WO2020084799A1 - Power source unit for non-combustion-type inhaler, atomization unit, and non-combustion-type inhaler - Google Patents

Abstract

The power source unit for a non-combustion-type inhaler according to one embodiment of the present invention comprises: a housing to which an atomization unit can be connected; and a pressure sensor that is housed inside the housing and detects changes in pressure inside the housing. A first surface of the housing that faces the atomization unit when the atomization unit is connected has a communication opening that allows the inside and the outside of the housing to communicate. An enclosing protrusion that protrudes from the first surface and surrounds the communication opening is formed on the first surface at a distance from the communication opening in the in-plane direction of the first surface. When the atomization unit is connected to the housing, the first surface, the atomization unit, and the enclosing protrusion form a buffer space that allows the communication opening and a flow path to communicate.

Description

Non-combustion aspirator power supply unit, atomization unit and non-combustion aspirator

The present invention relates to a power supply unit for a non-combustion type aspirator, an atomizing unit and a non-combustion type aspirator.
The present application claims priority based on Chinese Patent Application No. 201211255597.9 filed on October 26, 2018, the content of which is incorporated herein by reference.

BACKGROUND ART Conventionally, a non-combustion type aspirator (hereinafter, simply referred to as an aspirator) that tastes a flavor by sucking vapor (for example, aerosol) atomized by heating has been known. As this type of inhaler, for example, there is one that includes an atomizing unit in which an atomizable content (for example, an aerosol source) is stored and a power supply unit in which a storage battery is mounted.
In the suction device, the heating unit provided in the atomizing unit generates heat by the electric power supplied from the storage battery. Thereby, the contents in the atomization unit are atomized. The user can suck the atomized aerosol together with the air through the mouthpiece.

For example, Patent Document 1 below discloses a configuration in which an atomization unit is detachably attached to a power supply unit. In the suction device described in Patent Document 1 below, the atomizing unit and the power supply unit communicate with each other with their ports butted against each other. According to this structure, the inside of the power supply unit becomes negative pressure by sucking the suction device through the suction port. Negative pressure in the power supply unit is detected by a pressure sensor built in the power supply unit. Thus, it is considered that the user can inhale the aerosol because the heating section generates heat.

China utility model publication No. 206482021 specification

However, in the above-mentioned conventional technique, the ports of the atomizing unit and the main body unit are directly butted against each other. Therefore, for example, when the aerosol is condensed, it may enter the power supply unit through the port.

An object of the present invention is to provide a power supply unit of a non-combustion type aspirator, an atomization unit and a non-combustion type aspirator capable of protecting the power supply unit from condensed aerosol.

(1) In order to achieve the above object, a power supply unit of a non-combustion type aspirator according to an aspect of the present invention is a fog in which an aerosol source is housed and a channel through which atomized aerosol flows is formed. A housing to which the atomizing unit can be connected is provided, and in the first surface of the housing that the atomizing unit faces when the atomizing unit is connected, a communication port that communicates the inside and the outside of the housing is opened, and On one surface, at a position away from the communication opening in the in-plane direction of the first surface, a surrounding convex portion that protrudes from the first surface and surrounds the communicating opening is formed, and the surrounding convex portion is A buffer space that communicates between the communication port and the flow path is formed together with the first surface and the atomizing unit when the atomizing unit is connected to the housing.

According to this aspect, since the buffer space is easily formed between the communication port and the flow path, it is not necessary to butt the ports with each other and the convenience for the user can be improved. Thereby, for example, once atomized, the condensed aerosol can be suppressed from directly flowing into the communication port through the flow path. Thereby, the power supply unit can be protected from the condensed aerosol.

(2) In the power supply unit for a non-combustion type aspirator according to the aspect of (1), a pressure sensor that detects a pressure change in the housing is housed in the housing, and the communication port is the first The surface may be arranged at a position overlapping with the pressure sensor when viewed from the normal direction.
According to this aspect, it is possible to reduce the distance between the pressure sensor and the communication port. As a result, it is possible to easily generate a negative pressure around the pressure sensor through the communication port. As a result, the sensitivity of the pressure sensor can be improved.

(3) In the power supply unit of the non-combustion type aspirator according to the above aspect (1) or (2), the surrounding convex portion is elastically deformable and the atomizing unit is connected to the housing. Sometimes it may be close to the atomization unit.
According to this aspect, when the atomizing unit is connected to the power supply unit, the surrounding convex portion comes into close contact with the atomizing unit with the elastically deformed state. Thereby, the sealing property of the buffer space can be improved and the sensitivity of the pressure sensor can be improved.

(4) A main unit of a non-combustion type aspirator according to an aspect of the present invention is provided at an end portion on the first surface side of the power supply unit according to the above aspect and the power supply unit, and the atomization unit. And a container holding cylinder in which the atomizing unit is housed when the container is connected to the power supply unit.
According to this aspect, the atomization unit is stably held in the container holding cylinder. Thereby, the connection state between the atomization unit and the power supply unit can be stabilized.

(5) In the main unit of the non-combustion inhaler according to the aspect of (4), the aerosol generated in the atomizing unit is provided on the side opposite to the power supply unit with respect to the container holding cylinder. A suction part that sucks through the passage may be provided, and the atomization unit may be sandwiched between the suction part and the surrounding convex part.
According to this aspect, the atomizing unit can be pressed against the surrounding convex portion by the suction port portion, and the sealing property of the buffer space can be improved. Further, since the atomization unit is arranged between the power supply unit and the suction port, the flow path from the atomization unit to the suction port becomes short.

(6) In the main unit of the non-combustion type inhaler according to the aspect of (5), the suction port is provided with a storage space capable of storing a flavor source container in at least a part of the suction port. Good.
According to this aspect, the flavor can be added to the aerosol by allowing the aerosol to pass through the flavor source container when the aerosol is sucked through the suction port.

(7) A non-combustion type aspirator according to an aspect of the present invention includes the main body unit according to the above aspect, and the atomization unit detachably attached to the main body unit.
According to this aspect, since the main body unit according to the above aspect is provided, it is possible to provide a highly reliable suction device.

(8) In the non-combustion type aspirator according to the aspect of (7), the second surface of the atomizing unit that faces the first surface may be formed as a flat surface.
According to this aspect, since the buffer space is formed by the contact or the proximity of the surrounding convex portion and the flat surface, the atomization unit can be simplified.

(9) In the non-combustion type aspirator according to the aspect of (8), the opening portion in the second surface of the flow path is arranged at a position displaced in the in-plane direction with respect to the communication port. It may have been done.
According to this aspect, it is possible to secure a distance between the opening on the second surface and the communication port in the flow path, so that even if condensed aerosol enters the buffer space, the inside of the housing is communicated through the communication port. Can be suppressed from flowing into.

(10) The atomization unit of the non-combustion type aspirator according to an aspect of the present invention is configured to be connectable to a power supply unit having a housing that houses a pressure sensor, and a container body that houses an aerosol source; A flow path formed in the container body, through which atomized aerosol flows, a communication port for communicating the inside and outside of the housing is opened on the first surface of the housing, and the power source of the container body is the power source. An enclosing convex portion protruding from the second surface is formed on a second surface facing the first surface when connected to the unit, and the enclosing convex portion is formed when the container body is connected to the power supply unit. , Surrounding the communication opening at a position away from the communication opening in the in-plane direction of the first surface, and communicating the communication opening and the flow path together with the first surface and the second surface Shape buffer space To.
According to this aspect, since the buffer space is formed between the communication port and the flow path, it is possible to prevent the condensed aerosol source from directly flowing into the communication port through the flow path after being once atomized. Thereby, the power supply unit can be protected from the condensed aerosol.

According to one aspect of the present invention, the power supply unit can be protected from the condensed aerosol.

It is a perspective view of the suction device which concerns on embodiment. It is a disassembled perspective view of the suction device which concerns on embodiment. FIG. 3 is a sectional view taken along line III-III in FIG. 1. It is a disassembled perspective view of the power supply unit which concerns on embodiment. FIG. 5 is a sectional view taken along line VV of FIG. 1. It is a perspective view of the power supply unit which concerns on embodiment. It is the top view which looked at the power supply unit which concerns on embodiment from the holding unit side of an axial direction. It is an exploded perspective view of a holding unit concerning an embodiment. It is a perspective view showing the connecting structure of the 1st connecting member and the 2nd connecting member concerning an embodiment. FIG. 3 is a plan view of the holding unit and the cartridge according to the embodiment as viewed from the power supply unit side in the axial direction. FIG. 2 is a sectional view taken along line XI-XI in FIG. 1. FIG. 2 is an exploded perspective view of the mouthpiece corresponding to line XII-XII in FIG. 1. FIG. 3 is a cross-sectional view taken along the axial direction of the cartridge according to the embodiment. FIG. 3 is an exploded perspective view of the cartridge according to the embodiment. It is the perspective view which looked at the tank concerning an embodiment from the opening side. It is the perspective view which looked at the heater holder concerning an embodiment from the power supply unit side. It is the perspective view which saw the atomization container which concerns on embodiment from the mesh body side. It is a front view of the suction device which concerns on embodiment. It is sectional drawing which follows the axial direction when removing the mouthpiece from the suction device which concerns on embodiment. FIG. 6 is an explanatory diagram showing a state in which the cartridge according to the embodiment rides on the vertical engagement convex portion. FIG. 6 is an explanatory diagram showing a state in which a mouthpiece is screwed on in a mounted state of the cartridge according to the embodiment. FIG. 6 is an explanatory diagram showing a manner in which the mouthpiece and the cartridge according to the embodiment rotate together. It is explanatory drawing which shows a mode that the mouthpiece which concerns on embodiment is fully tightened. It is a partial cross section figure of the suction device which concerns on the modification of embodiment.

Next, an embodiment of the present invention will be described based on the drawings.
[Aspirator]
FIG. 1 is a perspective view of the suction device.
The inhaler 1 shown in FIG. 1 is a so-called non-combustion inhaler, and the aerosol atomized by heating is sucked through the tobacco leaf to taste the flavor of the tobacco leaf.

The aspirator 1 includes a main body unit 10, a cartridge (atomization unit) 11 and a tobacco capsule (flavor source container) 12 that are detachably attached to the main body unit 10.

<Main unit>
FIG. 2 is an exploded perspective view of the suction device 1.
As shown in FIG. 2, the main body unit 10 includes a power supply unit 21, a holding unit 22, and a mouthpiece (suction portion) 23. The power supply unit 21, the holding unit 22, and the mouthpiece 23 are each formed in a tubular shape having the axis O as a central axis, and are arranged side by side on the axis O. In the following description, the direction along the axis O is referred to as the axial direction (normal direction). In this case, in the axial direction, the side from the mouthpiece 23 toward the power supply unit 21 may be referred to as the non-suction side or the first side, and the side from the power supply unit 21 toward the mouthpiece 23 may be referred to as the suction side or the second side. it can. In addition, a direction intersecting the axis O in a plan view seen from the axial direction may be referred to as a radial direction, and a direction around the axis O may be referred to as a circumferential direction. In this specification, the “direction” means two directions, and when one of the “directions” is shown, it is described as “side”.

<Power supply unit>
FIG. 3 is a sectional view taken along the line III-III in FIG.
As shown in FIG. 3, the power supply unit 21 includes a housing 31 and a holder assembly 32 housed in the housing 31.

(Holder assembly)
FIG. 4 is an exploded perspective view of the power supply unit 21.
As shown in FIGS. 3 and 4, the holder assembly 32 is configured such that the storage battery 33, the board modules (the first board module 34 and the second board module 35), and the like are mounted on the storage battery holder 36.
The storage battery holder 36 is integrally formed of, for example, a resin material. The storage battery holder 36 includes a base portion 40. The base portion 40 is formed in a semi-cylindrical shape with the axis O as the central axis. The base portion 40 may have a shape other than the semi-cylindrical shape as long as the assembly opening 40a (see FIG. 4) that receives the storage battery 33 and the like is opened to the outside in the radial direction.

A press-fitting cylinder part 41 is connected to an end of the base part 40 on the side opposite to the holding unit 22 in the axial direction. The press-fitting cylinder portion 41 is formed in a cylindrical shape with the axis O as the central axis. A part of the press-fitting cylinder portion 41 in the circumferential direction is formed with a connector passage hole 42 that radially penetrates the press-fitting cylinder portion 41. The opening of the press-fitting cylinder portion 41, which is located on the opposite side of the holding unit 22 in the axial direction, is closed by a closing portion 43. The closing portion 43 is formed in a circular shape having a diameter larger than that of the press-fitting cylinder portion 41.

A button opening 44 (see FIG. 3) is formed in a portion of the base portion 40 located on the holding unit 22 side in the axial direction. The button opening 44 radially penetrates a part of the base portion 40 in the circumferential direction. The connector passage hole 42 and the button opening 44 described above are arranged at positions different by 180 ° in the circumferential direction, for example. In the present embodiment, the radial direction passing through the centers of the connector passage hole 42 and the button opening 44 in the circumferential direction is the front and back surface direction. In this case, the connector passage hole 42 side with respect to the axis O is the back side, and the button opening 44 side with respect to the axis O is the front side. The positions of the connector passage hole 42 and the button opening 44 can be changed as appropriate.

In the base portion 40, a button guide cylinder 45 extending toward the back surface is formed at the opening edge of the button opening 44. The button guide cylinder 45 surrounds the periphery of the button opening 44.
A partition wall 46 that partitions the base portion 40 in the axial direction is formed in a portion of the base portion 40 that is located on the opposite side of the button opening 44 from the holding unit 22 in the axial direction.

FIG. 5 is a sectional view taken along the line VV of FIG.
As shown in FIGS. 3 to 5, a step portion 47 is connected to an end portion of the base portion 40 which is located on the holding unit 22 side in the axial direction. The step portion 47 is formed in a semi-cylindrical shape arranged coaxially with the base portion 40, and is gradually reduced in distance in the radial direction from the axis O toward the holding unit 22 in the axial direction. A connection pedestal 48 is connected to an edge of the step portion 47 located axially on the holding unit 22 side. The connection pedestal 48 is formed in a circular shape with the axis O as the central axis. A pair of electrode holding portions 50 and a communication port 51 are formed on the connection pedestal 48.

As shown in FIGS. 4 and 5, the pair of electrode holding portions 50 are formed in a cylindrical shape that projects toward the holding unit 22 side in the axial direction. Each electrode holding part 50 is located on both sides in the radial direction with respect to the axis O. In the present embodiment, the electrode holding portions 50 are arranged side by side in the radial direction, which is orthogonal to the front-back surface direction described above (hereinafter, sometimes referred to as the left-right direction). The electrode holding parts 50 extend in the axial direction and are continuous with each other in the radial direction.
As shown in FIGS. 3 and 4, the communication port 51 projects axially toward the holding unit 22 side from a portion of the connection pedestal 48 located on the rear side in the radial direction with respect to the axis O.

As shown in FIG. 5, each electrode holding portion 50 holds a pin electrode 49 separately. The pin electrode 49 has a pin-shaped electrode body elastically supported in a cylindrical case. The pin electrode 49 is configured such that the electrode body penetrates the electrode holding portion 50 in the axial direction in a state where the tubular case is fitted in the electrode holding portion 50. Of the axial ends of the pin electrode 49 (electrode body), the end located on the opposite side to the holding unit 22 in the axial direction is connected to the first substrate 60, which will be described later, through the electrode wiring in the storage battery holder 36. Has been done.

The storage battery 33 is formed in a columnar shape with the axis O as the axial direction. The storage battery 33 is housed in a portion of the base portion 40, which is located on the side opposite to the holding unit 22 in the axial direction with respect to the partition wall 46. The power supply unit mounted on the suction device 1 is not limited to a secondary battery such as the storage battery 33 as a chargeable / dischargeable power supply, but may be a supercapacitor or the like. The power supply unit may be a primary battery.

As shown in FIGS. 3 and 4, the first substrate module 34 is arranged in a portion of the base portion 40, which is located on the holding unit 22 side in the axial direction with respect to the partition wall 46. Specifically, the first substrate module 34 includes a first substrate 60, a switch element 52 (see FIG. 3), and a pressure sensor 53.
The 1st board | substrate 60 is arrange | positioned by making a front-back surface direction into a thickness direction. Specifically, the first substrate 60 is mounted on the opening end surface of the assembly opening 40a and is fixed to the base portion 40 with screws or the like. The first substrate 60 is connected to the storage battery 33 via a first connection wiring (not shown). In the example shown in FIG. 3, the first substrate 60 is located on the axis O.

The switch element 52 is arranged on the front surface (first main surface) of the first substrate 60 at a position overlapping the button opening 44 when viewed from the front and back surfaces. In the present embodiment, the switch element 52 is surface-mounted on the first substrate 60. However, the switch element 52 may be mounted on the first substrate 60 in a state where the connection terminal pulled out from the switch element 52 is inserted into the through hole of the first substrate 60.

The pressure sensor 53 is arranged on the back surface (second main surface) of the first substrate 60 on the holding unit 22 side in the axial direction with respect to the switch element 52. That is, the pressure sensor 53 is arranged at a position where it does not overlap with the switch element 52 in a plan view seen from the front and back surfaces. In addition, in the present embodiment, the pressure sensor 53 is arranged at a position displaced from the switch element 52 toward the holding unit 22 side in the axial direction, but is not limited to this configuration. That is, if the switch element 52 and the pressure sensor 53 are arranged at positions displaced in the in-plane direction of the first substrate 60, even if they are arranged at positions displaced in the axial direction on the side opposite to the holding unit 22. Of course, the radial direction may be shifted in the left-right direction.

As the pressure sensor 53, for example, a capacitance type can be adopted. That is, the pressure sensor 53 detects the behavior of the diaphragm that deforms in response to pressure fluctuations as a change in capacitance. The pressure sensor 53 of the present embodiment is mounted on the first board 60 in a state where the connection terminal drawn out from the pressure sensor 53 is inserted into the through hole of the first board 60. However, the pressure sensor 53 may be surface-mounted on the first substrate 60.

A sensor holder 54 is attached to the pressure sensor 53. The sensor holder 54 is made of a resin material such as silicone resin that is softer and more elastic than the storage battery holder 36. The sensor holder 54 includes an attachment portion 55 attached to the storage battery holder 36 and a covering portion 56 that covers the pressure sensor 53.

The attachment part 55 is formed in a semicircular shape. The mounting portion 55 is assembled to the storage battery holder 36 in a state of being abutted against the above-described connection pedestal 48 from the side opposite to the holding unit 22 in the axial direction. The stepped portion 47 described above is provided with a holding piece 57 (see FIG. 4) that holds the mounting portion 55 in the axial direction with the connection pedestal 48. The sandwiching piece 57 projects in the circumferential direction from both end surfaces of an arc located outside in the radial direction (horizontal direction) of the step portion 47.

The covering part 56 is continuous from the mounting part 55 on the side opposite to the holding unit 22 in the axial direction. The covering portion 56 is formed in a cap shape having an opening on the front surface side. On the bottom wall portion 56a of the covering portion 56, a spacer 56b that bulges toward the front surface side is formed. The pressure sensor 53 is fitted in the covering portion 56 in a state of being pressed against the spacer 56b. As a result, a radial gap is provided between the inner surface of the bottom wall portion 56a and the pressure sensor 53. The bottom wall portion 56a is formed with an air replacement hole 58 that penetrates the bottom wall portion 56a in the radial direction.

The above-mentioned mounting portion 55 is formed with a communication passage 59 for communicating the inside of the communication port 51 and the inside of the covering portion 56. The communication path 59 extends in the mounting portion 55 in the axial direction. The end of the communication passage 59 on the side opposite to the holding unit 22 in the axial direction is open on the inner peripheral surface of the covering portion 56. On the other hand, the end of the communication passage 59 on the side of the holding unit 22 in the axial direction is open on the surface of the mounting portion 55 facing the side of the holding unit 22 in the axial direction. In this embodiment, the minimum inner diameter of the communication passage 59 is larger than the maximum inner diameter of the air displacement hole 58. Further, in the communication passage 59, the inner diameter of the end portion on the holding unit 22 side at least in the axial direction is larger than the inner diameter of the communication port 51.

In the present embodiment, the communication port 51 and the communication passage 59 are arranged at positions where at least a part of the communication port 51 and the communication passage 59 overlap with the pressure sensor 53 when viewed in the axial direction. However, the communication port 51 and the communication passage 59 may be arranged at positions deviated from the pressure sensor 53 when viewed in the axial direction.

As shown in FIGS. 3 to 5, the second substrate module 35 is disposed axially opposite to the first substrate module 34 with the storage battery 33 interposed therebetween. That is, the board modules 34 and 35 of the present embodiment are separately arranged on both sides in the axial direction with the storage battery 33 interposed therebetween. The second board module 35 includes a second board 61 and a female connector 62.
The second substrate 61 is accommodated in the press-fitting cylinder portion 41 described above with the radial direction (front and back direction) as the thickness direction. As shown in FIG. 5, the second substrate 61 is fixed to the boss portion 41a with a screw or the like while being placed on the boss portion 41a protruding inward in the radial direction from the press-fitting cylinder portion 41. The second substrate 61 is connected to the first substrate 60 via the second connection wiring 61a. That is, the second connection wiring 61 a is routed around the storage battery 33 in the axial direction outside the storage battery holder 36.

As shown in FIGS. 3 and 4, the female connector 62 is used to charge the storage battery 33, and a male connector (not shown) drawn from an external power source is inserted and removed. In this embodiment, the female connector 62 is, for example, a USB connector (Universal Serial Bus). However, the female connector 62 is not limited to the USB connector. Further, the female connector 62 does not necessarily have to be used for charging, but may be used for communication, for example.

The female connector 62 is mounted on the second substrate 61 with the opening facing the back side. The front end portion (end portion near the opening) of the female connector 62 is inserted into the connector passage hole 42 described above. However, the female connector 62 may be retracted from the connector passage hole 42 inward in the radial direction.

(housing)
As shown in FIGS. 3 and 4, the housing 31 has an exterior tubular portion 71, an interposition member 72, and a connection mechanism 73.
The exterior cylinder portion 71 is formed in a cylindrical shape with the axis O as the central axis. The holder assembly 32 is inserted into the exterior cylindrical portion 71 through an opening located on the side opposite to the holding unit 22 in the axial direction. Specifically, the holder assembly 32 is assembled in the exterior tubular portion 71 in a state where the press-fitting tubular portion 41 of the storage battery holder 36 is press-fitted into the end portion of the exterior tubular portion 71 that is located on the side opposite to the holding unit 22. ing. As a result, the holder assembly 32 is housed in the exterior tubular portion 71 with the end portion located on the holding unit 22 side in the axial direction protruding from the exterior tubular portion 71. The opening portion of the outer tubular portion 71 located on the opposite side of the holding unit 22 in the axial direction is closed by the closing portion 43 of the storage battery holder 36.

A connector exposure hole 75 is formed in a portion of the outer cylindrical portion 71 axially opposite to the holding unit 22 at a portion overlapping the connector passage hole 42 and the female connector 62 when viewed from the radial direction. ing. The connector exposure hole 75 penetrates the exterior tubular portion 71 in the radial direction. In the present embodiment, the configuration in which the female connector 62 opens in the radial direction has been described, but the configuration in which the female connector 62 opens in the axial direction may be used.

A button exposure hole 76 is formed in a portion of the outer tubular portion 71 on the holding unit 22 side in the axial direction, which overlaps with the button opening 44 described above when viewed from the radial direction. The button exposure hole 76 penetrates the exterior tubular portion 71 in the radial direction.

A button 78 is housed in the button exposure hole 76 and the button opening 44. The button 78 is configured to be movable in the radial direction while being supported by the button guide cylinder 45. The button 78 presses the switch element 52 as it moves inward in the radial direction. The surface of the button 78 is exposed on the outer peripheral surface of the exterior tubular portion 71 through the button exposure hole 76. The button 78 is not limited to the button that moves in the radial direction, but may be the button that slides in the axial direction, for example. Further, the suction device 1 may be operated by a touch sensor or the like instead of the button 78.

The interposition member 72 is formed in a cylindrical shape with the axis O as the central axis. The interposition member 72 is fitted between the holder assembly 32 and the exterior tubular portion 71 from the holding unit 22 side in the axial direction. As a result, the opening between the holder assembly 32 and the exterior tubular portion 71 is sealed at the opening portion of the exterior tubular portion 71 located axially on the holding unit 22 side.

As shown in FIG. 3, in the housing 31, the space surrounded by the sensor holder 54 constitutes a pressure fluctuation chamber S1 in which the pressure fluctuates through the communication port 51 described above according to the use (suction) of the suction device 1. There is. On the other hand, in the housing 31, the space other than the pressure fluctuation chamber S1 constitutes a normal pressure chamber S2 in which atmospheric pressure acts. In the present embodiment, the storage battery 33 and the substrate modules 34 and 35 are housed in the normal pressure chamber S2 except for the pressure sensor 53. However, as long as at least the pressure sensor 53 is housed in the pressure fluctuation chamber S1, components other than the pressure sensor 53 may be housed in the pressure fluctuation chamber S1. In addition, a liquid detection seal or the like may be provided in the housing 31 in order to grasp the entry of the liquid into the housing 31.

<Connecting mechanism>
As shown in FIGS. 4 and 5, the connection mechanism 73 includes a connection cap 80, a first connecting member 81, and an annular piece 82.
The connection cap 80 is made of a resin material such as silicone resin, which is softer and more elastic than the storage battery holder 36. The connection cap 80 is attached to the above-described connection pedestal 48 from the holding unit 22 side in the axial direction. The connection cap 80 has a base portion 91, a flange portion 92, and a surrounding convex portion 93.

As shown in FIG. 5, the base portion 91 is formed in a cylindrical shape with the axis O as the central axis. In the base portion 91, accommodating recesses 95 that are recessed toward the holding unit 22 in the axial direction are formed at positions where they overlap the electrode holding portions 50 in plan view. Each accommodation recess 95 extends in the axial direction and is continuous in the radial direction. An electrode insertion hole 97 is formed in the base portion 91 at a position overlapping each accommodation recess 95 in a plan view. The electrode insertion hole 97 penetrates the base portion 91 in the axial direction and communicates with the accommodation recess 95.
As shown in FIG. 3, a port insertion hole 99 is formed in the base portion 91 at a position overlapping the communication port 51 in a plan view. The port insertion hole 99 penetrates the base portion 91 in the axial direction.

As shown in FIGS. 3 and 5, in the above-described connection cap 80, the electrode holding portion 50 is housed in each housing recess 95, and the communication port 51 is inserted in the port insertion hole 99. As a result, the connection cap 80 is assembled to the storage battery holder 36 in a state of being abutted against the end surface of the connection pedestal 48 facing the holding unit 22 side in the axial direction. In this state, the pin electrode 49 projects from the base portion 91 toward the holding unit 22 side in the axial direction through the electrode insertion hole 97. The communication port 51 projects from the base portion 91 toward the holding unit 22 side in the axial direction through the port insertion hole 99. That is, the surface of the connection cap 80 (base portion 91) facing the holding unit 22 side constitutes the base surface (first surface) 91a where the pin electrode 49 projects and the communication port (communication port) 51 opens. is doing.

The flange portion 92 projects outward in the radial direction at the end of the base portion 91 on the side opposite to the holding unit 22 in the axial direction.

The surrounding convex portion 93 projects in the axial direction from the end surface of the base portion 91 that faces the holding unit 22 side in the axial direction. Specifically, the surrounding convex portion 93 is formed in an annular shape extending along the outer peripheral edge of the base portion 91. That is, the surrounding convex portion 93 collectively surrounds the pin electrode 49 and the communication port 51 at a position separated from the pin electrode 49 and the communication port 51 to the outside in the radial direction. Note that the surrounding convex portion 93 may be located radially inside the outer peripheral edge of the base portion 91 as long as it surrounds the pin electrode 49 and the communication port 51 together. Further, the surrounding convex portion 93 is not limited to a ring shape, and may be a polygonal shape or the like. In addition, in the present embodiment, the “surrounding” is not limited to the one that extends continuously, but includes the one that extends intermittently. That is, the surrounding convex portion 93 in the present embodiment can be appropriately changed as long as it surrounds the pin electrode 49 and the communication port 51 as a whole.

The surrounding convex portion 93 is formed in a triangular shape that is sharpened toward the holding unit 22 side in the axial direction in a longitudinal sectional view along the axial direction. The protruding height of the surrounding convex portion 93 from the base portion 91 is higher than that of the communication port 51 and lower than that of the pin electrode 49. However, the protruding height of the surrounding convex portion 93 may be higher than that of the pin electrode 49. Further, the shape of the vertical section of the surrounding convex portion 93 is not limited to the triangular shape.

The first connecting member 81 includes a base tubular portion 100, a vertical engaging convex portion (first vertical engaging convex portion 101a to third vertical engaging convex portion 101c), and a lateral engaging convex portion 102. There is.
The base tubular portion 100 is formed in a multi-step tubular shape in which the diameter gradually decreases from the axis O toward the holding unit 22 side in the axial direction. An end portion of the base tubular portion 100, which is located on the side opposite to the holding unit 22 in the axial direction, is fitted inside the interposition member 72. In this state, the end portion of the base tubular portion 100 on the holding unit 22 side in the axial direction surrounds the periphery of the connection cap 80 with the flange portion 92 being axially sandwiched between the end portion and the connection pedestal 48. An outer flange portion 105 that projects outward in the radial direction is formed at an end portion of the base tubular portion 100 on the side of the holding unit 22 in the axial direction.

FIG. 6 is a perspective view of the power supply unit 21.
As shown in FIGS. 5 and 6, the vertical engaging projections 101a to 101c project from the base tubular portion 100 toward the holding unit 22 side in the axial direction. A plurality of the vertical engaging convex portions 101a to 101c are formed at intervals in the circumferential direction. In the present embodiment, the vertical engaging convex portions 101a to 101c are evenly arranged at intervals of 120 ° in the circumferential direction. Note that the vertical engagement convex portions 101a to 101c may be single or plural. Further, the pitch of the vertical engaging convex portions 101a to 101c can be changed appropriately. In this case, the plurality of vertical engaging protrusions 101a to 101c may be arranged unevenly.

FIG. 7 is a plan view of the power supply unit 21 viewed from the holding unit 22 side in the axial direction.
As shown in FIG. 7, in each of the above-described vertical engagement convex portions 101a to 101c, each of the pin electrodes 49 is arranged so as not to be arranged on the virtual straight lines La to Lc connecting the center of the circumferential direction and the axis O. The vertical engaging convex portions 101a to 101c are arranged. Specifically, the pin electrode 49 is arranged at a position that is line-symmetric with respect to the virtual straight line La that connects the first vertical engaging convex portion 101a and the axis O. That is, the virtual straight line T1 and the virtual straight line La connecting the pin electrodes 49 are orthogonal to each other, and the distances from the virtual straight line La to the pin electrodes 49 are equal to each other.

As shown in FIGS. 5 and 6, the end edges of the vertical engaging projections 101a to 101c located on the axial holding unit 22 side are located on the axial holding unit 22 side of the pin electrode 49. . The vertical engaging projections 101a to 101c are formed in a rectangular shape in a side view as seen from the radial direction. At the ends of the longitudinal engagement protrusions 101a to 101c on the side of the holding unit 22 in the axial direction, the surfaces that face inward in the radial direction are inclined so that the thickness in the radial direction gradually decreases toward the holding unit 22 side in the axial direction. It is regarded as a face. This inclined surface functions as a guide for smoothly guiding the vertical engaging projections 101a to 101c to the engaging recess 210 described later of the cartridge 11.

The lateral engagement convex portion 102 projects outward in the radial direction from the outer flange portion 105. The lateral engagement convex portion 102 is formed in a rectangular shape in a plan view. A plurality of lateral engagement convex portions 102 are formed at intervals in the circumferential direction. In this embodiment, the lateral engagement protrusions 102 are evenly arranged at 90 ° intervals in the circumferential direction. In the present embodiment, the one lateral engagement convex portion 102 is arranged at the same position in the circumferential direction as the first vertical engagement convex portion 101a. In addition, the lateral engagement convex portion 102 may be single or plural. Further, the pitch of the lateral engagement convex portions 102 can be changed appropriately. In this case, the plurality of lateral engagement protrusions 102 may be arranged unevenly.

The annular piece 82 is formed in a thin annular shape. The base tubular portion 100 described above is inserted into the annular piece 82 from the holding unit 22 side in the axial direction, so that it is sandwiched in the axial direction between the interposition member 72 and the outer flange portion 105. As shown in FIG. 5, a bending portion 106 is formed in a part of the annular piece 82 in the circumferential direction. The bending portion 106 is formed in an arch shape that bulges outward in the radial direction. The bending portion 106 is configured to be elastically deformable in the radial direction. The flexure portion 106 is located radially inward of the radially outer end surface of the lateral engagement protrusion 102.

The plurality of bending portions 106 described above are formed at intervals in the circumferential direction. For example, the bending portion 106 is arranged at the same position in the circumferential direction as the pair of lateral engagement convex portions 102 that are opposed to each other in the radial direction (left-right direction) in each lateral engagement convex portion 102. However, the number of the bending portions 106 can be changed appropriately. For example, the bending portion 106 may be formed corresponding to each lateral engagement convex portion 102, or may be formed corresponding to only one lateral engagement convex portion 102.

<Holding unit>
FIG. 8 is an exploded perspective view of the holding unit 22.
As shown in FIG. 8, the holding unit 22 is detachably attached to the main body unit 10. Specifically, the holding unit 22 includes a container holding cylinder 120, a transparent cylinder 121, a second connecting member 122, and a sleeve 123.
The container holding cylinder 120 is formed in a cylindrical shape with the axis O as the central axis. An observation hole 130 is formed in a central portion of the container holding cylinder 120 in the axial direction. The observation hole 130 penetrates the container holding cylinder 120 in the radial direction. The observation hole 130 is formed in an oval shape having the axial direction as the longitudinal direction. The observation holes 130 are formed in a pair in the portions of the container holding cylinder 120 that face each other in the radial direction. The number, position, shape, etc. of the observation holes 130 can be changed as appropriate.

A vent 131 is formed in a portion of the container holding cylinder 120 that is located closer to the power supply unit 21 in the axial direction than the observation hole 130. The vent 131 penetrates the container holding cylinder 120 in the radial direction. The vent 131 communicates the inside and outside of the holding unit 22. The vent holes 131 are formed in a pair in portions of the container holding cylinder 120 that face each other in the radial direction (front and back surfaces). The number, position, shape, etc. of the vent holes 131 can be changed as appropriate.

The transparent tube 121 is made of a material having light transparency. The transparent cylinder 121 is inserted into the container holding cylinder 120. Specifically, the transparent tube 121 covers the observation hole 130 from the inside in the radial direction on the mouthpiece 23 side in the axial direction with respect to the vent 131 in the container holding tube 120. That is, the user can visually recognize the inside of the holding unit 22 through the observation hole 130 and the transmission tube 121. The holding unit 22 may have a configuration that does not have the observation hole 130 and the transmission tube 121.

The second connecting member 122 is locked to the above-described first connecting member 81 when the holding unit 22 is attached to the main body unit 10. Specifically, the second connecting member 122 includes a fitting cylinder 140, a guide cylinder 141, and a locking piece 142.

The fitting cylinder 140 is formed in a cylindrical shape with the axis O as the central axis. The fitting cylinder 140 is fitted into a portion of the container holding cylinder 120, which is located closer to the power supply unit 21 in the axial direction than the transmission cylinder 121, by press fitting or the like.

The guide cylinder 141 is arranged coaxially with the fitting cylinder 140. The guide cylinder 141 extends from the fitting cylinder 140 toward the mouthpiece 23 side in the axial direction. The guide cylinder 141 is formed in a tapered cylinder shape whose inner diameter gradually increases toward the mouthpiece 23 side in the axial direction. The outer diameter of the guide cylinder 141 is smaller than the outer diameter of the fitting cylinder 140. An escape portion 145 is formed in the guide cylinder 141 at a position where it overlaps with the above-described vent hole 131 in a side view seen from the radial direction. The escape portion 145 is formed, for example, in a U-shape that opens toward the mouthpiece 23 side in the axial direction. The ventilation hole 131 is opened in the holding unit 22 through the escape portion 145. The shape of the escape portion 145 may be any configuration as long as at least a part of the vent hole 131 is exposed inside the holding unit 22. Further, when the guide cylinder 141 and the vent 131 are arranged at different positions in the axial direction, the guide cylinder 141 may not have the escape portion 145.

FIG. 9 is a perspective view showing a connection structure of the first connecting member 81 and the second connecting member 122.
As shown in FIGS. 8 and 9, the locking piece 142 projects from the fitting cylinder 140 toward the power supply unit 21 side in the axial direction. The locking piece 142 is formed in an L shape in a side view as seen from the radial direction. Specifically, the locking piece 142 has a vertically extending portion 150 and a horizontally extending portion 151.
The vertically extending portion 150 projects from the fitting cylinder 140 toward the power supply unit 21 side in the axial direction.

As shown in FIG. 9, the laterally extending portion 151 extends in a cantilever manner from one end of the longitudinally extending portion 150 on the power supply unit 21 side in the axial direction toward one side in the circumferential direction.

FIG. 10 is a plan view of the holding unit 22 and the cartridge 11 as seen from the power supply unit 21 side in the axial direction.
As shown in FIGS. 9 and 10, in the laterally extending portion 151, an engaging recess 155 that is recessed outward in the radial direction is formed at one end portion in the circumferential direction. The engagement recess 155 is formed in a semicircular shape toward the outside in the radial direction.

The plurality of locking pieces 142 described above are formed at intervals in the circumferential direction. In this embodiment, the locking pieces 142 are evenly arranged at 90 ° intervals in the circumferential direction. An engaging groove 158 into which the above-described lateral engaging convex portion 102 is inserted is defined between the locking pieces 142 that are adjacent to each other in the circumferential direction. The engagement groove 158 is formed in an L shape in a side view.

As shown in FIGS. 2 and 9, the power supply unit 21 and the holding unit 22 are detachable by connecting the locking piece 142 and the lateral engagement convex portion 102. That is, in order to connect the power supply unit 21 and the holding unit 22, after inserting the lateral engagement convex portion 102 in the engagement groove 158 in the axial direction, the power supply unit 21 and the holding unit 22 are relatively arranged around the axis O. Rotate. Then, the lateral engagement protrusion 102 axially engages between the lateral extension 151 and the fitting cylinder 140. Further, in the process in which the power supply unit 21 and the holding unit 22 relatively rotate about the axis O, the bending portion 106 of the annular piece 82 fits into the engagement recess 155. As a result, the bending portion 106 engages with the engagement recess 155 in the circumferential direction. As a result, the power supply unit 21 and the holding unit 22 are assembled to each other in a state where they are positioned in the axial direction and the circumferential direction.

As shown in FIG. 9, in the engagement groove 158 of the present embodiment, the axial width between the fitting cylinder 140 and the laterally extending portion 151 gradually increases from the other side in the circumferential direction toward the one side. It is formed in a tapered shape that becomes narrower. Specifically, the end surface of the laterally extending portion 151 facing the mouthpiece 23 side in the axial direction is an inclined surface extending toward the power supply unit 21 side in the axial direction from the other side to the one side in the circumferential direction. .
The lateral engagement convex portion 102 is formed in a taper shape in which the width in the axial direction gradually narrows from one side in the circumferential direction toward the other side. Specifically, the end surface of the above-described lateral engagement convex portion 102 that faces the side opposite to the axial holding unit 22 extends from the one side in the circumferential direction to the other side, and extends toward the mouthpiece 23 side in the axial direction. It is regarded as a face. Thereby, when the power supply unit 21 and the holding unit 22 are connected, interference between the laterally extending portion 151 and the lateral engaging convex portion 102 can be suppressed, and the assembling property can be improved.

As shown in FIG. 8, the sleeve 123 is press-fitted into a portion of the container holding cylinder 120 that is located closer to the mouthpiece 23 in the axial direction than the transmission cylinder 121. The transparent cylinder 121 described above is axially held between the second connecting member 122 and the sleeve 123. A female screw portion 123 a is formed on the inner peripheral surface of the sleeve 123.

<Mouthpiece>
FIG. 11 is a sectional view taken along the line XI-XI of FIG. FIG. 12 is an exploded perspective view of the mouthpiece 23 corresponding to line XII-XII in FIG.
As shown in FIGS. 11 and 12, the mouthpiece 23 includes a mouthpiece body 160 and an anti-slip member (first anti-slip member 161 and second anti-slip member 162).
The mouthpiece 23 is formed with a suction port (accommodation space) 23a capable of accommodating the tobacco capsule 12. The mouthpiece body 160 is formed in a multi-stage tubular shape with the axis O as the central axis. A male screw portion 160a is formed at the end of the mouthpiece body 160 on the side of the holding unit 22 in the axial direction. The male screw portion 160a of the mouthpiece body 160 is detachably screwed to the female screw portion 123a of the sleeve 123 described above. The mouthpiece body 160 may be configured to be attached to and detached from the sleeve 123 by a method other than screwing (for example, fitting).

An abutting flange 165 is formed in a portion of the mouthpiece body 160, which is located on the side opposite to the holding unit 22 in the axial direction with respect to the male screw portion 160a. The abutting flange 165 is formed in an annular shape protruding outward in the radial direction. The abutting flange 165 is abutted in the holding unit 22 in the axial direction when the mouthpiece 23 is attached to the holding unit 22. In addition, the outer diameter of the abutting flange 165 is gradually reduced as it is separated from the holding unit 22 in the axial direction.

A partition 167 is formed at the end of the mouthpiece body 160 on the side of the holding unit 22 in the axial direction to partition the inside of the mouthpiece body 160 in the axial direction. In the partition portion 167, a through hole 168 is formed at a position overlapping with the axis O so as to penetrate the partition portion 167 in the axial direction. The through-hole 168 has, for example, an elliptical shape having one of the radial directions as the longitudinal direction. The shape of the through hole 168 in plan view may be a perfect circle, a polygon, or the like.

The first anti-slip member 161 is integrally formed of a resin material such as silicone resin. The first anti-slip member 161 includes a ring portion 169, a fitting protrusion 170, and a contact protrusion 171.

The ring portion 169 is fitted in the mouthpiece body 160 from the holding unit 22 side in the axial direction. The first anti-slip member 161 is axially positioned with respect to the mouthpiece body 160 by the ring portion 169 being axially butted against the partition portion 167.

A communication hole 169a is formed at the center of the ring portion 169. The communication hole 169a connects the inside of the holding unit 22 and the inside of the mouthpiece body 160 through the through hole 168 described above.

The fitting protrusions 170 are formed in a pair on the inner peripheral edge of the ring portion 169 at positions radially opposite to each other with the communication hole 169a interposed therebetween. The fitting protrusion 170 projects from the ring portion 169 to the side opposite to the holding unit 22 in the axial direction. The fitting protrusions 170 are fitted to both ends of the through hole 168 in the radial direction. As a result, the first anti-slip member 161 is positioned in the circumferential direction with respect to the mouthpiece body 160. Although the present embodiment describes a configuration in which the fitting protrusion 170 is fitted in the through hole 168, the fitting protrusion 170 may be fitted in a hole different from the through hole 168. Good.

The contact protrusion 171 projects from the ring portion 169 toward the holding unit 22 side in the axial direction. The contact protrusion 171 is formed in a circular shape centered on the axis O. In the present embodiment, the contact protrusion 171 is formed with two concentric circles. The first anti-slip member 161 may not have the contact protrusion 171.

The second anti-slip member 162 is integrally formed of a resin material such as silicone resin. The second anti-slip member 162 is fitted in the mouthpiece body 160 from the side opposite to the axial holding unit 22. In addition, the second anti-slip member 162 is axially positioned with respect to the mouthpiece body 160 by being abutted against the partition portion 167 described above in the axial direction.

<Tobacco capsule>
As shown in FIGS. 2 and 11, the tobacco capsule 12 is detachably mounted in the mouthpiece body 160 from the side opposite to the holding unit 22 in the axial direction. The tobacco capsule 12 includes a capsule section 180 and a filter section 181.

As shown in FIG. 11, the capsule portion 180 is formed in a bottomed cylindrical shape with the axis O as the central axis. A mesh opening penetrating the bottom wall portion 186 in the axial direction is formed in the bottom wall portion 186 of the capsule portion 180 that closes the opening portion on the holding unit 22 side in the axial direction.
The filter portion 181 is fitted in the capsule portion 180 from the side opposite to the holding unit 22 in the axial direction. Tobacco leaves are enclosed in the space defined by the capsule unit 180 and the filter unit 181.

<Cartridge>
As shown in FIG. 2, the cartridge 11 stores a liquid aerosol source and atomizes the liquid aerosol source. The cartridge 11 is housed in the transparent cylinder 121 of the holding unit 22.

FIG. 13 is a sectional view taken along the axial direction of the cartridge 11. FIG. 14 is an exploded perspective view of the cartridge 11.
As shown in FIG. 13 and FIG. 14, the cartridge 11 includes a bottomed cylindrical tank (container body) 191, a substantially disk-shaped gasket 192 housed in the tank 191, and a substantially disk-shaped mesh body 193. The heating unit 194, the atomizing container (container body) 195, and the heater holder (container body) 196 that closes the opening 191a of the tank 191 are provided.

FIG. 15 is a perspective view of the tank 191 seen from the opening 191a side.
As shown in FIGS. 13 to 15, two engagement holes 198 are formed in the peripheral wall 191b of the tank 191, slightly closer to the bottom 191c than the opening 191a. The engagement hole 198 is for fixing the heater holder 196 to the tank 191. The engagement hole 198 is formed in a rectangular shape as viewed in the radial direction so as to be long in the circumferential direction. The two engagement holes 198 are arranged opposite to each other with the axis Q of the tank 191 interposed therebetween. The axis Q coincides with the axis O of the main body unit 10 when the cartridge 11 is housed in the transparent cylinder 121. The axis line Q is an axis line that is common to each part that constitutes the cartridge 11. In the following, the axis line Q is not limited to the axis line Q of the tank 191, and will be used in the description of each part constituting the cartridge 11.

Further, on the peripheral wall 191b of the tank 191, a guide recess 198a is formed on the inner peripheral surface slightly near the opening 191a from the engagement hole 198. The guide recess 198a is also open on the opening 191a side. The guide recess 198a has a role of guiding an engagement piece 206 described later when fixing the heater holder 196 to the tank 191.

The bottom portion 191c of the tank 191 has a through hole 191d formed at the center in the radial direction and penetrating the bottom portion 191c. An annular flow passage pipe (flow passage) 197 is integrally formed on the periphery of the through hole 191d so as to project from the inner surface of the bottom portion 191c into the tank 191. The inside of the flow path pipe 197 and the through hole 191d are communicated with each other. The flow path pipe 197 serves as a flow path for the atomized aerosol. The flow path pipe 197 extends from the bottom portion 191c to a position slightly closer to the opening 191a than the approximate center of the tank 191 in the axial direction.

Between the inner peripheral surface of the peripheral wall 191b and the outer peripheral surface of the flow channel 197, a plurality of (three in the present embodiment) ribs 199 extending over the peripheral wall 191b and the flow channel 197 are integrally formed. The ribs 199 are arranged at equal intervals in the circumferential direction so as to be radial when viewed in the axial direction. Further, the rib 199 extends from the bottom portion 191c of the tank 191 to a position slightly ahead of the end (tip) of the flow path pipe 197 on the opening 191a side. The rib 199 is for supporting the flow path pipe 197.

A convex portion 201 is integrally formed on the inner peripheral surface of the peripheral wall 191b at a location where a rib 199 is formed. The convex portion 201 extends in the axial direction along the rib 199. The convex portion 201 is formed between the bottom portion 191c of the tank 191 and the end portion (tip) on the opening 191a side of the rib 199 and the tip of the flow path pipe 197. The convex portion 201 has a role of increasing the mechanical strength of the tank 191, and a role of positioning the gasket 192.

The gasket 192 is formed so that the outer diameter is almost the same as the inner diameter of the tank 191. The gasket 192 positions the mesh body 193 described later and holds the posture of the mesh body 193. That is, the gasket 192 supports the mesh body 193 described later. An insertion hole 192a into which the flow path pipe 197 can be inserted is formed at the center of the gasket 192 in the radial direction. A gasket 192 is housed in the tank 191 so that the flow path pipe 197 is inserted into the insertion hole 192a. Further, the gasket 192 is positioned in the tank 191 by contacting the one surface 192b with the end surface 201a of the convex portion 201. With the gasket 192 positioned, the outer peripheral surface of the gasket 192 is in contact with the inner peripheral surface of the tank 191. Further, the insertion hole 192a of the gasket 192 is in contact with the outer peripheral surface of the flow path pipe 197.

A plurality of openings 192c (four in this embodiment) are formed in a large part of the gasket 192 between the insertion hole 192a and the outer peripheral surface. The opening 192c is formed in an arc shape when viewed in the axial direction. The openings 192c are arranged at equal intervals in the circumferential direction. The inside of the tank 191 is communicated with both sides of the gasket 192 with the opening 192c interposed therebetween. The mesh body 193 is arranged on the other surface 192d opposite to the one surface 192b of the gasket 192.

The mesh body 193 is a porous member having a liquid absorbing property. The mesh body 193 is formed of, for example, a cotton fiber material. The mesh body 193 is also formed in substantially the same shape as the gasket 192. That is, the mesh body 193 is formed so that the outer diameter is substantially the same as the inner diameter of the tank 191. An insertion hole 193a into which the flow path pipe 197 can be inserted is formed at the center of the mesh body 193 in the radial direction. The position of the mesh body 193 is determined by inserting the flow path pipe 197 into the insertion hole 193a and overlapping the one surface 193b of the mesh body 193 with the other surface 192d of the gasket 192. The outer peripheral surface of the mesh body 193 is in contact with the inner peripheral surface of the tank 191. The insertion hole 193 a of the mesh body 193 is in contact with the outer peripheral surface of the flow path pipe 197.

The inside of the tank 191 is partitioned by the mesh body 193 into a liquid storage chamber 202 on the bottom 191c side and an opening chamber 203 on the opening 191a side. A liquid aerosol source is stored in the liquid storage chamber 202. The opening chamber 203 is a room for atomizing the aerosol source sucked up by the mesh body 193.
One surface 193 b of the mesh body 193 and the other surface 193 c on the opposite side are exposed to the opening chamber 203. A heating unit 194 is provided so as to be connected to the other surface 193c of the mesh body 193 exposed in the opening chamber 203.

The heating unit 194 is for atomizing a liquid aerosol source. The heating unit 194 is housed in the opening chamber 203. The heating unit 194 includes a wick 204 formed in a substantially U shape and a heating wire 205 that heats the wick 204. The wick 204 is a porous, liquid-absorbing, substantially cylindrical member. Such a wick 204 is curved and deformed into a substantially U shape.
More specifically, the wick 204 includes two axially extending portions 204a that extend in the axial direction and a radial extending portion 204c that connects one ends of the two axially extending portions 204a via the bent portions 204b. ,. Then, the other end of the axially extending portion 204a is connected to the mesh body 193. As a result, the aerosol source absorbed by the mesh body 193 is sucked up by the wick 204.

The heating wire 205 extends from the heating wire main body 205a, which is formed in a spiral shape so as to surround the radial extension portion 204c of the wick 204, and both ends of the heating wire main body 205a, toward the heater holder 196 side along the axial direction. And two terminal portions 205b extending out. When the wick 204 is heated by the heating wire 205, the aerosol source absorbed by the wick 204 is atomized. The tips of the two terminal portions 205b are folded back toward the mesh body 193 side. The two terminal portions 205b are connected to the heater holder 196.

FIG. 16 is a perspective view of the heater holder 196 as viewed from the power supply unit 21 side (first side in the axial direction).
As shown in FIGS. 13 and 16, the heater holder 196 is formed in a substantially bottomed cylindrical shape. The opening 196a of the heater holder 196 is directed toward the tank 191 to close the opening 191a of the tank 191.

The peripheral wall 196b of the heater holder 196 is formed so that the outer diameter is substantially the same as the outer diameter of the peripheral wall 191b of the tank 191. On the outer peripheral surface of the peripheral wall 196b, a fitting portion 196d having a reduced diameter via a step surface 196c is formed between the approximate center in the axial direction and the opening 196a. The fitting portion 196d is fitted to the inner peripheral surface of the peripheral wall 191b of the tank 191. Further, the end portion of the peripheral wall 191b of the tank 191 on the side of the opening 191a is brought into contact with the step surface 196c of the peripheral wall 196b. As a result, the heater holder 196 is axially positioned with respect to the tank 191.

Further, two engaging pieces 206 are integrally formed at positions corresponding to the two engaging holes 198 of the tank 191 at the end of the fitting portion 196d on the opening 196a side. The two engagement pieces 206 are projected toward the corresponding engagement holes 198. That is, the two engaging pieces 206 are arranged on opposite sides of the heater holder 196 with the axis Q of the heater holder 196 interposed therebetween.
The engagement piece 206 is engaged with the engagement hole 198 of the tank 191, and integrates the tank 191 and the heater holder 196. The engagement piece 206 is formed so as to be elastically deformable in the radial direction. An engaging claw 207 that can be inserted into the engaging hole 198 of the tank 191 is formed at the tip of the engaging piece 206 so as to project radially outward.

The engaging claw 207 is formed so that the cross-sectional shape of a plane along the axial direction and the radial direction is substantially triangular. That is, the engaging claw 207 is formed as an inclined surface 207a so that the surface on the distal end side inclines toward the base end side (the fitting portion 196d side) as it goes radially outward. On the other hand, the flat surface 207b on the base end side of the engaging claw 207 is orthogonal to the axial direction.

Further, on the peripheral wall 196b of the heater holder 196, a concave portion 208 that is aligned with the engaging claw 207 in the axial direction is formed on the outer peripheral surface avoiding the fitting portion 196d. The concave portion 208 is open on the radially outer side and the step surface 196c side. The recess 208 is formed with a first intake hole 209 that penetrates the peripheral wall 196b in the thickness direction. The inside and outside of the peripheral wall 196b are communicated with each other via the first intake hole 209.

Further, three engaging recesses 210 are formed on the peripheral wall 196b of the heater holder 196 on the bottom 196e side. The three engagement recesses 210 are arranged at equal intervals in the circumferential direction (at intervals of 120 ° in the circumferential direction) so as to avoid the formation position of the recesses 208. The engagement recess 210 is formed so that the outer side in the radial direction and the bottom 196e are open. On the bottom 196e side of the engaging recess 210, a tapered chamfered portion 210a is formed in which the circumferential width of the engaging recess 210 gradually increases toward the bottom 196e.
The vertical engaging projections 101a to 101c of the first connecting member 81 are inserted into the three engaging recesses 210 thus formed. As a result, the heater holder 196 (cartridge 11) and the first connecting member 81 are connected, and the heater holder 196 (cartridge 11) and the first connecting member 81 are positioned in the circumferential direction.

A substantially plate-like connection wall 211 that is erected from the inner surface along the axial direction is integrally formed on the bottom portion 196e of the heater holder 196. The connecting wall 211 extends along the radial direction passing through the axis Q of the heater holder 196, and both ends in the radial longitudinal direction are connected to the inner surface of the peripheral wall 196b. The inside of the heater holder 196 is divided into two chambers by such a connection wall 211.
Further, two slits 212 are formed in the bottom portion 196e of the heater holder 196. The two slits 212 are arranged along both sides of the connection wall 211 in the plate thickness direction.

Electrodes 213 and 214 are provided on both sides in the thickness direction of the connection wall 211. The electrodes 213 and 214 are bent and extended from the lead electrode portions 213a and 214a provided on the connection wall 211 and the lead electrode portions 213a and 214a to the outer surface of the bottom portion 196e through the corresponding slits 212 ( Planar electrodes) 213b and 214b. Then, the two terminal portions 205b of the heating wire 205 constituting the heating portion 194 are separately connected to the extraction electrode portions 213a and 214a.

The connection electrode portions 213b and 214b are formed in a substantially semicircular shape on both sides in the radial direction with an insulating portion 215 described later interposed therebetween. Specifically, the two connection electrode portions 213b and 214b are arranged such that the straight sides 213c and 214c as viewed in the axial direction are opposed to each other in the radial direction. Further, in the two connection electrode portions 213b and 214b, arc-shaped arc sides 213d and 214d as viewed in the axial direction form outer peripheral portions. The end of the connection wall 211 is interposed between the sides 213c and 214c of the two connection electrode portions 213b and 214b. The tip of the pin electrode 49 (electrode body) held by each electrode holding portion 50 is in contact with the connection electrode portions 213b and 214b while the heater holder 196 (cartridge 11) and the first connecting member 81 are connected. To be done. That is, the bottom portion 196e of the heater holder 196 functions as an electrode arrangement surface that axially faces the above-described base surface 91a when the cartridge 11 is mounted on the main body unit 10.

Here, the connection electrode portions 213b and 214b rotate the pin electrode 49 (first pin electrode 49a and second pin electrode 49b) when the power supply unit 21 and the cartridge 11 relatively rotate around the axis O (axis Q). At least formed on the locus. That is, each of the connection electrode portions 213b and 214b has a first virtual circumference C1 passing through the first pin electrode 49a about the axis O and a second virtual circumference C2 passing through the second pin electrode 49b about the axis O. It is formed in a region including both. In the present embodiment, since the pin electrodes 49a and 49b are arranged line-symmetrically, the virtual circumferences C1 and C2 are the same.

In addition, since the end portion of the connection wall 211 interposed between the sides 213c and 214c of the two connection electrode portions 213b and 214b extends along the radial direction passing through the axis Q of the heater holder 196, in other words, For example, it can be said that the connection wall 211 is provided on the virtual straight line T1 in a predetermined direction among the virtual straight lines T1 connecting the two pin electrodes 49. This predetermined orientation coincides with an imaginary straight line T2 that passes through the circumferential center of one engagement recess 210 of the three engagement recesses 210 formed in the heater holder 196 and the axis Q of the heater holder 196. . The connection wall 211 is formed such that its width in the lateral direction (circumferential direction around the axis Q) is slightly larger than the axial diameter of each pin electrode 49.

The end portion of the connection wall 211 arranged in this way functions as an insulating portion 215 that partitions the connection electrode portions 213b and 214b in the circumferential direction. By arranging the insulating portion 215 on a virtual straight line T2 passing through the circumferential center of one engagement recess 210 and the axis Q of the heater holder 196, the heater holder 196 (cartridge 11) and the first connecting member 81 are connected. In this state, the tip ends of the pin electrodes 49 are surely brought into contact with the two connection electrode portions 213b and 214b, respectively. That is, the two pin electrodes 49 do not come into contact with one of the two connection electrode portions 213b and 214b at the same time. As described above, the connection electrode portions 213b and 214b of the present embodiment include the virtual circles C1 and C2 on both sides in the radial direction with the virtual straight line T2 (insulating portion 215) interposed therebetween, and the virtual circle C1. , C2 are formed in a semicircular shape that extends radially outward (arc sides 213d and 214d) and inward (one side 213c and 214c).

Also, recesses 213e and 214e that are recessed inward in the radial direction are formed on the arc sides 213d and 214d of the two connection electrode portions 213b and 214b, respectively, at approximately the center in the circumferential direction. In the bottom portion 196e of the heater holder 196, among the portions corresponding to the recesses 213e, 214e of the connection electrode portions 213b, 214b, the second intake hole 216 penetrating in the thickness direction of the bottom portion 196e is provided at the location corresponding to one recess 213e. Are formed. The inside and outside of the bottom portion 196e are communicated with each other via the second intake hole 216.

Further, the bottom portion 196e is provided with a recess 196f having the same shape as the connection electrode portions 213b and 214b when viewed in the axial direction, at a position corresponding to the connection electrode portions 213b and 214b. The connection electrode portions 213b and 214b are housed in the recess 196f. By forming the concave portion 196f, the surfaces of the connection electrode portions 213b and 214b and the surface of the bottom portion 196e where the connection electrode portions 213b and 214b are not arranged are located on the same plane. A part of the atomization container 195 is housed so as to be fitted to the inner peripheral surface of the peripheral wall 196b of the heater holder 196.

As shown in FIG. 11, when the cartridge 11 is mounted in the holding unit 22, the outer peripheral portion of the bottom portion 196e comes into axial contact with the surrounding convex portion 93. As a result, the space surrounded by the bottom portion 196e and the connection cap 80 (the base surface 91a and the surrounding convex portion 93) forms the buffer space S3 that connects the inside of the communication port 51 and the second intake hole 216. In the example of FIG. 11, the communication port 51 and the second intake hole 216 are axially separated from each other and are arranged at positions displaced from each other in the circumferential direction. The communication port 51 and the second intake hole (opening on the second surface of the flow path) 216 may be arranged at positions displaced from each other in the radial direction.

The communication port 51 of the present embodiment communicates with the inside of the flow path pipe 197 through the buffer space S3, the second intake hole 216, and the like. The portion of the bottom portion (second surface) 196e with which the surrounding convex portion 93 abuts is formed as a flat surface orthogonal to the axial direction. The portion of the bottom portion 196e with which the surrounding convex portion 93 abuts may be a convex surface, a concave surface, an inclined surface, or the like.

In the present embodiment, the surrounding convex portion 93 is in close contact with the bottom portion 196e in an elastically deformed state when the cartridge 11 is pressed by the mouthpiece 23. However, the surrounding convex portion 93 and the bottom portion 196e do not necessarily have to be in close contact with each other and may be separated from each other. That is, if a negative pressure can be generated in the pressure fluctuation chamber S1 through the communication port 51 during suction, a minute gap may be formed between the surrounding convex portion 93 and the bottom portion 196e.

FIG. 17 is a perspective view of the atomization container 195 seen from the mesh body 193 side (the second side in the axial direction).
The atomization container 195 shown in FIGS. 13, 14, 17 and the like is formed of an elastic member, for example, a resin material such as silicone resin. The atomization container 195 is provided between the other surface 193c of the mesh body 193 and the vicinity of the bottom portion 196e of the heater holder 196 in the axial direction. That is, the atomization container 195 is formed in a substantially cylindrical shape so as to surround the periphery of the heating section 194, and is fitted in the inner peripheral surface of the peripheral wall 191b of the tank 191, and the inner peripheral wall 196b of the heater holder 196. A substantially block-shaped fitting portion 218 fitted to the peripheral surface is integrally formed.

A stepped surface 217a is formed in a large portion at the center in the radial direction at the end of the tubular portion 217 on the mesh body 193 side. By forming the step surface 217a, a ring-shaped protruding portion 219 in which the outer peripheral portion of the cylindrical portion 217 protrudes toward the mesh body 193 side is formed. The end of the protrusion 219 is brought into contact with the other surface 193c of the mesh body 193. The outer diameter of the protrusion 219 is about the same as or slightly smaller than the inner diameter of the peripheral wall 191b of the tank 191.

A storage recess 220 is formed on most of the step surface 217a so as to correspond to the shape of the heating portion 194. The storage recess 220 serves as the atomization chamber M in which the aerosol atomized by the heating unit 194 is stored. The atomization chamber M is connected to the flow path pipe 197 of the tank 191.
A seating surface 221 on which the bent portion 204b of the wick 204 forming the heating portion 194 is placed is formed in the storage recess 220. A recess 221a is formed on the inner surface in the radial direction of the seat surface 221 to avoid interference with the terminal portion 205b of the heating wire 205 that constitutes the heating portion 194.

A seal portion 222 is formed on the outer peripheral surface of the tubular portion 217 near the fitting portion 218. The seal portion 222 is formed so as to project over the entire circumference and outward in the radial direction except for a notch portion 222a described later. The seal part 222 has a role of ensuring the sealing property between the tubular part 217 and the peripheral wall 191b of the tank 191, and also has a role of suppressing the escape of the atomization container 195 from the tank 191.
The outer diameter of the seal portion 222 is slightly larger than the inner diameter of the peripheral wall 191b of the tank 191. Therefore, when the atomization container 195 is housed in the tank 191, the seal portion 222 is compressed in the radial direction. As a result, the sealing property of the seal part 222 is secured, and the friction resistance of the seal part 222 suppresses the atomization container 195 from coming off the tank 191.

Also, the seal portion 222 is formed with two cutout portions 222a. The two cutouts 222a are arranged on opposite sides of the tank 191 with the axis Q of the tank 191 interposed therebetween. The cutout portion 222a allows the outside air to communicate with a liquid pool portion 223 described below.

A liquid pool 223 is formed on the outer peripheral surface of the cylindrical portion 217 between the tip of the protruding portion 219 and the seal portion 222. In the liquid reservoir 223, when the mesh body 193 and the wick 204 are saturated, the aerosol source of the liquid stored in the liquid storage chamber 202 of the tank 191 leaks along the inner peripheral surface of the peripheral wall 191b of the tank 191. In this case, this is a part for temporarily storing the leaked aerosol source.

In the liquid pool portion 223, the gap between the outer peripheral surface of the cylindrical portion 217 and the peripheral wall 191b of the tank 191 is gradually narrowed as the entire outer peripheral surface of the cylindrical portion 217 moves from the seal portion 222 toward the tip of the protruding portion 219. It is a recess formed by forming it obliquely. In other words, the liquid pool portion 223 is a concave portion in which the gap between the outer peripheral surface of the tubular portion 217 and the peripheral wall 191b of the tank 191 gradually widens toward the opening 191a of the tank 191. Since the liquid reservoir 223 is formed in this manner, a narrow portion 279 is formed in the vicinity of the protruding portion 219 of the cylindrical portion 217, in which a minute gap is formed between the protruding portion 219 and the peripheral wall 191b of the tank 191.
Here, the end of the protruding portion 219 of the tubular portion 217 is in contact with the other surface 193c of the mesh body 193. The outer peripheral surface of the mesh body 193 is in contact with the inner peripheral surface of the tank 191. Therefore, the narrow portion 279 formed between the protruding portion 219 of the tubular portion 217 and the peripheral wall 191b of the tank 191 is covered (closed) by the outer peripheral portion of the mesh body 193.

Further, on the outer peripheral surface of the tubular portion 217, a recess 224 for receiving the engagement piece 206 is formed at a position corresponding to the engagement piece 206 on the heater holder 196 side of the seal portion 222. By inserting the engagement piece 206 into the recess 224, the atomization container 195 and the heater holder 196 are positioned in the circumferential direction. Further, the bottom surface 224a of the recess 224 in the tubular portion 217 is brought into contact with the radially inner surface of the engagement piece 206.

The fitting portion 218 of the atomization container 195 is formed in a substantially columnar shape that can be fitted to the inner peripheral surface of the peripheral wall 196b of the heater holder 196. That is, the outer diameter of the fitting portion 218 is smaller than that of the cylindrical portion 217 via the step portion 217b. A slit 225 into which the connection wall 211 of the heater holder 196 can be inserted is formed in the fitting portion 218. Further, the fitting portion 218 is provided with a heating wire slit (not shown) which is communicated with the slit 225 and into which the terminal portion 205b of the heating wire 205 can be inserted. By inserting the terminal portion 205b of the heating wire 205 into the heating wire slit, the terminal portion 205b is held in the atomization container 195. Further, the lead electrode portions 213a and 214a provided on the connection wall 211 and the terminal portion 205b of the heating wire 205 are connected.

Further, in the fitting portion 218, an air passage 226 is formed at a position corresponding to the first intake hole 209 and the second intake hole 216 of the heater holder 196. Further, the fitting portion 218 is formed with a slit 225, a ventilation passage 226, and a slit 218a that communicates the atomization chamber M (storage recess 220) of the tubular portion 217. The air passage 226 and the atomization chamber M (storage recess 220) of the atomization container 195 are connected to each other through the slit 218a. As a result, the atomization chamber M (storage recess 220) of the atomization container 195 and the first intake hole 209 and the second intake hole 216 of the heater holder 196 communicate with each other through the ventilation path 226 and the slit 218a.

<Assembly structure of the whole suction device>
FIG. 18 is a front view of the suction device 1.
As shown in FIG. 18, the main body unit 10 of the suction device 1 includes a connecting portion 300 that connects the power supply unit 21, the holding unit 22, and the mouthpiece 23 in the axial direction in which the axis O (central axis) extends. . The connection part 300 has a first rotation connection part 301 that connects the power supply unit 21 and the holding unit 22, and a second rotation connection part 302 that connects the holding unit 22 and the mouthpiece 23.

In the following description, of the circumferential directions around the axis O, in the plan view of the power supply unit 21 side viewed from the mouthpiece 23 side along the axis O, the clockwise direction around the axis O is the rotation direction M1. , The direction in which the axis O orbits counterclockwise is referred to as the rotation direction M2.

The first rotary connection unit 301 connects and disconnects the power supply unit 21 and the holding unit 22 by the relative rotation of the power supply unit 21 and the holding unit 22 around the axis O. With the power supply unit 21 as a reference, when the holding unit 22 is rotated in the rotation direction M1 with respect to the power supply unit 21, the power supply unit 21 and the holding unit 22 are connected. Further, when the holding unit 22 is rotated in the rotation direction M2 with respect to the power supply unit 21, the connection between the power supply unit 21 and the holding unit 22 is released.

The first rotary connecting portion 301 includes the rotary connecting mechanism 310 including the first connecting member 81 and the second connecting member 122 shown in FIG. 9 described above, and the annular piece 82 and the second connecting member 122 shown in FIG. 9 and FIG. 10 described above. The lock mechanism 311 is provided. Specifically, in the rotary connection mechanism 310, as shown in FIG. 9, the lateral engagement protrusion 102 provided on the first connecting member 81 of the power supply unit 21 is provided on the second connecting member 122 of the holding unit 22. After being inserted into the engaging groove 158 in the axial direction, the holding unit 22 is rotated in the rotation direction M1 (see FIG. 18) with respect to the power supply unit 21 to lock the lateral engaging convex portion 102 to the locking piece 142. Then, the power supply unit 21 and the holding unit 22 are connected.

The lock mechanism 311 restricts the rotation of the holding unit 22 in the rotation direction M2 that releases the connection by the rotary connection mechanism 310. Specifically, as shown in FIGS. 9 and 10, the lock mechanism 311 is provided on the annular piece 82 attached to the power supply unit 21, and has the bending portion 106 protruding outward in the radial direction and the holding unit 22. And a tip portion 142a provided on the second connecting member 122 and protruding inward in the radial direction relative to the bottom portion of the engaging recess 155 in the locking piece 142. The tip portion 142a of the locking piece 142 is located on the movement path of the bending portion 106 around the axis O.

At the time of connection in the rotary connection mechanism 310 (when the holding unit 22 is rotated with respect to the power supply unit 21 in the rotation direction M1), the bending portion 106 and the tip portion 142a of the locking piece 142 come into contact with each other, and the bending portion 106 is It rides over the tip portion 142a while elastically deforming inward in the radial direction. The flexible portion 106, after overcoming the distal end portion 142a, is restored and deformed outward in the radial direction and engages with the engagement recess 155. When the bending portion 106 engages with the engaging recess 155, the bending portion 106 faces and locks the tip portion 142a of the locking piece 142 in the rotation direction M1. As a result, the connection between the power supply unit 21 and the holding unit 22 cannot be released without applying a certain amount of force.

According to the first rotary connection unit 301, in order to improve manufacturing efficiency and the like, even when the power supply unit 21 and the holding unit 22 are separable as in the present embodiment, the power supply unit by the rotary connection mechanism 310 is provided. 21 and the holding unit 22 can be easily connected, and the reliability (connection strength) of the connection state between the power supply unit 21 and the holding unit 22 by the lock mechanism 311 can be improved. Further, since the lock mechanism 311 locks at the same time as the connection by the rotary connection mechanism 310, the convenience (usability) of assembly can be improved.

In the lock mechanism 311, as shown in FIG. 10, the flexible portion 106 that elastically deforms is arranged inside the locking piece 142 that is thicker and has higher rigidity than the annular piece 82. Therefore, when the power supply unit 21 and the holding unit 22 are connected, the bending portion 106 is covered and protected from the outside by the locking piece 142. Therefore, even if it is dropped or collided, the number of cases in which the flexible portion 106 is damaged is reduced. This ensures the strength against repeated use of the assembly and improves the reliability of the lock.

As shown in FIG. 9, the locking piece 142 locked by the flexible portion 106 has an engaging groove 158 with which the lateral engaging convex portion 102 of the rotary connection mechanism 310 is engaged. As described above, the locking piece 142 forms a part of the rotary connection mechanism 310 (engagement groove 158) and a part of the lock mechanism 311 (tip portion 142a (convex portion)). The reliability of the connection state (connection strength) can be improved relatively easily.

As shown in FIG. 18, the second rotation connecting portion 302 connects and disconnects the holding unit 22 and the mouthpiece 23 by the relative rotation of the holding unit 22 and the mouthpiece 23 around the axis O. When the holding unit 22 is used as a reference, when the mouthpiece 23 is rotated in the rotation direction M1 with respect to the holding unit 22, the holding unit 22 and the mouthpiece 23 are connected. Further, when the mouthpiece 23 is rotated in the rotation direction M2 with respect to the holding unit 22, the connection between the holding unit 22 and the mouthpiece 23 is released.

As shown in FIG. 11 described above, the second rotation connecting portion 302 includes the male screw portion 160a provided on the mouthpiece 23 and the female screw portion 123a provided on the holding unit 22. Specifically, the second rotation connecting portion 302 rotates the male screw portion 160a provided on the mouthpiece 23 with respect to the female screw portion 123a provided on the holding unit 22 in the rotation direction M1, so that the holding unit 22 and The mouthpiece 23 is connected. Further, the male screw portion 160a provided on the mouthpiece 23 is rotated in the rotation direction M2 with respect to the female screw portion 123a provided on the holding unit 22, thereby disconnecting the holding unit 22 and the mouthpiece 23.

As shown in FIG. 18, the rotation direction M1 is the connecting direction of the holding unit 22 to the power supply unit 21 and the connecting direction of the mouthpiece 23 to the holding unit 22. The rotation direction M2 is a disconnection direction of the holding unit 22 with respect to the power supply unit 21 and a disconnection direction of the mouthpiece 23 with respect to the holding unit 22. As described above, in the first rotary connecting portion 301 and the second rotary connecting portion 302, the rotation directions of connection and disconnection around the axis O are the same. For this reason, it is possible to give the user a unified feeling of unit assembly work and improve convenience (usability).

The frequency of disconnecting the connection between the mouthpiece 23 and the holding unit 22 is higher than the frequency of disconnecting the connection between the power supply unit 21 and the holding unit 22 due to replacement of the cartridge 11 or the like. In the present embodiment, in the first rotary connecting portion 301, the connection between the power supply unit 21 and the holding unit 22 is released by applying the first torque 301T around the axis O, and in the second rotary connecting portion 302. The connection between the holding unit 22 and the mouthpiece 23 is released by applying a second torque 302T that is smaller than the first torque 301T. This can prevent the holding unit 22 and the power supply unit 21 from being rotated together when the mouthpiece 23 is removed from the holding unit 22.

The first torque 301T is the peak value of the torque value when the holding unit 22 rotates in the rotation direction M2 with respect to the power supply unit 21, and corresponds to the radial elastic deformation of the bending portion 106 shown in FIGS. 9 and 10. Depends on the spring coefficient etc. The second torque 302T is the peak value of the torque value when the mouthpiece 23 rotates in the rotation direction M2 with respect to the holding unit 22, and the static friction force between the male screw portion 160a and the female screw portion 123a shown in FIG. Depends on. The first torque 301T may be, for example, 1.5 times or more than the second torque 302T.

Since the first rotary connecting portion 301 and the second rotary connecting portion 302 have different connection structures, it is easy to adjust the magnitude relationship between the first torque 301T and the second torque 302T. For example, when the material of the flexible portion 106 (annular piece 82) forming the lock mechanism 311 of the first rotary connection portion 301 is selected and the thickness is adjusted, the spring coefficient for elastic deformation of the flexible portion 106 in the radial direction is changed, The magnitude of the first torque 301T with respect to the second torque 302T can be easily adjusted.

FIG. 19 is a sectional view taken along the axial direction when the mouthpiece 23 is removed from the aspirator 1.
As shown in FIG. 19, in the suction device 1, by removing the mouthpiece 23 from the main body unit 10, the cartridge 11 can be attached and detached in the axial direction. The one in which the mouthpiece 23 is removed from the main body unit 10 is referred to as a cartridge housing portion 320. That is, the cartridge housing portion 320 includes the holding unit 22 and the power supply unit 21.

The cartridge housing portion 320 forms a bottomed cylindrical cartridge housing space 321. The peripheral wall of the cartridge housing portion 320 forming the cartridge housing space 321 is formed by the holding unit 22. The bottom of the cartridge housing 320 that forms the cartridge housing space 321 is formed by the power supply unit 21. That is, the peripheral wall (holding unit 22) of the cartridge housing 320 is attachable to and detachable from the bottom of the cartridge housing 320 (power supply unit 21).

At the bottom of the cartridge accommodating portion 320, the vertical engaging convex portion 101 (the vertical engaging convex portions 101a to 101c are denoted by reference numeral 101 in FIG. 19 and subsequent figures) provided on the above-described first connecting member 81 is a shaft. It stands in the direction. The vertical engaging convex portion 101 is arranged so as to be axially insertable into the engaging concave portion 210 provided in the cartridge 11. That is, the vertical engaging convex portion 101 and the engaging concave portion 210 are arranged on the same radius with the axis O as the center. The vertical engaging convex portion 101 and the engaging concave portion 210 form a first rotation restricting portion 330 that restricts relative rotation of the cartridge 11 around the axis O with respect to the cartridge housing portion 320 (cartridge housing space 321).

In the first rotation restricting portion 330, when the cartridge 11 and the cartridge accommodating portion 320 are relatively rotated about the axis O, the vertical engaging convex portion 101 provided on the same radius is inserted into the engaging concave portion 210, and the cartridge The rotation of the shaft 11 about the axis O is restricted. As a result, the cartridge 11 is positioned in the circumferential direction, and electrical connection between the connection electrode portions 213b and 214b (see FIG. 10) of the bottom portion 196e of the cartridge 11 and the pin electrode 49 of the power supply unit 21 is secured.

The first rotation restricting portion 330, together with the mouthpiece 23, includes a positioning mechanism 340 that positions the cartridge 11 with respect to the cartridge accommodating portion 320 in association with screwing of the mouthpiece 23 to the cartridge accommodating portion 320 (holding unit 22). Is forming. According to the positioning mechanism 340, the cartridge 11 can be positioned at the same time when the mouthpiece 23 is screwed into the cartridge housing portion 320. Therefore, the positioning of the removable cartridge 11 with respect to the cartridge accommodating portion 320 becomes easy, and the complexity of assembly is eliminated. Further, it is not necessary to directly turn the cartridge 11 by hand.

Specifically, the mouthpiece 23 includes the above-described first anti-slip member (cartridge contact portion) 161 that rotates the cartridge 11 around the axis O with respect to the cartridge housing portion 320. The first anti-slip member 161 is attached to the mouthpiece body 160, and comes into contact with the cartridge 11 while the mouthpiece body 160 is being connected to the holding unit 22. When the first anti-slip member 161 comes into contact with the cartridge 11, the cartridge 11 starts to rotate together with the mouthpiece 23, and when the positions of the engaging recess 210 and the longitudinal engaging protrusion 101 in the circumferential direction coincide, the cartridge 11 is released. The cartridge 11 is positioned in the circumferential direction by falling toward the bottom of the cartridge housing 320 due to gravity and inserting the vertical engaging projection 101 into the engaging recess 210.

Further, when the mouthpiece 23 is screwed in, the first anti-slip member 161 is axially compressed between the cartridge 11 supported by the power supply unit 21 (the vertical engaging convex portion 101 and the like) and the mouthpiece body 160. To be done. As shown in FIG. 11, the first anti-slip member 161 presses the cartridge 11 toward the power supply unit 21 with the mouthpiece 23 screwed to the holding unit 22. As a result, the axial positioning of the cartridge 11 is performed.

Since the first anti-skid member 161 is formed of the silicone resin as described above, it exerts a frictional force that rotates the cartridge 11 in the circumferential direction and exerts a pressing force that presses the cartridge 11 in the axial direction. Cheap. Further, as shown in FIG. 19, the first anti-skid member 161 has an abutting protrusion 171 formed on the facing surface 161 a facing the cartridge 11. By the contact projection 171, the contact of the first anti-skid member 161 with the cartridge 11 is not a plane contact, so that the contact pressure increases, and the frictional force in the circumferential direction and the pressing force in the axial direction are more easily developed.

Further, as shown in FIG. 11, the contact protrusion 171 is crushed in the axial direction, so that the space between the through hole 191d of the cartridge 11 and the communication hole 169a of the first anti-slip member 161 is hermetically sealed. The flow paths of the cartridge 11 and the mouthpiece 23 communicate with each other, and the aerosol generated in the cartridge 11 can be sucked through the mouthpiece 23. Since the contact protrusion 171 is formed in a double ring shape (see FIG. 12), it is possible to form a double seal having high airtightness.

As shown in FIG. 19, the mouthpiece 23 includes a second rotation restricting portion 350 that restricts relative rotation of the first anti-slip member 161 with respect to the mouthpiece body 160. The second rotation restricting portion 350 includes a fitting protrusion 170 (see FIG. 12) provided on the first anti-slip member 161, an elongated through hole 168 (see FIG. 12) provided on the mouthpiece body 160, Is formed by. The fitting protrusions 170 extend in a pair in the axial direction toward the mouthpiece body 160, and are fitted to both ends of the through hole 168 in the longitudinal direction.

According to the second rotation restricting section 350, even if condensed aerosol is accumulated between the mouthpiece body 160 and the first anti-slip member 161, the first anti-slip member 161 slips against the mouthpiece body 160 ( Slippage) can be prevented. Therefore, it is possible to reliably position the cartridge 11 in the circumferential direction. Further, the through hole 168 may be formed as a long hole and integrated with the suction port 23a.

[Action]
<Assembly method of suction device>
Next, a method for assembling the above-described suction device 1 will be described.
As shown in FIG. 2, when assembling the suction device 1 of this embodiment, first, the holding unit 22 is assembled to the power supply unit 21. Specifically, after inserting the lateral engagement convex portion 102 into the engagement groove 158 in the axial direction, the power supply unit 21 and the holding unit 22 are relatively rotated about the axis O. Then, the power supply unit 21 and the holding unit 22 are assembled to each other in the above-described first rotary connection portion 301 in a state where they are positioned in the axial direction and the circumferential direction. When the power supply unit 21 and the holding unit 22 are removed, the operation reverse to the above-mentioned operation is performed.

Next, the cartridge 11 is inserted into the holding unit 22. Specifically, the cartridge 11 is inserted into the holding unit 22 with the connection electrode portions 213b and 214b of the cartridge 11 facing the holding unit 22 side in the axial direction. When the longitudinal engagement protrusions 101a to 101c of the power supply unit 21 and the engagement recess 210 of the cartridge 11 are aligned in the circumferential direction, the vertical engagement protrusions 101a to 101c correspond to the engagement recesses 210. Inserted inside. The engaging recess 210 has a chamfered portion 210a, while the vertical engaging protrusions 101a to 101c have inclined surfaces formed at the tips thereof. Therefore, the vertical engaging projections 101a to 101c are smoothly inserted into the engaging recess 210. As a result, the cartridge 11 is positioned in the circumferential direction and the axial direction with respect to the power supply unit 21, and the cartridge 11 is assembled to the power supply unit 21 at the proper position.

That is, one pin electrode 49 of the pin electrodes 49 of the power supply unit 21 and one of the connection electrode portions 213b and 214b of the cartridge 11 are connected to each other. Further, the other pin electrode 49 is connected to the other connection electrode portion 213b, 214b of the connection electrode portions 213b, 214b in the cartridge 11. Through the connection electrode portions 213b and 214b (electrodes 213 and 214), the electric power of the power supply unit 21 can be applied to the heating wire 205 of the heating portion 194. Further, the bottom portion 196e of the cartridge 11 contacts the surrounding convex portion 93, so that the buffer space S3 is defined by the cartridge 11 and the connection cap 80.

Next, the mouthpiece 23 is assembled to the holding unit 22 by the above-described second rotation connecting portion 302. Specifically, the male screw portion 160a of the mouthpiece body 160 is screwed onto the female screw portion 123a of the sleeve 123. Then, the first anti-slip member 161 of the mouthpiece 23 comes into contact with the bottom portion 191c of the cartridge 11. When the mouthpiece 23 is further tightened in this state, the first anti-slip member 161 elastically deforms, and the cartridge 11 is held in the holding unit 22 while being pressed toward the power supply unit 21 side in the axial direction. To be done. The cartridge 11 is restricted from moving in the circumferential direction with respect to the power supply unit 21 by the vertical engaging projections 101a to 101c. Therefore, due to the frictional force acting between the first anti-skid member 161 and the cartridge 11, the cartridge 11 is prevented from rotating with the mouthpiece 23.

Next, the tobacco capsule 12 is inserted into the mouthpiece 23. Specifically, the tobacco capsule 12 is fitted in the mouthpiece body 160 with the mesh opening facing the mouthpiece 23.
The above completes the assembly of the suction device 1.

By the way, when the above-described cartridge 11 is inserted, depending on the circumferential direction of the cartridge 11, the circumferential positions of the vertical engaging projections 101a to 101c of the power supply unit 21 and the engaging recess 210 of the cartridge 11 may be different. It may not match. In this case, the bottom portion 196e of the cartridge 11 is in a state of riding on the vertical engagement convex portions 101a to 101c (hereinafter, simply referred to as "riding state").

FIG. 20 is an explanatory diagram showing a state in which the cartridge 11 rides on the vertical engagement convex portion 101.
As shown in FIG. 20, when the cartridge 11 is in the riding state, the movement of the cartridge 11 to the power supply unit 21 side in the axial direction with respect to the power supply unit 21 is restricted. Therefore, the pin electrode 49 and the connection electrode portions 213b and 214b are separated from each other in the axial direction, and electrical continuity between the power supply unit 21 and the cartridge 11 is not secured. Even if the pin electrode 49 and the connection electrode portions 213b and 214b contact each other in the riding state, the pin electrode 49 and the connection electrode portions 213b and 214b may not be arranged at desired circumferential positions.

FIG. 21 is an explanatory diagram showing how the mouthpiece 23 is screwed on while the cartridge 11 is in the riding state.
As shown in FIG. 21, when the mouthpiece 23 is turned while the cartridge 11 is in the riding state and screwed to the holding unit 22, as shown in FIG. 22 described later, at least before the screwing is completed, the first slip stopper The member 161 contacts the cartridge 11. Specifically, as shown in FIG. 21, the first anti-skid member 161 is not in contact with the cartridge 11 at the moment when the male screw portion 160a of the mouthpiece 23 is engaged with the female screw portion 123a of the holding unit 22, As shown in FIG. 5, the male screw portion 160a is screwed into the female screw portion 123a, and after one to two full rotations, the first anti-slip member 161 comes into contact with the cartridge 11.

FIG. 22 is an explanatory diagram showing a manner in which the mouthpiece 23 and the cartridge 11 rotate together.
As shown in FIG. 22, when the screwing operation of the mouthpiece 23 is continued in a state where the first anti-slip member 161 is in contact with the cartridge 11, the friction acting between the first anti-slip member 161 and the cartridge 11 is generated. The force causes the mouthpiece 23 and the cartridge 11 to rotate together. That is, by the screwing operation of the mouthpiece 23, the cartridge 11 rotates in the circumferential direction (tightening direction (rotation direction M1)) while being pressed against the power supply unit 21 side in the axial direction.

Thereafter, when the circumferential positions of the connection electrode portions 213b and 214b of the cartridge 11 and the vertical engaging convex portions 101a to 101c of the power supply unit 21 match, the vertical engaging convex portions 101a to 101c correspond to the corresponding engaging concave portions 210. Enter inside. That is, the movement of the cartridge 11 in the axial direction with respect to the power supply unit 21 is allowed, so that the cartridge 11 is assembled in the regular position. As a result, the pin electrode 49 and the connection electrode portions 213b and 214b come into contact (conduction) with the movement of the cartridge 11 with respect to the power supply unit 21 in the circumferential direction restricted.

FIG. 23 is an explanatory diagram showing a state where the mouthpiece 23 is tightened to the end.
As shown in FIG. 23, if the axial movement of the cartridge 11 is allowed by the positioning of the vertical engaging convex portion 101 and the engaging concave portion 210 in the circumferential direction, the mouthpiece 23 can be further screwed. When the mouthpiece 23 is tightened to the end, the connection electrode portions 213b and 214b are pressed against the pin electrode 49, and the first anti-slip member 161 is provided between the cartridge 11 supported by the power supply unit 21 and the mouthpiece body 160. The cartridge 11 is compressed in the axial direction and the cartridge 11 is positioned in the axial direction. As described above, by screwing the mouthpiece 23, the cartridge 11 is positioned in the circumferential direction and the axial direction, and the cartridge 11 and the power supply unit 21 are electrically connected. In addition, the abutment protrusion 171 of the first anti-slip member 161 is axially compressed, so that the gap between the cartridge 11 and the mouthpiece 23 is sealed.
Further, when the cartridge 11 is assembled in the regular position in this way, the surrounding convex portion 93 of the connection cap 80 is brought into contact with the cartridge 11. Therefore, a buffer space S3 (see FIG. 3) surrounded by the surrounding convex portion 93 is formed between the bottom portion 196e of the heater holder 196 of the cartridge 11 and the connection cap 80.

<Cartridge assembly method>
Next, a method for assembling the above-described cartridge 11 will be described.
First, the liquid storage chamber 202 of the tank 191 is filled with a liquid aerosol source, and then the gasket 192 and the mesh body 193 are inserted in this order from the opening 191a of the tank 191. At this time, one surface 192b of the gasket 192 is brought into contact with the end surface 201a of the convex portion 201 of the tank 191. Further, one surface 193b of the mesh body 193 is superposed on the other surface 192d of the gasket 192. As a result, the inside of the tank 191 is correctly divided into the liquid storage chamber 202 and the opening chamber 203 by the mesh body 193. Although the mesh body 193 itself is soft, the gasket 192 maintains its posture and performs positioning.

Also, in parallel with the above process, the heater 196 and the atomizing container 195 are assembled to the heater holder 196. Specifically, first, the heating unit 194 is attached to the storage recess 220 of the atomization container 195. Subsequently, the atomizing container 195 is inserted into the heater holder 196 with the fitting portion 218 side of the atomizing container 195 facing the opening 196 a of the heater holder 196. Then, the fitting portion 218 is fitted to the inner peripheral surface of the peripheral wall 196b of the heater holder 196. At this time, the connection wall 211 of the heater holder 196 and the slit 225 of the fitting portion 218 are aligned with each other, and the connection wall 211 is inserted into the slit 225.

Then, the heater holder 196 is attached to the opening 191 a of the tank 191. Specifically, the heater holder 196 is inserted into the opening 191 a of the tank 191 such that the engaging piece 206 side of the heater holder 196 faces the opening 191 a of the tank 191. At this time, the positions of the engaging hole 198 and the guide recess 198a formed in the peripheral wall 191b of the tank 191 and the engaging piece 206 of the heater holder 196 are also aligned.
When the heater holder 196 is inserted into the opening 191a of the tank 191, the inclined surface 207a formed on the engaging claw 207 of the engaging piece 206 is first brought into contact with the peripheral wall 191b of the tank 191. . Due to this inclined surface 207a, the engaging claw 207 is brought into smooth contact with the guide recess 198a of the tank 191.

After that, when the heater holder 196 is further pushed into the tank 191, the engaging claw 207 is set in the guide recess 198a. Then, the guide recess 198a presses the engagement piece 206 inward in the radial direction and elastically deforms it. At this time, the inclined surface 207a of the engagement claw 207 causes the engagement piece 206 to smoothly elastically deform inward in the radial direction. Here, since the two engagement pieces 206 are arranged opposite to each other with the axis line Q in between, the radial inward force applied to the two engagement pieces 206 is unlikely to be biased when viewed as the entire heater holder 196. Therefore, the force when elastically deforming the engagement piece 206 is balanced, and the heater holder 196 is easily inserted into the opening 191a of the tank 191. The bottom surface 224a of the recess 224 of the atomization container 195 is in contact with the inner surface of the engagement piece 206 on the radially inner side. Therefore, when the engagement piece 206 elastically deforms inward in the radial direction, the recess 224 of the atomization container 195 slightly deforms inward in the radial direction.

After that, when the heater holder 196 is further pushed in, the engagement claw 207 moves along the guide recess 198a. After that, the engaging claw 207 rides on the end of the guide recess 198a (the end of the tank 191 on the side of the engaging hole 198), and the restoring force of the engaging piece 206 and the restoring force of the recess 224 of the atomizing container 195. Thereby, the engaging claw 207 is inserted into the engaging hole 198 of the tank 191. As a result, the heater holder 196 is fixed to the tank 191, and the assembly of the cartridge 11 is completed.

Here, when the heater holder 196 is fixed to the tank 191, the circumferential wall 191 b of the tank 191 covers the radially outer surface of the engagement piece 206. Further, if one of the two engaging claws 207 is released, for example, if the tank 191 or the heater holder 196 is inclined so that the engaging claw 207 comes out of the engaging hole 198, the other engaging claw 207 is released. 207 is pressed radially outward. Therefore, once engaged, it is difficult to release the engagement hole 198 and the engagement piece 206.

<How to use the suction device>
When using the aspirator 1 described above, the user presses the button 78. At this time, for example, by pressing the button 78 a plurality of times (for example, five times), the switch element 52 outputs a start preparation signal to the control unit mounted on the first substrate module 34.

Next, the user sucks the mouthpiece 23 or the tobacco capsule 12 while holding it. Then, the air in the holding unit 22 is sucked, so that the inside of the holding unit 22 has a negative pressure. When the pressure in the holding unit 22 becomes negative, the pressure in the atomization container 195 of the cartridge 11 (in the atomization chamber M), the buffer space S3, and the air in the pressure fluctuation chamber S1 are also sucked through the communication port 51. The inside of the fluctuation chamber S1 also becomes negative pressure. Specifically, the air in the pressure fluctuation chamber S1 flows into the buffer space S3 through the communication port 51 and then flows into the heater holder 196 through the second intake hole 216. The air that has flowed into the heater holder 196 passes through the air passage 226 and the atomization container 195, passes through the flow path pipe 197, and then passes through the mouthpiece 23 to enter the mouth of the user. When the pressure sensor 53 detects that the pressure in the pressure fluctuation chamber S1 has become lower than a predetermined value, for example, it outputs a start signal to the control unit.

The control unit that receives the activation signal energizes the heating unit 194 of the cartridge 11. It should be noted that when the holding unit 22 has a negative pressure, new air is introduced into the holding unit 22 through the ventilation holes 131. Further, new air is introduced into the atomization chamber M of the cartridge 11 (opening chamber 203 of the tank 191) through the first intake hole 209 formed in the heater holder 196 of the cartridge 11 and the air passage 226 of the atomization container 195. To be done.

The heating wire 205 generates heat when the heating unit 194 is energized. Then, the liquid aerosol source impregnated in the wick 204 is heated and atomized through the mesh body 193. The atomized aerosol fills the atomization chamber M. Then, the atomized aerosol is sucked up to the mouthpiece 23 side through the flow path pipe 197 of the tank 191 together with the new air introduced into the atomization chamber M. Then, the atomized mixed gas of aerosol and air enters the mouth of the user through the tobacco capsule 12. This allows the user to enjoy the flavor of tobacco.

<Action of cartridge>
By the way, in the cartridge 11, the aerosol source of the liquid stored in the liquid storage chamber 202 of the tank 191 is absorbed by the mesh body 193 and further absorbed by the wick 204. When the mesh body 193 and the wick 204 are saturated (exceeding the liquid holding force), an aerosol source of liquid is transmitted from between the outer peripheral portion of the mesh body 193 and the inner peripheral surface of the peripheral wall 191b of the tank 191 through the inner peripheral surface. May leak to the heater holder 196 side.

Here, in the atomization container 195 located on the heater holder 196 side of the mesh body 193, a liquid pool 223 is formed on the outer peripheral surface. Therefore, the liquid aerosol source is prevented from collecting in the liquid collecting portion 223 and leaking to the heater holder 196 side.
Specifically, in this embodiment, the volume (space volume) of the liquid reservoir 223 is about 53.4 mm 3. Then, the remaining amount of the liquid in the liquid storage chamber 202 of the tank 191 is set to 1/3, and the head space volume expansion coefficient (the volume expansion coefficient of air in the remaining 2/3 of the space in the liquid storage chamber 202) is 6%. Assuming that, the liquid aerosol source of about 100 mm 3 is pushed out of the liquid storage chamber 202 due to the air expansion in the liquid storage chamber 202 of the tank 191. Among the extruded liquid aerosol sources, the aerosol source of about 20 to 30 mm3 can be held by the mesh body 193 and the wick 204. Of the aerosol source of liquid of about 100 mm 3, the remaining aerosol source of 70 to 80 mm 3 is accumulated in the liquid reservoir 223.

Here, the liquid pool portion 223 is formed such that the gap between the outer peripheral surface of the cylindrical portion 217 and the peripheral wall 191b of the tank 191 becomes gradually narrower from the seal portion 222 toward the tip of the protruding portion 219. That is, in the vicinity of the protruding portion 219 of the tubular portion 217, the narrow portion 279 is formed in which the gap between the protruding portion 219 and the peripheral wall 191b of the tank 191 is narrowed. Therefore, among the aerosol sources of the liquid pushed out from the liquid storage chamber 202 of the tank 191, the remaining aerosol sources after the mesh body 193 and the wick 204 are saturated are easily sucked up by the narrow portion 279, and the narrower area is positively reduced. It flows through the portion 279 to the liquid pool portion 223.

That is, the liquid aerosol source stored in the liquid storage chamber 202 of the tank 191 is first absorbed by the mesh body 193 and then absorbed by the wick 204. After the mesh body 193 and the wick 204 are saturated, the liquid aerosol source is sucked up by the narrow portion 279 and accumulated in the liquid reservoir 223.

On the other hand, when the saturated state of the mesh body 193 is eliminated, the aerosol source of the liquid stored in the liquid reservoir 223 is sucked up through the narrow portion 279 (between the protruding portion 219 and the peripheral wall 191b of the tank 191). Then, the aerosol source of this liquid is absorbed by the mesh body 193. That is, the liquid aerosol source stored in the liquid reservoir 223 is returned to the liquid storage chamber 202 of the tank 191 through the narrow portion 279. At this time, since the narrow portion 279 is covered (closed) by the outer peripheral portion of the mesh body 193, the capillary force of the mesh body 193 also acts and liquid is efficiently stored in the liquid storage chamber 202 of the tank 191. The aerosol source is refluxed.

Further, since the seal portion 222 of the tubular portion 217 is formed with the two cutout portions 222a, the liquid pool portion 223 and the outside air are separated from each other by the cutout portion 222a of the seal portion 222 and the engagement hole of the tank 191. 198 and the engagement piece 206 (engagement claw 207) of the heater holder 196 are communicated with each other through a gap. As another example, the liquid pool portion 223 and the outside air may be communicated with each other through the notch portion 222a of the seal portion 222 and the first intake hole 209 of the heater holder 196. Therefore, a pressure difference does not occur between the inside and the outside of the liquid reservoir 223. As a result, the liquid aerosol source is more efficiently recirculated to the liquid storage chamber 202 of the tank 191 while preventing the liquid aerosol source from unintentionally flowing out from the liquid reservoir 223.

[effect]
As described above, in the power supply unit 21 of the present embodiment, the surrounding convex portion 93 surrounding the communication port 51 is formed on the base surface 91a at a position away from the communication port 51, and the cartridge 11 is connected to the power supply unit 21. At some time, the buffer space S3 for communicating the communication port 51 and the second intake hole 216 is formed.
According to this configuration, since the buffer space S3 is easily formed between the communication port 51 and the second intake hole 216, the trouble of butting the ports with each other is eliminated and the convenience for the user can be improved. Thereby, for example, it is possible to suppress the aerosol, which is once atomized and then condensed, from directly flowing into the communication port 51 through the second intake hole 216. Thereby, the power supply unit 21 can be protected from the condensed aerosol.

Moreover, in the present embodiment, the communication port 51 and the second intake hole 216 communicate with each other through the buffer space S3. This facilitates dimensional control when the power supply unit 21 (pressure fluctuation chamber S1) and the inside of the cartridge 11 are made to communicate with each other, as compared with a conventional configuration in which ports are butted against each other.
Further, in the present embodiment, since the communication port 51 and the second intake hole 216 need only communicate with each other through the buffer space S3, the layout property of the communication port 51 and the second intake hole 216 can be improved.

In the power supply unit 21 of the present embodiment, the communication port 51 is arranged at a position overlapping the pressure sensor 53 when viewed in the axial direction.
With this configuration, the positions of the pressure sensor 53 and the communication port 51 in the radial direction and the circumferential direction can be close to each other. Thereby, it is possible to easily generate a negative pressure around the pressure sensor 53 through the communication port 51. As a result, the sensitivity of the pressure sensor 53 can be improved.

In the power supply unit 21 of the present embodiment, the surrounding convex portion 93 is elastically deformable.
According to this configuration, when the cartridge 11 is connected to the power supply unit 21, the surrounding convex portion 93 comes into close contact with the bottom portion 196e while being elastically deformed. Thereby, the sealing property of the buffer space S3 can be improved and the sensitivity of the pressure sensor 53 can be improved.

The main body unit 10 of the present embodiment is configured to include the holding unit 22 that is axially continuous with the power supply unit 21 and that accommodates the cartridge 11 when the cartridge 11 is connected to the power supply unit 21.
According to this structure, the cartridge 11 is stably held in the holding unit 22. Thereby, the connection state between the cartridge 11 and the power supply unit 21 can be stabilized.

In the main body unit 10 of the present embodiment, the mouthpiece 23 is provided on the side opposite to the power supply unit 21 with respect to the holding unit 22, and the cartridge 11 is sandwiched between the mouthpiece 23 and the surrounding convex portion 93. did.
With this configuration, the cartridge 11 can be pressed against the surrounding convex portion 93 by the mouthpiece 23, and the sealing property of the buffer space S3 can be improved. Further, since the cartridge 11 is arranged between the power supply unit 21 and the mouthpiece 23, the flow path from the cartridge 11 to the mouthpiece 23 becomes short.

In the main body unit 10 of the present embodiment, the mouthpiece 23 is provided with the suction port 23a capable of accommodating the tobacco capsule 12.
According to this configuration, when the aerosol is sucked through the mouthpiece 23, the aerosol passes through the tobacco capsule 12 so that a flavor can be added to the aerosol.

Since the aspirator 1 of the present embodiment includes the above-described main body unit 10, the aspirator 1 having excellent reliability can be provided.

In the suction device 1 of this embodiment, the bottom 196e of the cartridge 11 has a flat surface on which the surrounding convex portion 93 abuts.
According to this structure, the buffer space S3 is sealed by the contact between the surrounding convex portion 93 and the flat surface, so that the cartridge 11 can be simplified.

In the suction device 1 of the present embodiment, the communication port 51 and the second intake hole 216 are arranged at positions displaced from each other in the radial direction.
According to this configuration, the distance between the communication port 51 and the second intake hole 216 can be secured, so that even if condensed aerosol enters the buffer space S3, it can be suppressed from flowing into the communication port 51.

(Modification)
Next, a modified example of the above-described embodiment will be described. FIG. 24 is a partial cross-sectional view of the suction device 1 according to the modification. The present modified example is different from the above-described embodiment in that the surrounding convex portion 500 is formed in the cartridge 11. In the description below, configurations corresponding to those of the above-described embodiment may be assigned the same reference numerals and may not be described.
As shown in FIG. 24, in the suction device 1 of the present modification, the surrounding convex portion 500 is formed on the bottom portion 196e of the cartridge 11. The surrounding convex portion 500 projects from the bottom portion 196e toward the power supply unit 21 side in the axial direction. The surrounding convex portion 500 is formed in an annular shape extending along the outer peripheral portion of the bottom portion 196e in a plan view seen from the axial direction.

When the cartridge 11 is mounted in the holding unit 22, the outer peripheral portion of the base surface 91a of the connection cap 80 axially approaches or abuts the above-described surrounding convex portion 500. As a result, the space surrounded by the bottom portion 196e and the connection cap 80 (the base surface 91a and the surrounding convex portion 500) forms a buffer space S3 that connects the inside of the communication port 51 and the second intake hole 216. The portion of the base surface 91a with which the surrounding convex portion 500 abuts is formed as a flat surface orthogonal to the axial direction. The portion of the base surface 91a with which the surrounding convex portion 500 abuts may be a convex surface, a concave surface, an inclined surface, or the like.

Also in this modification, it is possible to achieve the same effects as the above-described embodiment.

(Other modifications)
Although the preferred embodiments of the present invention have been described above, the present invention is not limited to these embodiments. Additions, omissions, substitutions, and other changes can be made to the configuration without departing from the spirit of the present invention. The present invention is not limited by the above description, but only by the appended claims.
For example, in the above-described embodiment, the suction device 1 in which the tobacco capsule 12 is detachably configured is described as an example of the aerosol generation device that generates the aerosol without combustion, but only this configuration is described. Not limited. As another example of the aerosol generation device, a configuration without the tobacco capsule 12 such as an electronic cigarette may be adopted. In this case, the aerosol source containing the flavor is contained in the cartridge 11, and the aerosol containing the flavor is generated by the aerosol generating device.
In the above-described embodiment, the case where the main body unit 10 has the divided configuration of the power supply unit 21, the holding unit 22, and the mouthpiece 23 has been described, but the configuration is not limited to this configuration. For example, the power supply unit 21 and the holding unit 22 may be integrally formed, or the holding unit 22 and the mouthpiece 23 may be integrally formed.
In the above-described embodiment, the configuration in which the holding unit 22 is formed in a cylindrical shape surrounding the periphery of the cartridge 11 has been described, but the configuration is not limited to this. The holding unit 22 may have a configuration capable of holding the cartridge 11. In the present specification, attachment / detachment of the cartridge 11 and the main body unit 10 (power supply unit 21) is not limited to one in which the cartridge 11 is housed in the holding unit 22 and held by the mouthpiece 23, but is simply the pin electrode 49. And the connection electrode portions 213b and 214b connect and release the connection.

In the above-described embodiment, the configuration in which the power supply unit 21 and the holding unit 22 are formed in a cylindrical shape coaxially arranged has been described, but the configuration is not limited to this. The power supply unit 21 and the holding unit 22 may have different shapes.
In the above-described embodiment, the configuration in which the storage battery 33 and the substrate modules 34 and 35 are mounted on the storage battery holder 36 has been described, but the configuration is not limited to this. The storage battery 33 and the substrate modules 34 and 35 may be directly mounted in the housing 31.
In the above-described embodiment, the configuration in which the button 78 (switch element 52) for outputting the activation preparation signal is mounted has been described, but the configuration without the button 78 (configuration activated by detection by the pressure sensor 53) is used. It may be.

In the above-described embodiment, the configuration in which the pin electrode 49 is arranged at a position symmetrical with respect to the virtual straight line La has been described, but the configuration is not limited to this. In other words, the pin electrode 49 extends along the in-plane direction (tangential direction) of the base surface 91a, and if the virtual straight line T1 connecting the two pin electrodes 49 passes through the axis O, the radial direction from the axis O will be described. May have different distances. In this case, the connection electrode portions 213b and 214b have a first virtual circumference C1 passing through the first pin electrode 49a about the axis O and a second virtual circumference C2 passing through the second pin electrode 49b about the axis O. It suffices that they are arranged at least in an arc shape in a region including both. Therefore, each pin electrode 49 is not limited to a semi-circular shape, but may be a rectangular shape or an oval shape. Further, each pin electrode 49 may have a different shape.

In the above-described embodiment, the configuration in which the axis O passes through the center of the base surface 91a has been described, but the configuration is not limited to this. The axis O may be displaced from the center of the base surface 91a. Further, in the above-described embodiment, the configuration in which the entire power supply unit 21 and the cartridge 11 are coaxially arranged has been described, but the configuration is not limited to this configuration. If the first electrode arrangement surface and the second electrode arrangement surface are arranged to face each other, for example, the axes of the storage battery 33 of the power supply unit 21 and the cartridge 11 may be arranged parallel to each other.

In the above-described embodiment, the configuration in which the first substrate 60 is arranged with the thickness direction aligned with the radial direction has been described, but the configuration is not limited to this configuration. The 1st board | substrate 60 may be arrange | positioned in the state which matched the thickness direction with the axial direction, for example.
In the above-described embodiment, the pressure sensor 53 is described as an example of the sensor mounted on the first substrate 60, but various sensors other than the pressure sensor 53 may be mounted. In the above-described embodiment, the configuration in which the negative pressure generated in the housing 31 through the communication port 51 is detected by the pressure sensor 53 has been described, but the configuration is not limited to this. The housing 31 may communicate with the inside and outside through the communication port 51.
In the above-described embodiment, the configuration in which the inside of the housing 31 is partitioned into the pressure fluctuation chamber S1 and the normal pressure chamber S2 has been described, but the housing 31 may not be partitioned into the pressure fluctuation chamber S1 and the normal pressure chamber S2.

The whole or part of the exemplary embodiments described above can be described as, but not limited to, the following supplementary notes.

(Appendix 1)
A cylindrical housing,
A pressure sensor that is housed in the housing and that detects a pressure change in the housing;
A communication port that communicates the inside and the outside of the housing is opened on the first surface of the housing that faces the axial direction,
In the first surface, a non-combustion type in which a surrounding convex portion that projects from the first surface and surrounds the communication opening is formed at a position away from the communication opening in the in-plane direction of the first surface. Suction unit power supply unit.

(Appendix 2)
A cylindrical housing that accommodates the aerosol source and is configured so that the atomization unit in which the flow path through which the atomized aerosol flows is formed is connectable in the axial direction,
A pressure sensor that is housed in the housing and that detects a pressure change in the housing;
In the first surface of the housing, which is opposed to the atomizing unit when the atomizing unit is connected, a communication port that communicates the inside and the outside of the housing is opened,
An outer peripheral portion of the first surface is formed with a surrounding convex portion projecting from the first surface and surrounding the communication port,
The surrounding convex portion forms a non-combustion suction that forms a buffer space that communicates between the communication port and the flow path together with the first surface and the atomization unit when the atomization unit is connected to the housing. Power supply unit.

Other than that, it is possible to appropriately replace the constituent elements in the above-described embodiments with known constituent elements within the scope of the present invention, and it is also possible to appropriately combine the above-described modifications.

According to the power unit of the non-combustion type aspirator, the power unit can be protected from the condensed aerosol.

Claims (10)

1. An aerosol source is housed, and a housing is provided to which an atomization unit having a flow path through which atomized aerosol flows is connectable,
   In the first surface of the housing, which is opposed to the atomizing unit when the atomizing unit is connected, a communication port that communicates the inside and the outside of the housing is opened,
   On the first surface, at a position away from the communication opening in the in-plane direction of the first surface, a surrounding convex portion that protrudes from the first surface and surrounds the communication opening is formed,
   The surrounding convex portion forms a non-combustion suction that forms a buffer space that communicates between the communication port and the flow path together with the first surface and the atomization unit when the atomization unit is connected to the housing. Power supply unit.
2. A pressure sensor for detecting a pressure change in the housing is housed in the housing,
   The power supply unit of the non-combustion type aspirator according to claim 1, wherein the communication port is arranged at a position overlapping the pressure sensor when the first surface is viewed in a normal direction.
3. The power supply for the non-combustion inhaler according to claim 1 or 2, wherein the surrounding convex portion is formed so as to be elastically deformable, and closely contacts the atomizing unit when the atomizing unit is connected to the housing. unit.
4. A power supply unit according to any one of claims 1 to 3,
   A container holding cylinder that is provided at an end of the power supply unit on the first surface side and that stores the atomization unit when the atomization unit is connected to the power supply unit. Main unit of combustion type suction device.
5. On the side opposite to the power supply unit with respect to the container holding cylinder, a suction portion that sucks the aerosol generated in the atomization unit through the flow path is provided,
   The main unit of the non-combustion type aspirator according to claim 4, wherein the atomizing unit is configured to be sandwiched between the suction port portion and the surrounding convex portion.
6. The main unit of the non-combustion type inhaler according to claim 5, wherein the suction port is provided with a storage space capable of storing a flavor source container in at least a part of the suction port.
7. A main body unit according to any one of claims 4 to 6,
   A non-combustion type aspirator comprising: the atomization unit detachably attached to the main body unit.
8. The non-combustion aspirator according to claim 7, wherein a second surface of the atomizing unit, which is opposed to the first surface, is formed into a flat surface.
9. The non-combustion type aspirator according to claim 8, wherein the opening in the second surface of the flow path is arranged at a position displaced in the in-plane direction with respect to the communication port.
10. A container body configured to be connectable to a power supply unit having a housing in which a pressure sensor is housed, in which an aerosol source is housed,
    A flow path formed in the container body, through which atomized aerosol flows,
    A communication port that communicates the inside and the outside of the housing is opened on the first surface of the housing,
    In the container body, on the second surface facing the first surface when connected to the power supply unit, a surrounding convex portion protruding from the second surface is formed,
    The surrounding convex portion surrounds the periphery of the communication port at a position apart from the communication port in the in-plane direction of the first surface when the container body is connected to the power supply unit, and the first surface and the The atomization unit of the non-combustion type suction device which forms the buffer space which connects the said 2nd surface and the said communication port and the said flow path.

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