest diameter of the lower cap 50 and the largest diameter of the inner tube 42 are in the above ranges, the end portion of the smoking article 110 is securely held by the interface portion 50d of the lower cap 50, and at the same time at the same time, the airway passage 70 is sufficiently provided. The diameter of the lower cap 50 here includes the inner diameter of the small diameter portion 50c, excluding the portion of the lower cap 50 that surrounds the inner tube 42.

[0050] The following discussion explains the relationship between the smoking article 110 and the heating unit 41 in a state where the smoking article 110 is inserted into the aroma inhaling device 10. Fig. 8 schematically shows the axial relationship between the base material portion 110A of the smoking article 110, on the one hand, and the heating element 43 and the inner tube 42 of the aroma inhalation device 10, on the other hand, in the aroma inhalation device 10 according to the present embodiment. Here, the axis means the central axis of the first opening 42a in the fragrance inhaler 10 . When the smoking article 110 is inserted into the first hole 42a, the axis and the central axis of the smoking article 110 partially coincide with each other.

[0051] If the axial length of the heating element 43 is D0, and the axial length of the base material portion 110A of the smoking article 110 is L0, the length D0 can be shortened to shorter than the length L0 (D0<L0). The ratio of length D0 to length L0 (D0/L0) may be in the range of 0.70 to 0.90, preferably 0.75 to 0.85, and may typically be 0.80. Therefore, when the length L0 of the base material portion 110A is 20 mm, the length D0 of the heating element 43 varies from 14 mm to 18 mm, preferably from 15 mm to 17 mm, and can generally be 16 mm. If the ratio of the length D0 to the length L0 (D0/L0) is adjusted to the above-mentioned range, a desired amount of aerosol generation can be achieved, and at the same time, the size of the heating element 43 in the length direction can be reduced.

[0052] With reference to FIG. 8, the upstream end of the base material portion 110A may project further upstream than the upstream end of the heating element 43 by a length D1. The terms "upstream" and "downstream" respectively refer to the upstream and downstream flow of air passing through the air passage 70 in response to the user's inhalation (see FIG. 4). The protruding portion of the base material portion 110A that protrudes from the heating element 43 does not include the heating element 43 on its radially outer side, so that the protruding portion may have an internal temperature slightly lower than the outer portions of the base material portion 110A. This prevents aerosol formation at and near the upstream end of base material portion 110A. In addition, the aerosol generated at and near the upstream end of the base material portion 110A can be prevented from condensing in the air passage or flowing back through the air passage to cause leakage from the device. The ratio of the projecting length D1 to the entire length L0 of the base material section 110A (D1/L0) varies from 0.25 to 0.40, preferably from 0.30 to 0.35, and can typically be 0.325. Therefore, if the entire length L0 of the base material portion 110A is 20 mm, the protruding length D1 varies from 5 mm to 8 mm, preferably from 6 mm to 7 mm, and can generally be 6.5 mm. The protruding length D1 here can also be referred to as the axial distance between the upstream end of the heating element 43 and the upstream end of the inner tube 42. If the ratio of the protruding length D1 to the length L0 (D1/L0) is adjusted in the above range, aerosol generation at and near the upstream end of the base material section 110A, while sufficient aerosol generation can be achieved in other parts of the base material section 110A.

[0053] With reference to FIG. 8, the downstream end of the heating element 43 may protrude further downstream than the downstream end of the base material portion 110A by a length D2. This allows sufficient heating of the downstream end of the base material section 110A and a portion near it, which prevents an insufficient amount of aerosol generated and the occurrence of aerosol condensation at the downstream end of the base material section 110A and the area near it. The ratio of the protruding length D2 of the heating element 43 to the length L0 of the base material portion 110A (D2/L0) ranges from 0.075 to 0.175, preferably from 0.1 to 0.15, and can typically be 0.125. Therefore, if the length L0 of the base material portion 110A is 20 mm, the protruding length D2 of the heating element 43 may be in the range of 1.5 mm to 3.5 mm, preferably 2 mm to 3 mm, and may generally be 2.5 mm. . If the ratio of the protruding length D2 to the length L0 (D2/L0) is adjusted in the above range, it is possible to achieve sufficient aerosol generation at and near the downstream end of the base material portion 110A, and at the same time, the heating element 43 is prevented from growing in size in the direction length.

[0054] The axial position of the upstream end of the inner tube 42 and the axial position of the upstream end of the base material portion 110A may more or less coincide. Like the downstream end of the heating element 43, the downstream end of the inner tube 42 may protrude further downstream than the downstream end of the base material portion 110A by a length D3. This allows the upstream end of the paper tubular section 114 and the area near it, as well as the downstream end of the base material section 110A and the area near it to be heated. This prevents excessive cooling of the aerosol formed from base material portion 110A and condensation at and near the upstream end of paper tubular portion 114. The ratio of the protruding length D3 of the inner tube 42 to the protruding length D2 of the heating element 43 (D3/D2) varies from 2.6 to 3.4, preferably from 2.8 to 3.2, and can typically be 3.0. Therefore, if the protruding length D2 of the heating element 43 is 2.5 mm, the protruding length D3 of the inner tube 42 varies from 6.5 mm to 8.5 mm, preferably from 7.0 mm to 8.0 mm, and can generally be 7 .5 mm. If the ratio of the projecting length D3 to the projecting length D2 (D3/D2) is adjusted in the above range, it is possible to prevent condensation of aerosol at and near the upstream end of the paper tube portion 114, and at the same time prevent the heating element 43 from increasing in size in the direction length.

[0055] Embodiments of the invention have been discussed. However, the invention need not be carried out according to the above-described embodiments. The invention can be modified in various ways within the scope of the claims and technical ideas discussed in the description and drawings. Any form and material that provides the operation and advantageous effects of the invention are within the scope of the technical ideas of the invention, even if there is no express reference to such form and material in the description and drawings.

[0056] Some embodiments disclosed in the present description are described below.

[0057] According to a first embodiment, a heating assembly is provided that includes a first cylindrical element at one end with a first opening into which an aroma-generating article can be inserted and at the other end with a second opening that forms an air inlet; and thermal insulation material. The heating unit additionally includes a second cylindrical element placed around the first cylindrical element. A sealed zone is provided between the first cylindrical element and the second cylindrical element. A heating element and heat-insulating material are placed in the sealed zone.

[0058] According to the second embodiment, in the heating unit according to the first embodiment, the heating element is adjacent to the first cylindrical element, and the first cylindrical element is made of a metal material.

[0059] According to the third embodiment, in the heating unit according to the first or second embodiment, the heating element is located on the outer peripheral side of the first cylindrical element. Between the heating element and the heat-insulating material is the first polymeric material. The first polymeric material stresses the heating element by pressing the heating element against the first cylindrical element.

[0060] According to the fourth embodiment, in the heating unit according to the third embodiment, the first resin material is heat-shrinkable, and thereby stresses the heating element by pressing the heating element against the first cylindrical element.

[0061] According to the fifth embodiment, in the heating unit according to the third or fourth embodiment, the upstream end of the first polymeric material, which is adjacent to the second opening, protrudes outward from the second cylindrical member.

[0062] According to the sixth embodiment, in the heating unit according to the fifth embodiment, the heating unit includes a third cylindrical element including an interior space into which an aroma-generating article can be inserted, the interior space being in communication with the first opening of the first cylindrical element. The third cylindrical element is connected to the downstream end of the first cylindrical element, which is located on the side of the first hole. The downstream end of the first polymeric material, which is adjacent to the first opening, surrounds the outer periphery of the upstream end of the third cylindrical element, which is connected to the first opening.

[0063] According to the seventh embodiment, in the heating unit according to the sixth embodiment, the upstream end of the third cylindrical element surrounds the outer periphery of the downstream end of the first cylindrical element.

[0064] According to the eighth embodiment, in the heating unit according to any of the third to seventh embodiments, the first polymeric material has a length substantially equal to the axial length of the first cylindrical element.

[0065] According to the ninth embodiment, in the heating unit according to any of the third to eighth embodiments, the first polymeric material is longer than the heating element in the axial direction, and the heating element is located between the upstream end of the first polymeric material, which is adjacent to the second opening, and the downstream end of the first polymeric material which is adjacent to the first opening.

[0066] According to the tenth embodiment, in the heating unit according to any of the third to ninth embodiments, the heating unit includes a fourth cylindrical element connected to the upstream end of the first cylindrical element, which is located on the side of the second hole, and forms an internal channel , which introduces air towards the second opening of the first cylindrical element. The upstream end of the first polymeric material, which is adjacent to the second opening, surrounds the outer periphery of the fourth cylindrical element.

[0067] According to the 11th embodiment, in the heating unit according to the tenth embodiment, the downstream end of the fourth cylindrical element, which is adjacent to the second opening, surrounds the outer periphery of the upstream end of the first cylindrical element.

[0068] According to the 12th embodiment, in the heating unit according to any of the first to 11th embodiments, the upstream end of the first cylindrical element, which is on the side of the second hole, and the downstream end of the first cylindrical element , which is on the side of the first hole, protrudes outward from the second cylindrical element. The heating element is inserted between the upstream end of the second cylindrical element, which is adjacent to the second hole, and the downstream end of the second cylindrical element, which is adjacent to the first hole in the axial direction.

[0069] According to the 13th embodiment, in the heating assembly according to any one of the first to the 12th embodiments, the thermal insulation material is axially extended at least between the upstream end of the heating element that is adjacent to the second opening. , and located downstream end of the heating element, which is adjacent to the first hole.

[0070] According to the 14th embodiment, in the heating unit according to any of the first to 13th embodiments, the heating unit includes an annular member extending in the circumferential direction between the end portion of the first cylindrical member which is on the side of the first opening, and end section of the second cylindrical element, which is located near the first hole, and between the end section of the first cylindrical element, which is on the side of the second hole, and the end section of the second cylindrical element, which is located near the second hole.

[0071] According to the 15th embodiment, in the heating unit according to the 14th embodiment, the annular member is made of a material having a lower thermal conductivity than the first cylindrical member and the second cylindrical member.

[0072] According to the 16th embodiment, in the heating unit according to any one of the first to the 15th embodiments, the thermal insulation material includes an airgel.

[0073] According to the 17th embodiment, in the heating unit according to the 16th embodiment, the cubic volume of the thermal insulation material is in the range of 85% to 100% of the volume of the sealed area.

[0074] According to the 18th embodiment, in the heating assembly according to any of the first to 17th embodiments, the heating assembly includes a heater shank that electrically connects the heating element to the control unit. At least part of the heater shank runs along the outer surface of the first cylindrical element, protruding outward from the sealed area.

[0075] According to the 19th embodiment, in the heating unit according to any one of the first to the 18th embodiments, the heating element is for heating the aroma-generating article. The D0/L0 ratio ranges from 0.7 to 0.9, where L0 represents the axial length of the aroma generating base material in the aroma generating article and D0 represents the axial length of the heating element.

[0076] According to the 20th embodiment, in the heating unit according to the 19th embodiment, D0/L0 varies from 0.75 to 0.85.

[0077] According to the 21st embodiment, in the heating unit according to any one of the first to the 20th embodiments, the heating element is for heating the aroma-generating article. The ratio D1/L0 ranges from 0.25 to 0.40, where L0 represents the axial length of the flavor generating article and D1 represents the axial distance between the upstream end of the heating element and the upstream end of the first cylindrical element.

[0078] According to the 22nd embodiment, in the heating unit according to the 21st embodiment, the D1/L0 ratio varies from 0.30 to 0.35.

[0079] According to the 23rd embodiment, in the heating unit according to any of the first to 22nd embodiments, in a state where the aroma-generating article is inside the first cylindrical member so that the upstream end of the aroma-generating article and located the upstream end of the first cylindrical element is axially aligned with each other, the downstream end of the heating element is downstream of the downstream end of the aroma generating base material. The D2/L1 ratio ranges from 0.075 to 0.175, where D2 represents the axial distance between the downstream end of the heating element and the downstream end of the aroma-generating base material in the aroma-generating article, and L1 represents the axial length of the aroma-generating base material in aroma-generating product.

[0080] According to the 24th embodiment, in the heating unit according to the 23rd embodiment, D2/L1 varies from 0.1 to 0.15.

[0081] According to the 25th embodiment, in the heating unit according to any of the first to 23rd embodiments, in a state where the aroma-generating article is inside the first cylindrical member so that the upstream end of the aroma-generating article and located the upstream end of the first cylindrical element is axially aligned with each other, the downstream end of the heating element and the downstream end of the first cylindrical element are downstream of the downstream end of the aroma generating base material, and downstream the downstream end of the first cylindrical element is downstream of the downstream end of the heating element. The D3/D2 ratio ranges from 2.6 to 3.4, where D2 represents the axial distance between the downstream end of the heating element and the downstream end of the aroma-generating base material in the aroma-generating article, and D3 represents the axial distance direction between the downstream end of the first cylindrical member and the downstream end of the aroma-generating base material in the aroma-generating article.

[0082] According to the 26th embodiment, in the heating unit according to the 25th embodiment, D3/D2 varies from 2.8 to 3.2.

[0083] According to the 27th embodiment, an aroma inhalation device is provided that includes a heating unit according to any of the first to 26th embodiments.

[0084] According to the 28th embodiment, an aroma inhalation device is provided that includes an air passage for creating air communication between an air inlet and an air outlet. The air passage includes a first hollow tube that forms part of an opening portion for receiving an aroma source from outside; a second hollow tube that forms part of the heating unit; and a third hollow tube including an interface for positioning the aroma source. The third hollow tube, the second hollow tube and the first hollow tube are arranged in the order referred to as the direction from the air inlet towards the air outlet. The first hollow tube and the second hollow tube have an overlapping section in the longitudinal direction, and the second hollow tube and the third hollow tube have an overlapping section in the longitudinal direction. Both overlapping areas are sealed.

[0085] According to the 29th embodiment, in the aroma inhaling device according to the 28th embodiment, the second hollow tube has a cylindrical shape.

[0086] According to the 30th embodiment, in the aroma inhalation device according to the 28th or 29th embodiment, the second hollow tube is designed to accommodate the aroma source inside and to contact at least a portion of the aroma source.

[0087] According to the 31st embodiment, in the aroma inhalation device according to any one of the 28th to 30th embodiments, the first hollow tube includes a seat in an overlapping portion, the seat being suitable for receiving a downstream end the second hollow tube and has a larger inner diameter than the outer diameter of the downstream end of the second hollow tube.

[0088] According to the 32nd embodiment, in the aroma inhalation device according to any one of the 28th to 31st embodiments, the third hollow tube includes a seat in an overlapping portion, the seat being suitable for receiving an upstream end the second hollow tube and has a larger inner diameter than the outer diameter of the upstream end of the second hollow tube.

[0089] According to the 33rd embodiment, in the aroma inhalation device according to any one of the 28th to 32nd embodiments, the third hollow tube includes a first flavor source coupling portion in a region other than the overlapping portion, wherein the first aroma source coupling portion the aroma source has a smaller inner diameter than the inner diameter of the second hollow tube.

[0090] According to the 34th embodiment, in the aroma inhalation device according to any of the embodiments 28 to 33, the aroma inhalation device includes a fourth hollow tube disposed around the second hollow tube. The upstream end of the fourth hollow tube encloses the downstream end of the third hollow tube, and alternatively, the downstream end of the fourth hollow tube encloses the upstream end of the first hollow tube.

[0091] According to the 35th embodiment, in the aroma inhaling device according to any of the 28th to 34th embodiments, the contact portion in the overlapping portion between the inner surface of the first hollow tube and the outer surface of the second hollow tube are connected to each other through an adhesive.

[0092] According to the 36th embodiment, in the aroma inhaling device according to any of the 28th to 35th embodiments, the contact portion in the overlapping portion between the outer surface of the second hollow tube and the inner surface of the third hollow tube are connected to each other through an adhesive.

[0093] According to the 37th embodiment, in the aroma inhalation device according to any one of the 28th to 36th embodiments, the aroma inhalation device includes a housing configured to receive at least a portion of each of the first hollow tube , a second hollow tube, and a third hollow tube. The body includes an inlet in communication with the interior of the third hollow tube. The end section of the third hollow tube, other than the end section, including the overlapping section with the second hollow tube, is adjacent to the inlet channel of the housing.

[0094] According to the 38th embodiment, in the aroma inhalation device according to any one of the 28th to 37th embodiments, the first hollow tube is provided on the inner surface with a second aroma source interface for pairing the aroma source.

[0095] According to the 39th embodiment, in the aroma inhalation device according to any of the 28th to 38th embodiments, the second hollow tube is made of a metal material, and the first hollow tube and the third hollow tube are made of a resin material.

[0096] According to the 40th embodiment, in the aroma inhalation device according to any of the embodiments 28 to 39, the aroma inhalation device includes a sleeve member provided with an opening. The sleeve element forms part of the hole section.

[0097] According to the 41st embodiment, in the aroma inhaling device according to the 40th embodiment, the end portion of the first hollow tube other than the end portion including the overlapping portion with the second hollow tube is in engagement with the sleeve member

[0098] According to the 42nd embodiment, in the aroma inhaling device according to the 41st embodiment, a hollow rubber material is provided for mating the end portion of the sleeve member and the first hollow tube.

[0099] According to the 43rd embodiment, in the aroma inhaling device according to the 42nd embodiment, the sleeve member includes a seat for accommodating a rubber material.

[0100] According to the 44th embodiment, in the aroma inhalation device according to any one of the 40th to 43rd embodiments, the sleeve member has a larger inner diameter than the outer diameter of the first hollow tube. Sleeve element covers at least part of the first hollow tube.

[0101] According to the 45th embodiment, in the aroma inhalation device according to any one of the embodiments from the 40th to the 44th, the aroma inhalation device includes a movable cover element for providing or restricting access of the aroma source to the opening of the sleeve element or to section of the inner wall of the first hollow tube.

[0102] According to the 46th embodiment, in the aroma inhalation device according to any of the embodiments 28 to 45, the second hollow tube defines a portion of the space containing the heating element for heating the aroma source.

[0103] According to the 47th embodiment, in the aroma inhalation device according to any of the 28th to 46th embodiments, the Sc/Smax ratio varies from 1.4 to 2.34, where Smax represents the largest inner diameter of the third hollow tube, and Sc represents the largest outside diameter of the aroma source.

[0104] According to the 48th embodiment, in the aroma inhalation device according to the 47th embodiment, Sc/Smax ranges from 1.56 to 2.01.

LIST OF REFERENCES

[0105] 10 fragrance inhaler

11 building

12 cap

12a hole

14 cap part

15 vent

16 cover

17 outer spacer

17a seat

21 power supplies

24 rubber material

30 circuit block

41 heating units

42 inner tube

43 heating element

44 airgel

45 outer tube

46 first annular element

47 second ring element

48 top cap

50 bottom cap

50c section with small diameter

50d interface section

52 heat shrink tube

54 sealed area

56 heater shank

70 air duct

110 smoking article

111 filler.

Claims (57)

1. A heating assembly comprising a first cylindrical element, provided at one end with a first hole configured to insert an aroma-generating product into it, and at the other end with a second hole that forms an air inlet, a heating element and a heat-insulating material, moreover, the heating unit additionally contains a second cylindrical element placed with coverage of the first cylindrical element, moreover, a sealed zone is provided between the first cylindrical element and the second cylindrical element, while the heating element and the heat-insulating material are placed in the sealed zone. 2. Heating unit according to claim 1, in which the heating element is adjacent to the first cylindrical element, wherein the first cylindrical element is made of a metallic material. 3. Heating unit according to item 1 or 2, in which the heating element is placed on the outer peripheral side of the first cylindrical element, and between the heating element and the heat-insulating material is the first polymeric material, and the first polymeric material creates a voltage on the heating element, pressing the heating element against the first cylindrical element. 4. Heating unit according to item 3, in which the first polymeric material is subjected to heat shrinkage and thereby creates a voltage on the heating element, pressing the heating element against the first cylindrical element. 5. Heating unit according to item 3 or 4, in which the upstream end of the first polymeric material, which is adjacent to the second hole, protrudes outward from the second cylindrical element. 6. Heating unit according to item 5, moreover, the heating unit contains a third cylindrical element, including an internal space made with the possibility of inserting an aroma-generating product into it, the internal space being in communication with the first opening of the first cylindrical element, moreover, the third cylindrical element is connected to the downstream end of the first cylindrical element, which is located on the side of the first hole, moreover, the downstream end of the first polymeric material, which is adjacent to the first hole, covers the outer periphery of the upstream end of the third cylindrical element, which is connected to the first hole. 7. Heating unit according to item 6, wherein the upstream end of the third cylindrical element surrounds the outer periphery of the downstream end of the first cylindrical element. 8. Heating unit according to any one of paragraphs. 3-7, in which the first polymeric material has a length equal to the axial length of the first cylindrical element. 9. Heating unit according to any one of paragraphs. 3-8, wherein the first polymeric material is longer than the heating element in the axial direction, wherein the heating element is located between the upstream end of the first polymeric material that is adjacent to the second opening and the downstream end of the first polymeric material that is adjacent to the first opening. 10. Heating unit according to any one of paragraphs. 3-9, moreover, the heating unit contains a fourth cylindrical element connected to the upstream end of the first cylindrical element, which is located on the side of the second hole, and forms an internal channel that introduces air towards the second hole of the first cylindrical element, and the upstream end of the first polymeric material, which is adjacent to the second hole, covers the outer periphery of the fourth cylindrical element. 11. Heating unit according to item 10, moreover, the downstream end of the fourth cylindrical element, which is located near the second hole, surrounds the outer periphery of the upstream end of the first cylindrical element. 12. The heating unit according to any one of paragraphs. 1-11, moreover, the upstream end of the first cylindrical element, which is on the side of the second hole, and the downstream end of the first cylindrical element, which is on the side of the first hole, protrude outward from the second cylindrical element, wherein the heating element is inserted between the upstream end of the second cylindrical element that is adjacent to the second opening and the downstream end of the second cylindrical element that is adjacent to the first opening in the axial direction. 13. The heating unit according to any one of paragraphs. 1-12, the thermal insulation material extending axially at least between the upstream end of the heating element adjacent to the second opening and the downstream end of the heating element adjacent to the first opening. 14. Heating unit according to any one of paragraphs. 1-13, moreover, the heating unit contains an annular element extending in the circumferential direction between the end section of the first cylindrical element, which is located on the side of the first hole, and the end section of the second cylindrical element, which is adjacent to the first hole, and between the end section of the first cylindrical element, which is located on side of the second hole, and the end portion of the second cylindrical element, which is adjacent to the second hole. 15. Heating unit according to item 14, moreover, the annular element is made of a material having a lower thermal conductivity than the first cylindrical element and the second cylindrical element. 16. Heating unit according to any one of paragraphs. 1-15, moreover, the heat-insulating material includes airgel. 17. The heating unit according to any one of paragraphs. 1-16, moreover, the heating unit includes a heater shank that electrically connects the heating element to the control unit, and at least part of the heater shank extends along the outer surface of the first cylindrical element, protruding outward from the sealed area. 18. The heating unit according to any one of paragraphs. 1-17, wherein the heating element is configured to heat the aroma-generating article, wherein the ratio D0/L0 ranges from 0.7 to 0.9, where L0 is the axial length of the aroma-generating base material in the aroma-generating article, and D0 is the axial length of the heating element. 19. Heating unit according to item 18, moreover, D0/L0 varies from 0.75 to 0.85. 20. The heating unit according to any one of paragraphs. 1-19, wherein the heating element is configured to heat the aroma-generating article, wherein the ratio D1/L0 ranges from 0.25 to 0.40, where L0 is the axial length of the flavor generating article and D1 is the axial distance between the upstream end of the heating element and the upstream end of the first cylindrical element. 21. Heating unit according to item 20, wherein the D1/L0 ratio varies from 0.30 to 0.35. 22. The heating unit according to any one of paragraphs. 1-21, moreover, in a state in which the aroma-generating article is inside the first cylindrical element so that the upstream end of the aroma-generating article and the upstream end of the first cylindrical element coincide with each other in the axial direction, the downstream end of the heating element is downstream of the downstream end of the aroma-generating base material. 23. A device for inhaling aroma, containing a heating unit according to any one of paragraphs. 1-22.

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