TECHNICAL FIELD
[0001] The present invention relates to a flavor inhaler and a method for manufacturing
a flavor inhaler.
BACKGROUND ART
[0002] Conventionally, flavor inhalers for inhaling flavors or the like without burning
materials are known. As such a flavor inhaler, there is a flavor inhaler including
an accommodating portion that accommodates a flavor generating article and a heating
portion that heats the flavor generating article accommodated in the accommodating
portion and adapted to secure air tightness by using an O-ring, for example (see PTL
1, for example).
CITATION LIST
PATENT LITERATURE
SUMMARY OF INVENTION
TECHNICAL PROBLEM
[0004] In the flavor inhaler described in PTL 1, the O-ring is disposed in the vicinity
of the accommodating portion. Therefore, there is a concern that the O-ring is degraded
due to long-term exposure to a heat from the heating portion and an aerosol generated
in the accommodating portion. As a result, there is a concern that the aerosol generated
in the accommodating portion leaks to the inside of a casing of the flavor inhaler.
[0005] The present invention was made in order to solve at least a part of the problem as
described above, and an object thereof is to obtain a flavor inhaler and a method
for manufacturing a flavor inhaler capable of preventing an aerosol generated in an
accommodating portion from leaking to the inside of a casing of the flavor inhaler.
SOLUTION TO PROBLEM
[0006] According to a first aspect of the present invention, a flavor inhaler is provided.
The flavor inhaler includes: a tubular accommodating portion that has an opening formed
at one end by an opening edge portion and accommodates at least a part of a flavor
generating article via the opening; an abutting portion that abuts the opening edge
portion over an entire circumference of the opening; and a sealing portion that seals
a part between the accommodating portion and the abutting portion at a position separated
from the accommodating portion.
[0007] According to the first aspect of the present invention, heat from the accommodating
portion is unlikely to be transmitted to the sealed part and degradation of the sealed
part is prevented by the sealing portion sealing the part between the accommodating
portion and the abutting portion at the position separated from the accommodating
portion, and it is thus possible to prevent an aerosol generated in the accommodating
portion from leaking to the inside of a casing of the flavor inhaler.
[0008] In a second aspect of the present invention, the sealing portion includes an annular
first member that is provided over an entire circumference of an outer circumferential
surface of the accommodating portion and supports the accommodating portion and a
second member that comes into contact with the abutting portion over an entire circumference
of the abutting portion, is engaged with the first member over an entire circumference
of the first member, and is configured of an elastic material, a seal portion is formed
at a contact location between the first member and the second member, and the seal
portion is formed on a side closer to an axis of the accommodating portion in a radial
direction of the accommodating portion than an outer edge of the first member, in
the first aspect.
[0009] According to the second aspect of the present invention, the seal portion is formed
on the side closer to the axis of the accommodating portion in the radial direction
of the accommodating portion than the outer edge of the first member at the contact
location between the first member and the second member, and it is thus possible to
reduce the size of the flavor inhaler as compared with a case where the seal portion
is formed at the outer edge of the first member. Also, the second member is configured
of an elastic material, and it is thus possible to improve a sealing property of the
seal portion.
[0010] In a third aspect of the present invention, the seal portion includes a seal surface
that extends along an axial direction of the accommodating portion in the second aspect.
[0011] According to the third aspect of the present invention, it is possible to widen the
area where the first member and the second member come into contact with each other
by the first member and the second member coming into surface contact with each other
to form the seal surface, and it is thus possible to further prevent an aerosol generated
in the accommodating portion from leaking to the inside of the casing of the flavor
inhaler.
[0012] In a fourth aspect of the present invention, the first member and the second member
are disposed to be aligned along the axial direction of the accommodating portion,
the first member includes a projecting portion that projects toward the second member
along the axial direction of the accommodating portion, the second member includes
a recessed portion that is provided to face the projecting portion, and the seal surface
is formed at a contact location between a surface of the projecting portion on an
inner side in the axial direction of the accommodating portion and a surface of the
recessed portion on an outer side in the axial direction of the accommodating portion,
in the third aspect.
[0013] According to the fourth aspect of the present invention, the surface of the projecting
portion and the surface of the recessed portion come into contact with each other
and forms the seal surface at the contact location between the projecting portion
and the recessed portion, and it is thus possible to improve a sealing property of
the seal surface and to further prevent an aerosol generated in the accommodating
portion from leaking to the inside of the casing of the flavor inhaler. Also, it is
possible to extend the leakage path length of the aerosol by the projecting portion
and the recessed portion forming the seal surface and thereby to further prevent the
aerosol generated in the accommodating portion from leaking to the inside of the casing
of the flavor inhaler.
[0014] In a fifth aspect of the present invention, the first member and the second member
are disposed to be aligned along the axial direction of the accommodating portion,
the first member includes a first projecting portion that projects toward the second
member along the axial direction of the accommodating portion, the second member includes
a second projecting portion that projects toward the first member along the axial
direction of the accommodating portion, and the seal surface is formed at a contact
location between a surface of the first projecting portion on an inner side in the
axial direction of the accommodating portion and a surface of the second projecting
portion on an outer side in the axial direction of the accommodating portion, in the
third aspect.
[0015] According to the fifth aspect of the present invention, the surface of the first
projecting portion and the surface of the second projecting portion come into contact
with each other and form the seal surface at the contact location between the first
projecting portion and the second projecting portion, and it is thus possible to improve
a sealing property of the seal surface and to further prevent an aerosol generated
in the accommodating portion from leaking to the inside of the casing of the flavor
inhaler.
[0016] In a sixth aspect of the present invention, the first member and the second member
are mutually slidable on the seal surface in any of the third to fifth aspects.
[0017] According to the sixth aspect of the present invention, a stress does not occur at
the first member that supports the accommodating portion by the first member and the
second member mutually sliding on the seal surface even in a case where a force in
the axial direction is applied to the accommodating portion, and it is thus possible
to prevent sealing breakage from occurring between the first member and the second
member.
[0018] In a seventh aspect of the present invention, the second member includes a pressurized
portion that is pressurized by the abutting portion in any of the second to sixth
aspects.
[0019] According to the seventh aspect of the present invention, a seal is formed between
the abutting portion and the second member by the pressurized portion being pressurized
by the abutting portion, and it is thus possible to prevent an aerosol generated in
the accommodating portion from leaking to the inside of the casing of the flavor inhaler.
[0020] In an eighth aspect of the present invention, the second member is biased toward
the first member by the pressurized portion being pressurized by the abutting portion
in the seventh aspect.
[0021] According to the eighth aspect of the present invention, the second member is biased
toward the first member by the pressurized portion being pressurized by the abutting
portion, and it is thus possible to improve a sealing property of the sealing surface.
[0022] In a ninth aspect of the present invention, the second member includes a positioning
portion that is engaged with at least one of a casing of the flavor inhaler and a
fixed portion that is fixed to the casing of the flavor inhaler in any of the second
to eighth aspects.
[0023] According to the ninth aspect of the present invention, the second member is held
by the casing of the flavor inhaler or by the fixed portion that is fixed to the casing
of the flavor inhaler by the positioning portion, and it is thus possible to prevent
positional deviation of the accommodating portion in the casing.
[0024] In a tenth aspect of the present invention, the second member includes a holding
portion that holds a state detecting portion that detects a state of the abutting
portion in any of the second to ninth aspects.
[0025] According to the tenth aspect of the present invention, it is possible to detect
the state of the abutting portion by using the state detecting portion and thereby
to detect a puffing operation on the basis of a change in temperature of the abutting
portion by using a thermistor as the state detecting portion, for example.
[0026] According to an eleventh aspect of the present invention, a flavor inhaler is provided.
The flavor inhaler includes: a tubular accommodating portion that has an opening formed
at one end by an opening edge portion and accommodates at least a part of a flavor
generating article via the opening; a tubular abutting portion that abuts the opening
edge portion over an entire circumference of the opening; and a sealing portion that
seals a part between the accommodating portion and the abutting portion at a position
separated from the accommodating portion, the sealing portion including a pressurized
portion that projects from the sealing portion, is pressurized by the abutting portion,
has an annular shape, and is configured of an elastic member, and a projecting length
of the pressurized portion being longer than a thickness of the pressurized portion
that perpendicularly intersects the projecting direction in a state before the pressurization.
[0027] According to the eleventh aspect of the present invention, heat from the accommodating
portion is unlikely to be transmitted to the sealed part and degradation of the sealed
part is prevented by the sealing portion sealing the part between the accommodating
portion and the abutting portion at the position separated from the accommodating
portion, and it is thus possible to prevent an aerosol generated in the accommodating
portion from leaking to the inside of a casing of the flavor inhaler. Also, the projecting
length of the pressurized portion is longer than the thickness of the pressurized
portion in a state before the pressurization, and it is thus possible to form a seal
between the abutting portion and the pressurized portion while reducing a resistance
at the time of the insertion of the abutting portion.
[0028] According to a twelfth aspect of the present invention, a method for manufacturing
a flavor inhaler is provided. The method is a method for manufacturing a flavor inhaler
including a tubular accommodating portion that has an opening formed at one end by
an opening edge portion and accommodates at least a part of a flavor generating article
via the opening, a tubular abutting portion that abuts the opening edge portion, and
a sealing portion that seals a part between the accommodating portion and the abutting
portion at a position separated from the accommodating portion, in which the sealing
portion includes a pressurized portion that is pressurized by the abutting portion,
has an annular shape, and is configured of an elastic member, the method including:
disposing the accommodating portion inside the sealing portion, disposing the sealing
portion inside a casing of the flavor inhaler, inserting the abutting portion into
the sealing portion such that the abutting portion abuts the opening edge portion;
and pressurizing the pressurized portion in an insertion direction of the abutting
portion by inserting the abutting portion into the sealing portion and forming a seal
portion by biasing the pressurized portion toward an outer side in a radial direction
of the accommodating portion.
[0029] According to the twelfth aspect of the present invention, heat from the accommodating
portion is unlikely to be transmitted to the sealed part and degradation of the sealed
part is prevented by the sealing portion sealing the part between the accommodating
portion and the abutting portion at the position separated from the accommodating
portion, and it is thus possible to obtain a flavor inhaler capable of preventing
an aerosol generated in the accommodating portion from leaking to the inside of a
casing of the flavor inhaler.
BRIEF DESCRIPTION OF DRAWINGS
[0030]
Fig. 1A is a schematic front view of a flavor inhaler according to an embodiment.
Fig. 1B is a schematic top view of the flavor inhaler according to the embodiment.
Fig. 1C is a schematic bottom view of the flavor inhaler according to the embodiment.
Fig. 2 is a schematic side sectional view of a flavor generating article.
Fig. 3 is a sectional view of the flavor inhaler along the arrow 3-3 illustrated in
Fig. 1B.
Fig. 4A is a perspective view of a chamber.
Fig. 4B is a sectional view of the chamber along the arrow 4B-4B illustrated in Fig.
4A.
Fig. 5A is a sectional view of the chamber along the arrow 5A-5A illustrated in Fig.
4B.
Fig. 5B is a sectional view of the chamber along the arrow 5B-5B illustrated in Fig.
4B.
Fig. 6 is a perspective view of the chamber and the heating portion.
Fig. 7 is a sectional view illustrated in Fig. 5B in a state where the flavor generating
article is disposed at a desired position in the chamber.
Fig. 8 is an enlarged sectional view of a first holding portion.
Fig. 9 is an enlarged sectional view of a second holding portion.
Fig. 10 is a perspective view of a gasket and an annular member.
Fig. 11 is a perspective view of the annular member and a fixed portion.
Fig. 12 is a sectional view illustrating a state of the annular member in a case where
an insertion guide member is inserted into an inner housing.
Fig. 13 is an enlarged sectional view illustrating another aspect of the second holding
portion.
DESCRIPTION OF EMBODIMENTS
[0031] Hereinafter, embodiments of the present invention will be described with reference
to the drawings. In the drawings described below, the same reference signs will be
applied to the same or corresponding components, and repeated description will be
omitted.
[0032] Fig. 1A is a schematic front view of a flavor inhaler 100 according to an embodiment.
Fig. 1B is a schematic top view of the flavor inhaler 100 according to the embodiment.
Fig. 1C is a schematic bottom view of the flavor inhaler 100 according to the embodiment.
In the drawings described in the specification, an X-Y-Z orthogonal coordinate system
may be added for convenience of description. In the coordinate system, the Z axis
is directed vertically upward, the X-Y plane is disposed to cut the flavor inhaler
100 in the horizontal direction, and the Y axis is disposed to extend from the front
surface to the rear surface of the flavor inhaler 100. The Z axis can also be called
an insertion direction of a flavor generating article to be accommodated in a chamber
50 of an atomization portion 30, which will be described later, or an axial direction
of the chamber 50. Additionally, the X axis is in a direction that perpendicularly
intersects the Y axis and the Z axis.
[0033] The flavor inhaler 100 according to the present embodiment is configured to generate
an aerosol containing a flavor by heating a flavor generating article of a stick type
having a flavor source containing an aerosol source, for example.
[0034] As illustrated in Figs. 1A to 1C, the flavor inhaler 100 has an outer housing 101
(corresponding to an example of a casing), a slide cover 102, and a switch portion
103. The outer housing 101 configures the outermost housing of the flavor inhaler
100 and has a size with which it fits in a user's hand. The user can hold the flavor
inhaler 100 with his/her hand and inhale the aerosol when the user uses the flavor
inhaler 100. The outer housing 101 may be configured by assembling a plurality of
members. The outer housing 101 is made of a resin, for example, and may be formed
of polycarbonate (PC), an acrylonitrile-butadiene-styrene (ABS) resin, or a polymer
alloy or the like containing polyether ether ketone (PEEK) or a plurality of types
of polymers, or metal such as aluminum, in particular.
[0035] The outer housing 101 has an opening, which is not illustrated, for receiving the
flavor generating article, and the slide cover 102 is slidably attached to the outer
housing 101 to close the opening. Specifically, the slide cover 102 is configured
to be movable along an outer surface of the outer housing 101 between a closed position
(the position illustrated in Figs. 1A and 1B) at which the opening of the outer housing
101 is closed and an open position at which the opening is open. It is possible to
cause the slide cover 102 to move between the closed position and the open position
by the user manually operating the slide cover 102, for example. In this manner, the
slide cover 102 is able to permit or restrict access to the flavor generating article
inside the flavor inhaler 100.
[0036] The switch portion 103 is used to switch ON and OFF of an operation of the flavor
inhaler 100. For example, power is supplied from a power source, which is not illustrated,
to a heating portion, which is not illustrated, and it is possible to heat the flavor
generating article without burning the flavor generating article, by the user operating
the switch portion 103 in a state where the flavor generating article is inserted
into the flavor inhaler 100. Note that the switch portion 103 may be a switch provided
outside the outer housing 101 or may be a switch located inside the outer housing
101. In a case where the switch is located inside the outer housing 101, the switch
is indirectly pressed by pressing the switch portion 103 on the surface of the outer
housing 101. In the present embodiment, an example in which the switch of the switch
portion 103 is located inside the outer housing 101 will be described.
[0037] The flavor inhaler 100 may further have a terminal, which is not illustrated. The
terminal can be an interface that connects the flavor inhaler 100 to an external power
source, for example. In a case where the power source included in the flavor inhaler
100 is a chargeable battery, the external power source can cause a current to flow
to the power source and charge the power source by connecting the external power source
to the terminal. Also, the flavor inhaler 100 may be configured to be able to transmit
data related to the operation of the flavor inhaler 100 to an external device by connecting
a data transmission cable to the terminal.
[0038] Next, the flavor generating article used by the flavor inhaler 100 according to the
present embodiment will be described. Fig. 2 is a schematic side sectional view of
the flavor generating article 110. In the present embodiment, the flavor inhaler 100
and the flavor generating article 110 can configure a smoking system. In the example
illustrated in Fig. 2, the flavor generating article 110 has a smokable article 111,
a tubular member 114, a hollow filter portion 116, and a filter portion 115.
[0039] The smokable article 111 is rolled by a first roll paper 112. The tubular member
114, the hollow filter portion 116, and the filter portion 115 are rolled by a second
roll paper 113 that is different from the first roll paper 112. The second roll paper
113 also rolls a part of the first roll paper 112 that rolls the smokable article
111. In this manner, the tubular member 114, the hollow filter portion 116, and the
filter portion 115 are coupled to the smokable article 111. However, the second roll
paper 113 may be omitted, and the tubular member 114, the hollow filter portion 116,
and the filter portion 115 may be coupled to the smokable article 111 by using the
first roll paper 112. A lip release agent 117 for promoting the user's lip release
from the second roll paper 113 is applied to the outer surface of the second roll
paper 113 in the vicinity of an end portion thereof on the side of the filter portion
115. The part of the flavor generating article 110 to which the lip release agent
117 is applied functions as a mouthpiece of the flavor generating article 110.
[0040] The smokable article 111 can contain a flavor source such as tobacco, for example,
and an aerosol source. Also, the first roll paper 112 for rolling the smokable article
111 can be a sheet member with breathability. The tubular member 114 can be a paper
pipe or a hollow filter. Although the flavor generating article 110 includes the smokable
article 111, the tubular member 114, the hollow filter portion 116, and the filter
portion 115 in the illustrated example, the configuration of the flavor generating
article 110 is not limited thereto. For example, the hollow filter portion 116 may
be omitted, and the tubular member 114 and the filter portion 115 may be disposed
to be adjacent to each other.
[0041] Next, an internal structure of the flavor inhaler 100 will be described. Fig. 3 is
a sectional view of the flavor inhaler 100 along the arrow 3-3 illustrated in Fig.
1B. As illustrated in Fig. 3, an inner housing 10 (corresponding to an example of
a casing) is provided inside the outer housing 101 of the flavor inhaler 100. The
inner housing 10 is made of a resin, for example, and may be formed of polycarbonate
(PC), an acrylonitrile-butadiene-styrene (ABS) resin, or a polymer alloy or the like
containing polyether ether ketone (PEEK) or a plurality of types of polymers, or metal
such as aluminum, in particular. Note that the inner housing 10 is preferably made
of PEEK in terms of heat resistance and strength. A power source portion 20 and the
atomization portion 30 are provided in the inner space of the inner housing 10. Also,
the outer housing 101 and the inner housing 10 may be collectively referred to as
a casing.
[0042] The power source portion 20 includes a power source 21. The power source 21 can be
a chargeable battery or a nonchargeable battery, for example. The power source 21
is electrically connected to the atomization portion 30. The power source 21 can thus
supply power to the atomization portion 30 to appropriately heat the flavor generating
article 110.
[0043] The atomization portion 30 has a chamber 50 (corresponding to an example of an accommodating
portion) extending in an insertion direction (Z-axis direction) of the flavor generating
article 110, a heating portion 40 covering a part of the chamber 50, a heat insulating
portion 32, and a substantially tubular insertion guide member 34 (corresponding to
an example of an abutting portion) as illustrated in the drawing. The chamber 50 is
configured to accommodate the flavor generating article 110 therein. The heating portion
40 is configured to come into contact with an outer circumferential surface of the
chamber 50 and heat the flavor generating article 110 accommodated in the chamber
50. As illustrated in the drawing, a bottom member 36 may be provided at the bottom
portion of the chamber 50. The bottom member 36 can function as a stopper that positions
a consumable material 110 inserted into the chamber 50. The bottom member 36 has irregularity
on a surface that the flavor generating article 110 abuts and can define a space into
which air can be supplied on the surface that the flavor generating article 110 abuts.
The bottom member 36 is made of a resin, for example, and may be formed of polycarbonate
(PC), an acrylonitrile-butadiene-styrene (ABS) resin, a polymer alloy or the like
containing polyether ether ketone (PEEK) or a plurality of types of polymers, or metal
such as aluminum, in particular. Note that the bottom member 36 is preferably formed
of a material with a low heat conductivity to prevent heat from being transmitted
to the heat insulating portion 32 and the like.
[0044] The heat insulating portion 32 has a substantially tubular shape as a whole and is
disposed to cover the chamber 50. The heat insulating portion 32 can include an aerogel
sheet, for example. The insertion guide member 34 is formed of a resin material, for
example, and is provided between the slide cover 102 at the closed position and the
chamber 50. The insertion guide member 34 communicates with the outside of the flavor
inhaler 100 when the slide cover 102 is at the open position, and the insertion guide
member 34 guides insertion of the flavor generating article 110 into the chamber 50
by inserting the flavor generating article 110 into the insertion guide member 34.
In Fig. 3, a state where the slide cover 102 is closed to cover the entire insertion
guide member 34 is illustrated by the two-dotted chain line.
[0045] The flavor inhaler 100 further includes a first holding portion 37 and a second holding
portion 38 that support both ends of the chamber 50 and the heat insulating portion
32. The first holding portion 37 is disposed to support end portions of the chamber
50 and the heat insulating portion 32 on the negative direction side of the Z axis.
The second holding portion 38 is disposed to support end portions of the chamber 50
and the heat insulating portion 32 on the side of the slide cover 102 (the positive
direction side of the Z axis). Details of the first holding portion 37 and the second
holding portion 38 will be described later.
[0046] Next, a structure of the chamber 50 will be described. Fig. 4A is a perspective view
of the chamber 50. Fig. 4B is a sectional view of the chamber 50 along the arrow 4B-4B
illustrated in Fig. 4A. Fig. 5A is a sectional view of the chamber 50 along the arrow
5A-5A illustrated in Fig. 4B. Fig. 5B is a sectional view of the chamber 50 along
the arrow 5B-5B illustrated in Fig. 4B. Fig. 6 is a perspective view of the chamber
50 and the heating portion 40.
[0047] As illustrated in Figs. 4A and 4B, the chamber 50 can have a tubular shape including
an opening 52 into which the flavor generating article 110 is inserted and a tubular
side wall portion 60 that accommodates the flavor generating article 110. A flange
portion 52a (corresponding to an example of an opening edge portion) is formed at
an end surface that defines the opening 52 formed at an end of the chamber 50. The
chamber 50 is preferably formed of a material with heat resistance and a small coefficient
of thermal expansion and can be formed of, for example, stainless steel. Note that
the chamber 50 may be formed of a resin such as PEEK, glass, ceramics, or the like
as well as metal. This enables effective heating of the flavor generating article
110 from the chamber 50. Note that the chamber 50 is not limited to the tubular shape
and may have a cup shape.
[0048] As illustrated in Figs. 4B and 5B, the side wall portion 60 includes contact portions
62 and a separated portion 66. When the flavor generating article 110 is disposed
at a desired position in the chamber 50, the contact portions 62 come into contact
with or press a part of the flavor generating article 110, and the separated portion
66 is separated from the flavor generating article 110. Note that in the specification,
"the desired position in the chamber 50" means the position at which the flavor generating
article 110 is appropriately heated or the position of the flavor generating article
110 when the user smokes. Each contact portion 62 has an inner surface 62a and an
outer surface 62b. The separated portion 66 has an inner surface 66a and an outer
surface 66b. As illustrated in Fig. 6, the heating portion 40 is disposed on the outer
surface 62b of the contact portion 62. The heating portion 40 is preferably disposed
with no clearance from the outer surface 62b of the contact portion 62. Note that
the heating portion 40 may include an adhesive layer. In that case, the heating portion
40 including the adhesive layer is preferably disposed with no clearance from the
outer surface 62b of the contact portion 62.
[0049] As illustrated in Figs. 4A and 5B, the outer surface 62b of the contact portion 62
is a planar surface. It is possible to prevent a strip-shaped electrode 48 from being
bent in a case where the strip-shaped electrode 48 is connected to the heating portion
40 disposed on the outer surface 62b of the contact portion 62 as illustrated in Fig.
6 by the outer surface 62b of the contact portion 62 being a planar surface. As illustrated
in Figs. 4B and 5B, the inner surface 62a of the contact portion 62 is a planar surface.
Also, the thickness of the contact portion 62 is uniform as illustrated in Figs. 4B
and 5B.
[0050] As illustrated in Figs. 4A, 4B, and 5B, the chamber 50 has two contact portions 62
in the circumferential direction of the chamber 50, and the two contact portions 62
face each other in parallel with each other. The distance of at least a part between
the inner surfaces 62a of the two contact portions 62 is preferably shorter than the
width of the flavor generating article 110 inserted into the chamber 50 at the location
disposed between the contact portions 62.
[0051] As illustrated in Fig. 5B, the inner surface 66a of the separated portion 66 can
have an arc-shaped section as a whole in the plane that perpendicularly intersects
the longitudinal direction (Z-axis direction) of the chamber 50. Also, the separated
portion 66 is disposed to be adjacent to the contact portions 62 in the circumferential
direction.
[0052] As illustrated in Fig. 4B, the chamber 50 can have a hole 56a at the bottom portion
56 thereof such that the bottom member 36 illustrated in Fig. 3 penetrates therethrough
and is disposed inside the chamber 50. The bottom member 36 can be fixed to the inside
of the bottom portion 56 of the chamber 50 with an adhesive or the like. Note that
the adhesive intervening between the bottom member 36 and the bottom portion 56 can
be configured of a resin material such as an epoxy resin. Instead of this, an inorganic
adhesive such as cement or welding can also be used. The bottom member 36 provided
at the bottom portion 56 can support a part of the flavor generating article 110 inserted
into the chamber 50 with at least a part of an end surface of the flavor generating
article 110 exposed. Also, the bottom portion 56 can support a part of the flavor
generating article 110 with the exposed end surface of the flavor generating article
110 communicating with a clearance 67 (see Fig. 7), which will be described later.
[0053] As illustrated in Figs. 4A and 4B, the chamber 50 preferably has a tubular non-holding
portion 54 between the opening 52 and the side wall portion 60. A clearance can be
formed between the non-holding portion 54 and the flavor generating article 110 in
a state where the flavor generating article 110 is positioned at a desired position
in the chamber 50. Also, as illustrated in Figs. 4A and 4B, the chamber 50 preferably
has a first guide portion 58 including a tapered surface 58a that connects the inner
surface of the non-holding portion 54 to the inner surfaces 62a of the contact portions
62.
[0054] As illustrated in Fig. 6, the heating portion 40 has a heating element 42. The heating
element 42 may be a heating track, for example. The heating element 42 is preferably
disposed to heat the contact portions 62 without coming into contact with the separated
portion 66 of the chamber 50. In other words, the heating element 42 is preferably
disposed only on the outer surfaces of the contact portions 62. The heating element
42 may have a difference in heating capability between a part heating the separated
portion 66 of the chamber 50 and a part heating the contact portions 62. Specifically,
the heating element 42 may be configured to heat the contact portions 62 to a higher
temperature than that of the separated portion 66. For example, disposition densities
of the heating track of the heating element 42 in the contact portions 62 and the
separated portion 66 can be adjusted. Also, the heating element 42 may be wound around
the outer circumference of the chamber 50 while exhibiting substantially the same
heating capability over the entire circumference of the chamber 50. As illustrated
in Fig. 6, the heating portion 40 preferably has an electrically insulating member
44 that covers at least one surface of the heating element 42 in addition to the heating
element 42. In the present embodiment, the electrically insulating member 44 is disposed
to cover both surfaces of the heating element 42.
[0055] Fig. 7 is a sectional view illustrated in Fig. 5B in a state where the flavor generating
article 110 is disposed at a desired position in the chamber 50. As illustrated in
Fig. 7, once the flavor generating article 110 is disposed at a desired position in
the chamber 50, the flavor generating article 110 can come into contact with and be
pressed by the contact portions 62 of the chamber 50. On the other hand, the clearance
67 is formed between the flavor generating article 110 and the separated portion 66.
The clearance 67 can communicate with the opening 52 of the chamber 50 and the end
surface of the flavor generating article 110 located in the chamber 50. In this manner,
air flowing from the opening 52 of the chamber 50 can pass through the clearance 67
and flow to the inside of the flavor generating article 110. In other words, an air
flow path (clearance 67) is formed between the flavor generating article 110 and the
separated portion 66.
[0056] Next, structures of the first holding portion 37 and the second holding portion 38
(corresponding to an example of a sealing portion) that hold the chamber 50 and the
heat insulating portion 32 will be described. Fig. 8 is an enlarged sectional view
of the first holding portion 37. Fig. 9 is an enlarged sectional view of the second
holding portion 38. Note that an annular member 90, which will be described later,
is illustrated in a state before the insertion guide member 34 is inserted into an
inner housing, which is not illustrated, that is, in a state where a pressurized portion
92 of the annular member 90 has not been pushed down in Fig. 9.
[0057] As illustrated in Fig. 8, the first holding portion 37 has a cap 72 and a heater
cushion 74 . The cap 72 is configured such that a first side surface 72a facing the
chamber 50 abuts the bottom portion 56 of the chamber 50 and supports the chamber
50. The cap 72 is made of a resin, for example, and may be formed of polycarbonate
(PC), an acrylonitrile-butadiene-styrene (ABS) resin, or a polymer alloy or the like
containing polyether ether ketone (PEEK) or a plurality of types of polymers, in particular.
Note that the cap 72 may be formed of metal, glass, ceramics, or the like. Also, the
cap 72 is preferably made of PEEK in terms of heat resistance. Additionally, a rib
72b projecting toward the heater cushion 74 is provided at the cap 72 to stand on
the surface on the side opposite to the first side surface 72a.
[0058] The heater cushion 74 is configured to accommodate and support an end of the cap
72. The heater cushion 74 includes a second side surface 74d that is configured to
abut the rib 72b formed at the cap 72. Also, the heater cushion 74 includes, on a
surface on a side opposite to the chamber 50, a third side surface 74e that is configured
to abut the fixed portion 22 and is provided with a projecting portion 74a that projects
in a direction opposite to the chamber 50. The heater cushion 74 can be formed of
an elastic member such as silicone rubber, for example. Note that in a case where
silicone rubber is used, a preferred range of Shore A hardness is 40 to 60 and can
be appropriately selected in accordance with deformation of the heater cushion 74.
Also, the heater cushion 74 is configured to be positioned at and fixed to the fixed
portion 22 that is fixed to the inner housing, which is not illustrated. Note that
the fixed portion 22 may be the inner housing itself.
[0059] As illustrated in Fig. 9, the flange portion 52a of the chamber 50 is configured
to abut the insertion guide member 34 over the entire circumference. The insertion
guide member 34 is made of a resin, for example, and may be formed of polycarbonate
(PC), an acrylonitrile-butadiene-styrene (ABS) resin, or a polymer alloy or the like
containing polyether ether ketone (PEEK) or a plurality of types of polymers, in particular.
Note that the insertion guide member 34 may be formed of metal, glass, ceramics, or
the like. Also, the insertion guide member 34 is preferably made of PEEK in terms
of heat resistance. The second holding portion 38 is configured to seal an aerosol
that is generated in the chamber 50 due to heating of the flavor generating article
110 at a position away from the chamber 50, specifically, at a position thermally
separated from the heating portion 40 that covers the chamber 50 and leaks from a
part between the chamber 50 and the insertion guide member 34.
[0060] Specifically, the second holding portion 38 includes a gasket 80 (corresponding to
an example of a first member) and the annular member 90 (corresponding to an example
of a second member). The gasket 80 and the annular member 90 form a sealing portion.
The gasket 80 is disposed over the entire circumference of the outer circumferential
surface of the chamber 50 around the non-holding portion 54 of the chamber 50 and
is configured as an annular member that supports the chamber 50. The gasket 80 is
made of a resin, for example, and may be formed of polycarbonate (PC), an acrylonitrile-butadiene-styrene
(ABS) resin, or a polymer alloy or the like containing polyether ether ketone (PEEK)
or a plurality of types of polymers, in particular. Note that the gasket 80 may be
formed of metal, glass, ceramics, or the like. Also, the gasket 80 is preferably made
of PEEK in terms of heat resistance.
[0061] The annular member 90 is brought into contact with the insertion guide member 34
over the entire circumference of the insertion guide member 34 by the pressurized
portion 92, which will be described later and is configured to be engaged with the
gasket 80 and support them over the entire circumference of the gasket 80. The annular
member 90 can be formed of an elastic member such as silicone rubber, for example.
In a case where silicone rubber is used, a preferred range of Shore A hardness is
40 to 60 and can be appropriately selected in accordance with deformation of the annular
member 90. Also, the annular member 90 is configured to be positioned at and fixed
to the fixed portion 22 that is fixed to the inner housing, which is not illustrated.
[0062] Here, a seal surface 85 that extends along the axial direction of the chamber 50
is formed at a contact location between the gasket 80 and the annular member 90. The
seal surface 85 is formed on the side closer to the axis of the chamber 50 in the
radial direction of the chamber 50 than the outer edge of the gasket 80. The second
holding portion 38 including the gasket 80 and the annular member 90 can thus seal,
at a position separated from the chamber 50, the aerosol that leaks from the part
between the chamber 50 and the insertion guide member 34 to the inside of the inner
housing.
[0063] In this manner, heat from the chamber 50 is unlikely to be transmitted to the sealed
part, degradation at the sealed part is prevented, and it is thus possible to prevent
the aerosol generated in the chamber 50 from leaking to the inside of the inner housing
by the second holding portion 38 sealing the aerosol leaking from the part between
the chamber 50 and the insertion guide member 34 at the position separated from the
chamber 50.
[0064] Also, since the seal surface 85 is formed on the side closer to the axis of the chamber
50 in the radial direction of the chamber 50 than the outer edge of the gasket 80
at the contact location between the gasket 80 and the annular member 90, it is possible
to reduce the size of the flavor inhaler 100 as compared with a case where the seal
surface is formed at the outer edge of the gasket 80. Additionally, since the annular
member 90 is configured of an elastic material, it is possible to improve a sealing
property of the seal surface 85.
[0065] Furthermore, since it is possible to widen the area where the gasket 80 and the annular
member 90 come into contact with each other by the gasket 80 and the annular member
90 coming into surface contact with each other to form the seal surface 85, it is
possible to further prevent the aerosol generated in the chamber 50 from leaking to
the inside of the inner housing. Note that the gasket 80 and the annular member 90
are not necessarily in surface contact with each other, and the gasket 80 and the
annular member 90 may be in point contact with each other in a sectional view illustrated
in Fig. 9. In this case, a seal portion is formed at the contact location between
the gasket 80 and the annular member 90.
[0066] Next, preferred shapes of the gasket 80 and the annular member 90 will be described.
Fig. 10 is a perspective view of the gasket 80 and the annular member 90. Fig. 11
is a perspective view of the annular member 90 and the fixed portion 22. As illustrated
in Figs. 9, 10, and 11, the gasket 80 includes a jaw portion 81 and a projecting portion
82. Also, the annular member 90 includes a recessed portion 91, a pressurized portion
92, a positioning portion 93, and a holding portion 94. The gasket 80 and the annular
member 90 are disposed to be aligned along the axial direction of the chamber 50.
[0067] The jaw portion 81 of the gasket 80 is formed on an inner circumferential surface
of the gasket 80 and is configured to be engaged with the flange portion 52a of the
chamber 50 and support the chamber 50. The projecting portion 82 of the gasket 80
is configured to project from the main body part of the gasket 80 toward the annular
member 90 along the axial direction of the chamber 50.
[0068] The recessed portion 91 of the annular member 90 is provided to face the projecting
portion 82 of the gasket 80. Here, the seal surface 85 is formed at the contact location
between the surface of the projecting portion 82 on the inner side in the axial direction
of the chamber 50 and the surface of the recessed portion 91 on the outer side in
the axial direction of the chamber 50. In this manner, since the surface of the projecting
portion 82 and the surface of the recessed portion 91 come into contact with each
other to form the seal surface 85 at the contact location between the projecting portion
82 and the recessed portion 91, it is possible to improve the sealing property of
the seal surface 85 and to further prevent the aerosol generated in the chamber 50
from leaking to the inside of the inner housing. Additionally, it is possible to extend
the leakage path length of the aerosol by the projecting portion 82 and the recessed
portion 91 forming the seal surface 85 and thereby to further prevent the aerosol
generated in the chamber 50 from leaking to the inside of the inner housing.
[0069] At this time, the projecting portion 82 of the gasket 80 and the recessed portion
91 of the annular member 90 are preferably configured to be mutually slidable on the
seal surface 85. In this manner, even in a case where a force in the axial direction
is applied to the chamber 50 by the insertion guide member 34, for example, and the
chamber 50 moves in the axial direction, a stress does not occur at the gasket 80
supporting the chamber 50 since the projecting portion 82 and the recessed portion
91 mutually slide on the seal surface 85. Therefore, it is possible to prevent sealing
breakage between the gasket 80 and the annular member 90.
[0070] Note that although the description that the seal surface 85 is formed at the contact
location between the projecting portion 82 and the recessed portion 91 has been given,
the present invention is not limited thereto. The gasket 80 and the annular member
90 may include a first projecting portion and a second projecting portion projecting
toward the annular member 90 and the gasket 80, respectively, along the axial direction
of the chamber 50, and the seal surface may be formed at the contact location between
the surface of the first projecting portion on the inner side in the axial direction
of the chamber 50 and the surface of the second projecting portion on the outer side
in the axial direction of the chamber 50.
[0071] Since the surface of the first projecting portion and the surface of the second projecting
portion come into contact with each other to form the seal surface at the contact
location between the first projecting portion and the second projecting portion in
this case as well, it is possible to improve the sealing property of the seal surface
and to further prevent the aerosol generated in the chamber 50 from leaking to the
inside of the inner housing.
[0072] The pressurized portion 92 of the annular member 90 is formed to project from the
inner circumferential surface of the annular member 90 and is configured as an annular
lip-shaped member that comes into contact with the insertion guide member 34. The
projecting length of the pressurized portion 92 (the length along the radial direction
of the chamber 50) is longer than the thickness of the pressurized portion 92 (the
length along the axial direction of the chamber 50), and the pressurized portion 92
has an inner diameter that is smaller than the outer diameter of the insertion guide
member 34. The pressurized portion 92 is pressurized by the insertion guide member
34 and is pushed down on the negative direction side of the Z axis when the insertion
guide member 34 is inserted into the inner housing at the time of manufacturing of
the flavor inhaler 100. Fig. 12 is a sectional view illustrating a state of the annular
member in the case where the insertion guide member is inserted into the inner housing.
As illustrated in Fig. 12, the pressurized portion 92 of the annular member 90 is
pushed down in the insertion direction (from the upper side to the lower side in the
drawing) of the insertion guide member 34.
[0073] In this manner, since the sealing is formed between the insertion guide member 34
and the pressurized portion 92, it is possible to prevent the aerosol generated in
the chamber 50 from leaking to the inside of the inner housing. Also, since the projecting
length of the pressurized portion 92 is longer than the thickness of the pressurized
portion 92, it is possible to form sealing between the insertion guide member 34 and
the pressurized portion 92 while reducing a resistance at the time of the insertion
of the insertion guide member 34. Moreover, it is possible to prevent incomplete engagement
with the gasket 80 due to the outer circumferential portion of the annular member
90 being turned up on the side of the slide cover 102 (the positive direction side
of the Z axis) by reducing the resistance at the time of the insertion of the insertion
guide member 34.
[0074] At this time, the annular member 90 is preferably configured to be biased toward
the gasket 80 by the pressurized portion 92 being pressurized by the insertion guide
member 34. In this manner, the annular member 90 is biased toward the gasket 80, and
it is thus possible to improve the sealing property of the seal surface 85.
[0075] In summary, the recessed portion 91 of the annular member 90 is provided to face
the projecting portion 82 of the gasket 80, the projecting portion 82 is inserted
into the recessed portion 91, and the annular member 90 is held by the gasket 80.
Since the flange portion 52a does not pass through the chamber 50 when the chamber
50 is inserted into the gasket 80 from the bottom portion side, the chamber 50 is
held by the gasket 80. The flange portion 52a and the gasket 80 are brought into close
contact with each other with no gap therebetween with a gluing agent or an adhesive.
Additionally, the gasket 80 is fitted to the inner diameter of one side of the heat
insulating portion 32 and holds the heat insulating portion 32.
[0076] The heater cushion 74 holds the bottom portion side of the chamber 50 and the inner
diameter of the other side of the heat insulating portion 32. The rib 72b provided
at the support portion 72 abuts the second side surface 74d of the heater cushion
74, and the projecting portion 74a formed on the third side surface 74e of the heater
cushion 74 abuts the fixed portion 22.
[0077] If the insertion guide member 34 is inserted into the casing in a state where a heating
unit including the annular member 90, the gasket 80, the chamber 50, the heat insulating
portion 32, and the heater cushion 74 described above is accommodated in the casing,
the insertion guide member 34 comes into contact with the pressurized portion 92.
The diameter of the pressurized portion 92 is set to be smaller than the diameter
of the insertion guide member 34, the pressurized portion 92 is pushed down in the
insertion direction with the insertion of the insertion guide member 34, one surface
of the pressurized portion 92 is brought into close contact with the insertion guide
member 34, and the part between the one surface of the pressurized portion 92 and
the insertion guide member 34 is sealed. Thereafter, if the distal end of the insertion
guide member 34 comes into contact with the flange portion 52a, and the insertion
guide member 34 is further inserted until a claw thereof is engaged with the casing,
the rib 72b bites into the heater cushion 74, the projecting portion 74a of the heater
cushion 74 collapses at the same time, and the heater cushion 74 causes a reactive
force. The distal end of the insertion guide member 34 is brought into close contact
with the flange portion 52a due to the reactive force, and the gap between the flange
portion 52a and the insertion guide member 34 is canceled. It is possible to prevent
the aerosol that is present in the chamber 50 from leaking from the gap to the inside
of the casing by canceling the gap.
[0078] In the flavor inhaler described in PTL 1, the O-ring is extended to be fitted into
the groove and is further compressed in an attached state, and a compression stress
thus continuously acts on the member with the groove formed therein for a long period
of time. If the groove is deformed, there is a concern that the an aerosol generated
in the accommodating portion may leak to the inside of the casing of the flavor inhaler,
and may promote degradation of an electronic circuit portion, or may lead to a breakdown
of the device due to a contact failure of an electric contact portion. In order to
avoid this, it is necessary to increase the thickness or employ a material with high
rigidity in order to enhance rigidity of the member with the groove formed therein.
Also, in order to secure a stable amount of compression, the member with the groove
formed therein requires to be manufactured with high precision. This may result in
increases in size and cost of the device.
[0079] On the other hand, the gap between the flange portion 52a and the insertion guide
member 34 can be canceled by the aforementioned simple configuration in the present
embodiment.
[0080] Also, since this type of device is carried, a user may drop it by mistake in some
cases. There may be a case where the device is deformed at the moment when the device
is dropped and collides against the ground and the close contact between the flange
portion 52a and the distal end of the insertion guide member 34 achieved by the action
of the heater cushion 74 is canceled just for a moment. If the close contact is cancelled,
there is a concern that the aerosol may leak from the gap between the flange portion
52a and the insertion guide member 34 to the inside of the casing.
[0081] Thus, the annular member 90 capable of securing a sealing property between the insertion
guide member 34 and the annular member 90 and between the annular member 90 and the
gasket 80 by being pushed down is disposed in order to prevent the aerosol from leaking
to the inside of the casing through the gap generated between the flange portion 52a
and the insertion guide member 34 and avoid an increase in size of the device with
a simple configuration in the present embodiment.
[0082] Note that although Fig. 10 has been described on the assumption that the pressurized
portion 92 of the annular member 90 is a lip-shaped member, the present invention
is not limited thereto. Fig. 13 is an enlarged sectional view illustrating another
aspect of the second holding portion. As illustrated in Fig. 13, a pressurized portion
192 may be configured as an annular member that projects in an arc shape from the
inner circumferential surface of the annular member 90 toward the insertion guide
member 34 and comes into contact with the insertion guide member 34 at a point in
the sectional view illustrated in Fig. 9. Additionally, the pressurized portion 192
has an inner diameter that is smaller than the outer diameter of the insertion guide
member 34. In this case, it is possible to form a seal between the insertion guide
member 34 and the pressurized portion 192 while reducing a resistance at the time
of the insertion of the insertion guide member 34 as compared with a case where the
entire inner circumferential surface of the annular member 90 comes into contact with
the insertion guide member 34.
[0083] The positioning portion 93 of the annular member 90 projects outward from the main
body part of the annular member 90 and is configured to be engaged with a positioning
claw 22a formed at the fixed portion 22. In this manner, the annular member 90 is
held by the fixed portion 22, and the annular member 90 and the gasket 80 can thus
cooperate to prevent positional deviation of the chamber 50 in the inner housing.
Therefore, it is possible to easily attach the insertion guide member 34.
[0084] The holding portion 94 of the annular member 90 projects outward from the main body
part of the annular member 90 and is configured to hold a state detecting portion
that detects a state of the insertion guide member 34. The state detecting portion
is, for example, a puff thermistor. It is thus possible to measure a change in temperature
of the insertion guide member 34 by the puff thermistor and to detect a puffing operation
performed by the user.
[0085] Note that the heater cushion 74 may bias the chamber 50 toward the insertion guide
member 34 to form a seal between the flange portion 52a of the chamber 50 and the
insertion guide member 34 in order to further prevent the aerosol generated in the
chamber 50 from leaking from the part between the chamber 50 and the insertion guide
member 34 to the inside of the inner housing in Figs. 8 and 9.
[0086] A method for manufacturing such a flavor inhaler 100 includes disposing the chamber
50 inside the sealing portion, disposing the sealing portion inside the inner housing,
inserting the insertion guide member 34 into the sealing portion such that the insertion
guide member 34 abuts the flange portion 52a, pressurizing the pressurized portion
92 in the insertion direction of the insertion guide member 34 by inserting the insertion
guide member 34 into the sealing portion, and forming the seal part by biasing the
pressurized portion 92 toward the outer side in the radial direction of the chamber
50.
[0087] Although the embodiment of the present invention has been described above, the present
invention is not limited to the above embodiment, and various modification can be
made within the scope of the technical idea described in the claims, the specification,
and the drawings. Note that any shapes and materials that are not directly described
in the specification and the drawings also fall within the scope of the technical
idea of the invention of the present application as long as the effects and the advantages
of the invention of the present application can be achieved.
[0088] For example, although the flavor inhaler 100 according to the present embodiment
has a so-called counterflow-type air flow path through which air flowing from the
opening 52 of the chamber 50 is supplied to the end surface of the flavor generating
article 110, the present invention is not limited thereto, and the flavor inhaler
100 may have a so-called bottom flow-type air flow path through which air is supplied
from the bottom portion 56 of the chamber 50 to the inside of the chamber 50. Also,
the heating element 42 is not limited to a resistance heating type and may be an induction
heating type. In that case, the heating element 42 can heat the chamber 50 through
induction heating. Also, in a case where the flavor generating article 110 has a susceptor,
the heating element 42 can heat the susceptor of the flavor generating article 110
through induction heating.
REFERENCE SIGNS LIST
[0089]
10 Inner housing
22 Fixed portion
22a Positioning claw
34 Insertion guide member
37 First holding portion
38 Second holding portion
50 Chamber
52 Opening
52a Flange portion
72 Cap
74 Heater cushion
80 Gasket
81 Jaw portion
82 Projecting portion
85 Seal surface
90 Annular member
91 Recessed portion
92 Pressurized portion
93 Positioning portion
94 Holding portion
100 Flavor inhaler
101 Outer housing
110 Flavor generating article
192 Pressurized portion
1. A flavor inhaler comprising:
a tubular accommodating portion that has an opening formed at one end by an opening
edge portion and accommodates at least a part of a flavor generating article via the
opening;
a tubular abutting portion that abuts the opening edge portion over an entire circumference
of the opening; and
a sealing portion that seals a part between the accommodating portion and the abutting
portion at a position separated from the accommodating portion.
2. The flavor inhaler according to claim 1,
wherein the sealing portion includes
an annular first member that is provided over an entire circumference of an outer
circumferential surface of the accommodating portion and supports the accommodating
portion, and
a second member that comes into contact with the abutting portion over an entire circumference
of the abutting portion, is engaged with the first member over an entire circumference
of the first member, and is configured of an elastic material,
a seal portion is formed at a contact location between the first member and the second
member, and
the seal portion is formed on a side closer to an axis of the accommodating portion
in a radial direction of the accommodating portion than an outer edge of the first
member.
3. The flavor inhaler according to claim 2, wherein the seal portion includes a seal
surface that extends along an axial direction of the accommodating portion.
4. The flavor inhaler according to claim 3,
wherein the first member and the second member are disposed to be aligned along the
axial direction of the accommodating portion,
the first member includes a projecting portion that projects toward the second member
along the axial direction of the accommodating portion,
the second member includes a recessed portion that is provided to face the projecting
portion, and
the seal surface is formed at a contact location between a surface of the projecting
portion on an inner side in the axial direction of the accommodating portion and a
surface of the recessed portion on an outer side in the axial direction of the accommodating
portion.
5. The flavor inhaler according to claim 3,
wherein the first member and the second member are disposed to be aligned along the
axial direction of the accommodating portion,
the first member includes a first projecting portion that projects toward the second
member along the axial direction of the accommodating portion,
the second member includes a second projecting portion that projects toward the first
member along the axial direction of the accommodating portion, and
the seal surface is formed at a contact location between a surface of the first projecting
portion on an inner side in the axial direction of the accommodating portion and a
surface of the second projecting portion on an outer side in the axial direction of
the accommodating portion.
6. The flavor inhaler according to any one of claims 3 to 5, wherein the first member
and the second member are mutually slidable on the seal surface.
7. The flavor inhaler according to any one of claims 2 to 6, wherein the second member
includes a pressurized portion that is pressurized by the abutting portion.
8. The flavor inhaler according to claim 7, wherein the second member is biased toward
the first member by the pressurized portion being pressurized by the abutting portion.
9. The flavor inhaler according to any one of claims 2 to 8, wherein the second member
includes a positioning portion that is engaged with at least one of a casing of the
flavor inhaler and a fixed portion that is fixed to the casing of the flavor inhaler.
10. The flavor inhaler according to any one of claims 2 to 9, wherein the second member
includes a holding portion that holds a state detecting portion that detects a state
of the abutting portion.
11. A flavor inhaler comprising:
a tubular accommodating portion that has an opening formed at one end by an opening
edge portion and accommodates at least a part of a flavor generating article via the
opening;
a tubular abutting portion that abuts the opening edge portion over an entire circumference
of the opening; and
a sealing portion that seals a part between the accommodating portion and the abutting
portion at a position separated from the accommodating portion,
wherein the sealing portion includes a pressurized portion that projects from the
sealing portion, is pressurized by the abutting portion, has an annular shape, and
is configured of an elastic member, and
a projecting length of the pressurized portion is longer than a thickness of the pressurized
portion that perpendicularly intersects the projecting direction in a state before
the pressurization.
12. A method for manufacturing a flavor inhaler that includes
a tubular accommodating portion that has an opening formed at one end by an opening
edge portion and accommodates at least a part of a flavor generating article via the
opening,
a tubular abutting portion that abuts the opening edge portion, and
a sealing portion that seals a part between the accommodating portion and the abutting
portion at a position separated from the accommodating portion,
wherein the sealing portion includes a pressurized portion that is pressurized by
the abutting portion, has an annular shape, and is configured of an elastic member,
the method comprising:
disposing the accommodating portion inside the sealing portion;
disposing the sealing portion inside a casing of the flavor inhaler;
inserting the abutting portion into the sealing portion such that the abutting portion
abuts the opening edge portion; and
pressurizing the pressurized portion in an insertion direction of the abutting portion
by inserting the abutting portion into the sealing portion and forming a seal portion
by biasing the pressurized portion toward an outer side in a radial direction of the
accommodating portion.