KR102016848B1 - Cartridge for use of smoking article and aerosol inhaler thereof - Google Patents

Abstract

According to an embodiment, an aerosol inhaler may include a sealed space in which external air is blocked, an open space configured to allow external air to flow therein and be in fluid communication with the sealed space, and a mouthpiece in fluid communication with the open space. A nicotine source disposed in said confined space; An organic acid source disposed in the confined space; And a flow generator configured to generate flow from the closed space to the mouthpiece via the open space.

Description

Cartridge for smoking article and aerosol inhaler thereof {CARTRIDGE FOR USE OF SMOKING ARTICLE AND AEROSOL INHALER THEREOF}

The embodiments below relate to cartridges for smoking articles and aerosol inhalers thereof.

Inhalation devices have been developed, including e-cigarettes which vaporize by heating the liquid phase containing nicotine solution and inhale the vaporized aerosol. Many users smoke through the developed inhalation devices, and the number of users using the inhalation devices is increasing. In the related art, new types of aerosol inhalers have been developed that improve upon conventional smoking articles to aerosolize nicotine related substances in a manner other than combustion or heating. For example, Korean Patent Publication No. 10-1257597 discloses an unheated tobacco flavor aspirator.

It is an object according to one embodiment to provide a cartridge for a smoking article and an aerosol inhaler thereof for aerosolizing nicotine-related substances using a flow generator.

According to an embodiment, an aerosol inhaler may include a sealed space in which external air is blocked, an open space configured to allow external air to flow therein and be in fluid communication with the sealed space, and a mouthpiece in fluid communication with the open space. A nicotine source disposed in said confined space; An organic acid source disposed in the confined space; And a flow generator configured to generate flow from the closed space to the mouthpiece via the open space.

The pressure in the confined space after the flow generator is activated may be lower than the pressure in the confined space before the flow generator is operated.

While the flow generator is in operation, nicotine-related material of the nicotine source and organic acid material of the organic acid source may move from the enclosed space to the open space, where mixing of the nicotine-related material and the organic acid material may occur. have.

The nicotine source and the organic acid source may be separated based on the flow generator.

The aerosol inhaler may further comprise a flow barrier configured to guide some of the materials flowing from the closed space through the open space to the mouthpiece into the open space.

The aerosol inhaler may further comprise a liquid absorbing element for removing liquid components contained in the air flowing from the open space to the mouthpiece.

The aerosol inhaler comprising a first reservoir comprising a first brittle barrier surrounding the nicotine source; A second reservoir comprising a second brittle barrier surrounding the organic acid source; And crushing elements for crushing each of the first brittle barrier and the second brittle barrier, the crushing elements being configured to be movable relative to the first reservoir and the second reservoir.

In one embodiment, an aerosol inhaler includes a mouthpiece; An open space having an air inlet in fluid communication with the mouthpiece and into which outside air is introduced, and a closed space in fluid communication with the open space and blocking the inflow of external air, the nicotine source and an organic acid source; housing; And a flow generator having a rotation axis and rotatable about the rotation axis and configured to generate a flow from the closed space to the mouthpiece via the open space.

The flow generator includes a wing configured to rotate about the axis of rotation, the wing extending along the axial direction of the axis of rotation and the nicotine-related material of the nicotine source and the organic acid of the organic acid source from the closed space to the open space. It may have a profile that guides the material.

The flow generator further includes an additional wing configured to rotate about the axis of rotation, wherein the additional wing may extend from the outside of the housing toward the center of the housing in a direction crossing the axis of rotation.

The flow generator further includes an enclosure surrounding the wing, wherein the enclosure of the flow generator is configured to transfer nicotine-related material of the nicotine source and organic acid material of the organic acid source from the enclosed space to the open space along the profile of the wing. It may have a profile to guide.

According to one embodiment, a cartridge for a smoking article includes an air inlet and an air outlet, and includes a nicotine source; Organic acid sources; And a flow generator configured to generate a flow of nicotine related material of the nicotine source and organic acid material of the organic acid source in a flow path through which air flows from the air inlet to the air outlet, wherein the nicotine source and the organic acid source May be disposed on the flow path.

One source of the nicotine source and the organic acid source may be disposed behind the flow generator, and the other source may be disposed in front of the flow generator.

A reservoir comprising a source disposed in front of said flow generator, said reservoir having a profile for guiding the flow generated by said flow generator.

The nicotine source and the organic acid source may be disposed behind the flow generator.

According to one embodiment, a cartridge for a smoking article and an aerosol inhaler thereof may efficiently deliver an aerosolized nicotine-related substance to a user using a flow generator.

Effects of the cartridge for a smoking article and the aerosol inhaler thereof according to one embodiment are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a sectional view schematically showing an aerosol inhaler according to a first embodiment.
2 is a sectional view schematically showing the cartridge and the flow generator according to the first embodiment.
3 is an operation diagram schematically showing the operation of the aerosol inhaler according to the first embodiment.
4 is a sectional view schematically showing the cartridge and the flow generator according to the second embodiment.
5 is a cross-sectional view schematically showing an aerosol inhaler according to a third embodiment.
6 is a schematic cross-sectional view of a housing and a flow generator according to a third embodiment.
7 is an enlarged view enlarging a part of the flow generator according to the third embodiment.
8 is a cross-sectional view schematically showing an example of a bearing coupled to a housing according to the third embodiment.
9 is a schematic cross-sectional view of yet another example of a bearing coupled to a housing according to the third embodiment.
10 is a schematic cross-sectional view showing an assembly method of an aerosol inhaler according to a third embodiment.
11 is a schematic cross-sectional view illustrating an assembly method of an aerosol inhaler according to a third embodiment.
12 is a schematic cross-sectional view of an aerosol inhaler including a flow barrier and a liquid absorbing element according to a third embodiment.

Hereinafter, the embodiments will be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the embodiment, when it is determined that the detailed description of the related known configuration or function is to interfere with the understanding of the embodiment, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but between components It will be understood that may be "connected", "coupled" or "connected".

Components included in one embodiment and components including common functions will be described using the same names in other embodiments. Unless stated to the contrary, the description in any one embodiment may be applied to other embodiments, and detailed descriptions thereof will be omitted in the overlapping range.

As used herein, the term "aerosol inhaler" refers to an aerosolized nicotine-related material of a nicotine source, an aerosolized material according to the reaction of a nicotine-related material and an organic acid material of an organic acid source, through the user's mouth. A device that delivers into the stomach.

As used herein, the term "nicotine source" refers to a source that supplies nicotine related substances, including nicotine related substances. Here, the nicotine-related substance may include nicotine, nicotine salt, nicotine alkaloid, nicotine derivatives, and the like.

As used herein, the term "organic acid source" refers to a source for supplying organic acid materials, including organic acid materials. Here, the organic acid material is acetic acid, pyruvic acid, 3-methyl-2-oxobutyric acid, 2-oxovaleric acid, 3-methyl Oxo valeric acid (3-methyl-2-oxovaleric acid), 4-methyl-2-oxovaleric acid, 4-ox-2-ic acid, 2-oxooctanoic acid ( 2-oxoocatanoic acid), lactic acid, and the like.

As used herein, the term "closed space" refers to a space from which outside air is blocked. Therefore, the atmospheric pressure inside the sealed space may be smaller than the atmospheric pressure outside. Preferably, the interior of the sealed space is in a vacuum state.

As used herein, the term "open space" refers to a space in which outside air is allowed to enter. Thus, the atmospheric pressure inside the open space may be substantially the same as the external atmospheric pressure.

1 is a cross-sectional view schematically showing an aerosol inhaler according to a first embodiment, and FIG. 2 is a cross-sectional view schematically showing a cartridge and a flow generator according to a first embodiment.

1 and 2, the aerosol inhaler 100 according to an embodiment includes a cartridge 120 including a first reservoir 122 and a second reservoir 124 in the housing 110. The flow generator 130 may be installed in the cartridge 120 to generate aerosol by promoting vaporization of the material of the source included in the first reservoir 122 and the material of the source included in the second reservoir 124. have.

The housing 110 includes at least one air inlet 1121 and 1125 and a mouthpiece 1141 to which external air is introduced, and the aerosol is delivered to the oral cavity of the user through the mouthpiece 1141. At least one air inlet 1125 may be formed in a manner that is finely perforated in the housing 110.

In one embodiment, the housing 110 may include two portions 112, 114. The first portion 112 and the second portion 114 of the housing 110 are coupled to each other. In one example, the first portion 112 and the second portion 114 may be custom coupled to each other. In one example, the first portion 112 and the second portion 114 may move relative to each other. While the first portion 112 and the second portion 114 move relative to each other, the inflow of outside air into at least one or more air inlets 1121 and 1125 may be selectively opened or blocked.

The first portion 112 of the housing 110 has a first air inlet 1121 located behind the first portion 112 (distally from the user's mouth) and a first portion (distally from the user's mouth) A second air inlet 1125 located on the side of 112, wherein the second portion 114 of the housing 110 is in mouth fluid 1141 (proximal from the user's mouth) in fluid communication with the user's mouth. It may include.

The first portion 112 and the second portion 114 of the housing 110 may be substantially cylindrical. The diameter of the mouthpiece 1141 of the second portion 114 may be smaller than the diameter of other sections constituting the second portion 114 except for the mouthpiece 1141.

The first portion 112 of the housing 110 may include a power supply 1122 and a driver 1123. For example, the power supply 1122 may include a battery, and the driver 1123 may include a rotating motor that transmits rotational force. The power supply 1122 and the driver 1123 are electrically connected to each other.

The first portion 112 of the housing 110 may include a passage 1124 directed from the rear of the first portion 112 toward the front of the first portion 112 via the driver 1123. Accordingly, the outside air introduced through the first air inlet 1121 may flow along the passage 1124 to the front of the first portion 112 to cool the power supply 1122 and the driver 1123.

The cartridge 120 may include a first reservoir 122 and a second reservoir 124. One reservoir of the first reservoir 122 and the second reservoir 124 may comprise a nicotine source and the other reservoir may comprise an organic acid source.

In one embodiment, the first reservoir 122 may be configured to surround either the source of nicotine or the organic acid source, and the second reservoir 124 may be configured to surround the other of the nicotine source or the organic acid source. In one example, the first reservoir 122 and the second reservoir 124 may include a membrane for permeation of the material. In one example, the first reservoir 122 and the second reservoir 124 may include walls that prevent penetration of the material.

In one embodiment, the first reservoir 122 comprises a sorption element in which either source of nicotine or an organic acid source is sorbed, and the second reservoir 124 is the other of the nicotine source or the organic acid source. The source may comprise a sorbed sorption element. In one example, the sorption element may be a porous sorption element. In one example, the sorption element is glass, stainless steel, aluminum, polyethylene (PE), polypropylene, polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polytetrafluoroethylene (PTFE), expanded polytetra Fluoroethylene (ePTFE) and the like. In one example, the sorption element may comprise a sponge.

In one embodiment, the cartridge 120 includes at least one air inlet 1221, 1242, through which at least one air inlet 1221, 1242 air outside of the cartridge 120 is introduced into the cartridge 120. Can enter inside. The cartridge 120 includes at least one air outlet 1201, and the air inside the cartridge 120 may flow out of the cartridge 120 through the at least one air outlet 1201. While the air inside the cartridge 120 flows out of the cartridge 120, the material of the source included in the first reservoir 122 and the material of the source included in the second reservoir 124, or a reaction thereof. The aerosol formed by it may exit the cartridge 120 together with the air.

In one embodiment, the size of the at least one or more air inlets 1221 and 1242 and the position formed in the cartridge 120 may be appropriately set according to the optimum aerosol formation conditions.

The first air inlet 1221 of the cartridge 120 is in fluid communication with the first reservoir 122 such that air outside the cartridge 120 flows into the cartridge 120 via the first reservoir 122. Can be. The air inlet 1242 of the cartridge 120 may be in fluid communication with the second reservoir 124 such that air outside the cartridge 120 flows into the cartridge 120 via the second reservoir 124. . The cartridge 120 may include an air outlet 1243 in fluid communication with the interior of the cartridge 120.

In one embodiment, the first reservoir 122 may be disposed behind the flow generator 130 and the second reservoir 124 may be disposed in front of the flow generator 130. In one example, the air inlet 1221 in fluid communication with the first reservoir 122 is located behind the cartridge 120, and the air inlet 1242 in fluid communication with the second reservoir 124 is located in the cartridge 120. It can be located on the side.

The flow generator 130 may deliver the material of the source included in the first reservoir 122 and the material of the source included in the second reservoir 124 to the oral cavity of the user. In one example, the flow generator 130 may be disposed inside the cartridge 120. The flow generator 130 may generate a flow of the material of the source included in the first reservoir 122 and the material of the source included in the second reservoir 124 as a flow path through which air flows. In an example not shown, the flow generator 130 may be installed outside of the cartridge 120.

In one embodiment, the flow generator 130 has a rotation axis and can rotate about the rotation axis. The flow generator 130 may be configured to couple with the drive shaft of the driver 1123. In one example, the flow generator 130 may include a propeller. In this case, the flow generator 130 may rotate about the axis of rotation independently of the cartridge 120.

In one embodiment, the speed at which the flow generator 130 rotates may be appropriately adjusted according to the flow of flowing air, the pressure inside the cartridge 120.

In one embodiment, when the flow generator 130 is operated, the pressure inside the cartridge 120 may be lower than the pressure inside the cartridge 120 before the flow generator 130 is operated. As a result, a flow path through which air outside the cartridge 120 flows into the cartridge 120 is formed. In this process, air outside the cartridge 120 may be in fluid communication with the first reservoir 122, the air inlet 1242 in fluid communication with the second reservoir 124, and the cartridge 120. The air outlet 1243 in fluid communication with the interior may be introduced into the cartridge 120. As a result, when the flow generator 130 is operated, the nicotine-related material of the nicotine source and the organic acid material of the organic acid source in the first reservoir 122 and the second reservoir 124 are less than before the flow generator 130 is operated. As it is purged by the introduced air, it promotes the transition of nicotine-related substances and organic acid substances into the gas phase. When the nicotine-related substance and the organic acid substance are in gaseous state, the possibility that the nicotine-related substance and the organic acid substance may react to form an aerosol may increase.

In one embodiment, a second reservoir 124 including a source disposed in front of the flow generator 130 may guide the flow generated by the flow generator 130. The second reservoir 124 can include a streamlined wall 1241 having a profile for guiding the flow generated by the flow generator 130. In one example, the streamlined wall 1241 may have a profile that curves from the side of the cartridge 120 toward the center of the cartridge 120.

3 is an operation diagram schematically showing the operation of the aerosol inhaler according to the first embodiment.

Referring to FIG. 3, when the user operates the aerosol inhaler 100 and starts a puff through the mouthpiece 1141, the operation of the flow generator 130 and the exterior of the housing 110 by the user's puff. Air enters the inside of the housing 110.

Air outside the housing 110 enters the interior of the housing 110 through a first air inlet 1121 located behind the first portion 112 of the housing 110 and then along the passage 1124. The air inlet 1221 located at the rear of the cartridge 120 may enter the inside of the cartridge 120. In this process, the vaporized material in the first reservoir 122 moves to the front of the cartridge 120 together with the air passing through the first reservoir 122.

Meanwhile, air outside the housing 110 may flow into the housing 110 through the second air inlet 1125 positioned at the side of the first portion 112 of the housing 110. Air introduced into the housing 110 through the second air inlet 1125 is introduced into the cartridge 120 through the air inlet 1242 located on the side of the cartridge 120 along the outer wall of the cartridge 120. You can enter. In this process, the vaporized material in the second reservoir 124 moves forward of the cartridge 120 together with the air passing through the second reservoir 124 through the air outlet 1243 of the second reservoir 124. .

Nicotine-related material and organic acid material may be mixed in front of the cartridge 120 by the flow generated by the flow generator 130. An aerosol is formed by mixing nicotine-related substances with organic acid substances. The formed aerosol exits the cartridge 120 through at least one air outlet 1201 located in front of the cartridge 120 and is delivered to the mouth of the user via the mouthpiece 1141.

4 is a sectional view schematically showing the cartridge and the flow generator according to the second embodiment.

Referring to FIG. 4, FIG. 4 shows a cartridge 220 and a flow generator 230 according to one embodiment. The cartridge 220 includes a first reservoir 222 and a second reservoir 224, the first reservoir 222 includes a source of any one of a nicotine source and an organic acid source, and the second reservoir 224 A source of nicotine and the other of the organic acid source.

In one embodiment, the first reservoir 222 and the second reservoir 224 may be disposed behind the flow generator 230. The cartridge 220 is provided with a first air inlet 2221 located at the rear of the cartridge 220 such that the material of the first reservoir 222 and the material of the second reservoir 224 are in fluid communication with the air outside the cartridge 220. ) And a second air inlet 2221. The air outside the cartridge 220 passes through the first air inlet 2221 and the second air inlet 2221, and via the first reservoir 222 and the second reservoir 224, respectively. You can enter inside of. In this process, the material of the source included in the first reservoir 222 and the material of the source included in the second reservoir 224 are mixed inside the cartridge 220 to form an aerosol, and then the cartridge together with the air ( The cartridge 220 may exit through the air outlet 2202 located in front of the 220. In one example, the first reservoir 222 and the second reservoir 224 may be disposed in parallel around the flow generator 230.

In one embodiment, the cartridge 220 may include an additional air outlet 2201 through which external air directly flows from the exterior of the cartridge 220 to the interior of the cartridge 220. Air entering the interior of the cartridge 220 through the additional air outlet 2201 may force an aerosol formed in the interior of the cartridge 220 to flow out of the cartridge 220.

5 is a cross-sectional view schematically showing an aerosol inhaler according to a third embodiment, and FIG. 6 is a cross-sectional view schematically showing a housing and a flow generator according to a third embodiment.

5 and 6, the aerosol inhaler 300 according to an embodiment may include a base 310, a housing 320, a mouthpiece 330, and a flow generator 340.

The base 310 may include a power source 312 and a driver 314.

The housing 320 may include a body 321, a first storage 322, a second storage 323, and a switch 324. Here, the switch 324 is electrically connected to the power source 312. When the user operates the switch 324, the flow generator 340 may operate while power is transferred from the power supply 312 to the driver 314.

The body 321 may connect the base 310 and the mouthpiece 330 to protect the first storage 322 and the second storage 323 from outside air. The body 321 may include a closed space in which external air is blocked and an open space in which external air is allowed to flow and in fluid communication with the mouthpiece 330. The body 321 may include an air inlet 3211 to allow inflow of external air into the open space. The open space may be in fluid communication with the outside of the housing 320 such that air outside the housing 320 enters the open space inside the housing 320 through the air inlet 3211. In one example, the air inlet 3211 may be located on the side of the body 321. On the other hand, the closed space is in fluid communication with the outside of the housing 320 is blocked. Accordingly, the internal pressure of the closed space can be kept lower than the internal pressure of the open space. In a preferred example, the closed space can be kept in a vacuum.

In one embodiment, the size of the air inlet 3211 and the position where the air inlet 3211 is formed in the body 321 may be appropriately set according to the optimum aerosol formation conditions.

In one embodiment, the first reservoir 322 and the second reservoir 323 are disposed in a confined space. Here, the first reservoir 322 includes a source of any one of a nicotine source and an organic acid source, and the second reservoir 323 includes another source of a nicotine source and an organic acid source. In a preferred example, the internal pressure of the enclosed space may be appropriately set in consideration of the vapor pressure of the nicotine related material of the nicotine source and the vapor pressure of the organic acid material of the organic acid source. Nicotine-related substances and organic acid substances vaporize into the enclosed space from the nicotine source and the organic acid source disposed in the enclosed space. The enclosed space and the open space are configured to be in fluid communication. Thus, nicotine-related substances and organic acid substances vaporized into the enclosed space can move into the open space. Nicotine-related substances and organic acid substances that have moved to the open space may mix and react with each other to form an aerosol.

In one embodiment, the base 310 may include a switch 316. The switch 316 may include a cover 3151 hinged to the power source 312 and / or the driver 314 of the base 310. The cover 3151 may be configured to seal the first reservoir 322 and the second reservoir 323 with respect to the outside in a sealed space of the housing 320.

The mouthpiece 330 may include a mouthpiece body 331, an air outlet 332, and a coupler 333. The mouthpiece body 331 may have a shape suitable for insertion into the mouth of a user. The air outlet 332 is configured to be in fluid communication with the mouth of the user, and the aerosol formed in the open space is delivered to the mouth of the user through the air outlet 332. Coupler 333 may be formed at the end of the mouthpiece body 331 opposite the air outlet 332. The housing 320 and the mouthpiece 330 may be coupled to each other through the coupler 333.

The flow generator 340 is configured to generate a flow from the sealed space to the mouthpiece 330 via the open space from the nicotine-related material of the nicotine source disposed in the sealed space and the organic acid material of the organic acid source disposed in the sealed space. Can be. In one example, the flow generator 340 may be disposed inside the housing 320.

In one embodiment, the open space is located in front of the flow generator 340 relative to the flow generator 340 and may be defined by at least a portion of the housing 320 and at least a portion of the mouthpiece 330. On the other hand, the sealed space is defined by at least a portion of the housing 320, it may be located behind the flow generator 340 relative to the flow generator 340.

In one embodiment, the internal pressure of the sealed space after the flow generator 340 is operated may be lower than the internal pressure of the sealed space before the flow generator 340 is operated. When the flow generator 340 is operated, flow is generated from the sealed space to the open space, so that the decompression of the sealed space is performed. Thereby, vaporization of the nicotine-related substance of the nicotine source and the organic acid substance of the organic acid source disposed in the closed space is promoted.

In one embodiment, the flow generator 340 facilitates vaporization of nicotine-related materials and organic acid materials, guides nicotine-related materials and organic acid materials vaporized from an enclosed space to an open space, mixes nicotine-related materials and organic acid materials, and It may include a structure to promote the reaction.

In one embodiment, the flow generator 340 has an axis of rotation and can be configured to rotate about the axis of rotation. The speed at which the flow generator 340 rotates may be appropriately adjusted according to the flow of flowing air, the pressure inside the closed space and the open space.

Flow generator 340 may include a shaft 341 and wings 342 having a rotational axis. The shaft 341 is configured to be coupled to the driving shaft 3141 of the driver 314 and may rotate together with the driving shaft 3141 according to the rotation of the driving shaft 3141. The wing 342 may be connected to the shaft 341 to rotate about the axis of rotation with the shaft 341. The wing 342 may extend along the axial direction of the axis of rotation of the shaft 341. Accordingly, a flow path of nicotine-related material and organic acid material is formed in the shaft 341 and the wing 342 to guide the nicotine-related material and the organic acid material from the closed space to the open space. In one example, the wing 342 may have a streamlined profile 341 extending along the axial direction of the axis of rotation of the shaft 341.

Flow generator 340 may further include an additional wing 343 configured to rotate about an axis of rotation. The additional wing 343 may extend from the outside of the housing 320 toward the housing 320 in a direction crossing the axis of rotation of the shaft 341. As the additional wings 343 rotate, aerosols formed by nicotine-related materials, organic acid materials, or reactions thereof may accelerate toward the front of the flow generator 340. In one example, an additional wing 343 may be located in front of the shaft 341. In one example, the additional wing 343 can rotate independently of the wing 342. The rotational speed of the wing 342 and the rotational speed of the additional wing 343 can be controlled independently.

Flow generator 340 may further include an enclosure 344 surrounding the wing 342. The enclosure 344 can rotate with the shaft 341 as the shaft 341 rotates about an axis of rotation. The enclosure 344 may be installed in the housing 320 to be rotatable with respect to the housing 320. Enclosure 344 may have a profile 341 that guides nicotine-related and organic acid materials from the closed space along the profile 341 of the wing 342 to the open space. This creates an additional flow path through which nicotine related materials and organic acid materials flow between the profile 341 and the enclosure 341 of the wing 342. In one example, enclosure 344 can be cylindrical.

In one embodiment, additional wings 343 may be rotatably installed in enclosure 344. Additional wings 343 may extend from the inside of enclosure 344 toward the center of enclosure 344. In one example, shaft 341 and wings 342 may be disposed at the rear of enclosure 344 and additional wings 343 may be disposed at the front of enclosure 344.

In one embodiment, enclosure 344 may include a first zone in which shaft 341 and wings 342 are disposed and a second zone in which additional wings 343 are disposed. Accordingly, nicotine-related materials and organic acid materials move along the profile 341 of the wing 342 and / or the profile 341 of the enclosure 344 without reacting with each other in the first zone, while in the second zone. Can react by mixing.

In one embodiment, the first reservoir 322 and the second reservoir 233 may be separated based on the flow generator 340. Accordingly, the material of the source included in the first reservoir 322 and the material of the source included in the second reservoir 233 may be preserved so as not to react with each other before the operation of the flow generator 340. In one example, the first reservoir 322 and the second reservoir 233 may be disposed in parallel around the axis of rotation of the flow generator 340.

7 is an enlarged view enlarging a portion A of the flow generator according to the third embodiment.

Referring to FIG. 7, the plurality of wings 342 may be spaced apart from each other around the shaft 341 of the flow generator 340 and installed on the shaft 341. Profile 341, which makes up each of the plurality of wings 342, may be configured to form a channel through which material passes. Each end of the plurality of wings 342 may be connected to a shaft 341. In one example, the profile 341 of the wing 342 defines a path through which the material travels around the shaft 341 and in the circumferential direction of the shaft 341, and the rolled shape to surround the path through which the material travels ( rolled shape). Material may flow through at least one or more of the movement paths of the material formed by the profiles 341 of the plurality of wings 342, and the material may flow out through the remaining movement paths of the movement paths of the material. . In one example, the movement path from which the substance flows out of the movement paths of the substance may be a single movement path, and the substance flowing through the remaining movement paths may flow out of the substance along the single movement path. The spilled material may move forward of the flow generator 340.

8 is a cross-sectional view schematically showing an example of a bearing coupled to a housing according to the third embodiment.

Referring to FIG. 8, the flow generator 340 may include a bearing 345. Bearing 345 may be installed between enclosure 344 and body 321 (see FIG. 5). Accordingly, while the enclosure 344 is rotating about the axis of rotation of the shaft 341, the bearing 345 can hold the axis of rotation of the enclosure 344 in a fixed position and support the enclosure 344.

9 is a schematic cross-sectional view of yet another example of a bearing coupled to a housing according to the third embodiment.

Referring to FIG. 9, the flow generator 340 may include a bearing 345 ′. Bearing 345 ′ may be installed at both ends of enclosure 344. Accordingly, while the enclosure 344 rotates about the axis of rotation of the shaft 341, it is possible to limit the movement of the axis of rotation of the enclosure 344 in the axial direction and support the enclosure 344.

In an embodiment not shown, both the bearing 345 of FIG. 8 and the bearing 345 ′ of FIG. 9 may be installed between the body 321 and the enclosure 344 within the housing 320 to support the enclosure 344. Can be.

10 and 11 are cross-sectional views schematically showing an assembly method of the aerosol inhaler according to the third embodiment.

10 and 11, the first reservoir 322, the second reservoir 323, and the mouthpiece 330 may be disposable. Before the user uses the aerosol inhaler 300, the first reservoir 322, the second reservoir 323, and the mouthpiece 330 may be packaged. The user may couple the mouthpiece 330 to the body 321 of the housing 320. In addition, after opening the cover 3151 of the switch 316, the user may arrange the first reservoir 322 and the second reservoir 323 in a sealed space of the housing 320. At this time, the drive shaft 3141 of the driver 314 is decoupled with the shaft 341 of the flow generator 340.

When the first reservoir 322 and the second reservoir 323 are disposed in the sealed space of the housing 320, the user closes the cover 3151 of the switch 316. Accordingly, the first reservoir 322 and the second reservoir 323 is in fluid communication with the outside. When the user pushes the base 310 toward the housing 320, the drive shaft 3141 of the driver 314 may be coupled with the shaft 341 of the flow generator 340.

In one embodiment, the first reservoir 322 includes a first protective barrier 3221 and a first brittle barrier 3222 surrounding the source of either the nicotine source or the organic acid source, and the second reservoir 323. May comprise a second protective barrier 3231 and a second brittle barrier 3322 surrounding the other of the nicotine source and the organic acid source. In addition, the body 321 may include shredding elements 3212 that break the first brittle barrier 3222 and the second brittle barrier 3322, respectively.

The shredding elements 3212 may move relative to the first reservoir 322 and the second reservoir 323. From the state in which the aerosol inhaler 300 decouples the drive shaft 3141 of the driver 314 and the shaft 341 of the flow generator 340, the drive shaft 3141 of the driver 314 is the shaft of the flow generator 340 ( When converted to a coupled state with 341, the shredding elements 3212 can break the first brittle barrier 3222 and the second brittle barrier 3322, respectively. In one example, the shredding elements 3212 may be formed in a tip shape at the end of the wall that forms the body 321.

12 is a schematic cross-sectional view of an aerosol inhaler including a flow barrier and a liquid absorbing element according to a third embodiment.

Referring to FIG. 12, in one embodiment, the aerosol inhaler 300 reduces the direct delivery of the accelerated aerosol to the user's oral cavity and promotes the reaction of unreacted substances of nicotine and organic acids in the open space. It may include a structure to make. Aerosol inhaler 300 may include a flow barrier 350.

When the flow generator 340 is operated, nicotine-related materials and organic acid materials move from the closed space to the open space due to the forced flow generated by the flow generator 340, and the aerosol is mixed with nicotine-related materials and the organic acid materials in the open space. This can be formed. In this process, since the formed aerosol is in an accelerated state, when the aerosol in this state is delivered to the oral cavity of the user, it may harm the user's taste or damage the user's oral cavity or lungs. The flow barrier 350 can guide the accelerated aerosol back to the open space from the open space toward the mouthpiece 330 to slow down the accelerated aerosol. On the other hand, due to the forced flow generated by the flow generator 340, some of the nicotine-related material and / or some of the organic acid material in the open space may not react, the flow barrier 350 of the unreacted nicotine-related material A portion and / or a portion of the organic acid material may be guided back to the open space to induce a portion of the nicotine related material and / or a portion of the organic acid material to react again. In one example, the flow barrier 350 may be disposed in an open space defined by the housing 320 and the mouthpiece 330. In one example, the flow barrier 350 has a shape extending from the inside of the housing 320, the inside of the mouthpiece 330, or toward the open space, curved from between the housing 320 and the mouthpiece 330. can do.

In one embodiment, the aerosol inhaler 330 may include a structure to remove the liquid component contained in the air flowing with the aerosol delivered to the mouth of the user.

The aerosol inhaler 330 can include a liquid component absorbent layer 362. The liquid component absorbing layer 362 may reduce the delivery of the liquid component to the mouth of the user as the size of the liquid component included in the air increases. Here, the liquid component may be an aerosol in the liquid state. In one example, the liquid component absorbing layer 362 may be installed on the inner wall of the mouthpiece 330 along the inner wall of the mouthpiece 330.

Aerosol inhaler 300 may include a filter 364. The filter 364 may remove the liquid component included in the air flowing with the aerosol delivered to the mouth of the user through the mouthpiece 330. In one example, the filter 364 may be installed inside the mouthpiece 330 in bulk form.

Although the embodiments have been described by the limited embodiments and the drawings as described above, various modifications and variations are possible to those skilled in the art from the above description. For example, the described techniques may be performed in a different order than the described method, and / or components of the described systems, structures, devices, circuits, etc. may be combined or combined in a different form than the described method, or other components Or even if replaced or substituted by equivalents, an appropriate result can be achieved.

Claims (15)

An enclosed space in which external air is blocked from entering, an open space in which external air is allowed to enter and configured to be in fluid communication with the enclosed space, and a mouthpiece in fluid communication with the open space,
A nicotine source disposed in the confined space;
An organic acid source disposed in the confined space; And
A flow generator configured to generate flow from the enclosed space to the mouthpiece via the open space;
Including,
At least one source of the nicotine source and the organic acid source is disposed upstream of the flow path relative to the flow generator, and wherein the flow generator is activated to promote vaporization of the at least one source.
The method of claim 1,
An aerosol inhaler wherein the pressure in the confined space after the flow generator is operated is lower than the pressure in the confined space before the flow generator is operated.
The method of claim 1,
The nicotine-related material of the nicotine source and the organic acid material of the organic acid source move from the enclosed space to the open space while the flow generator is in operation, and mixing of the nicotine-related material and the organic acid material occurs in the open space. Aerosol Inhaler.
The method of claim 1,
Wherein said nicotine source and said organic acid source are separated based on said flow generator.
The method of claim 1,
And a flow barrier configured to guide a portion of the materials flowing from the closed space through the open space to the mouthpiece into the open space.
The method of claim 1,
And a liquid absorbing element for removing liquid components contained in the air flowing from the open space to the mouthpiece.
The method of claim 1,
A first reservoir comprising a first brittle barrier surrounding the nicotine source;
A second reservoir comprising a second brittle barrier surrounding the organic acid source; And
Shredding elements that break each of the first and second brittle barriers;
Including,
And the shredding elements are configured to be movable relative to the first reservoir and the second reservoir.
Mouthpiece;
An open space having an air inlet in fluid communication with the mouthpiece and into which outside air is introduced, and a closed space in fluid communication with the open space and blocking the inflow of external air, the nicotine source and an organic acid source; housing; And
A flow generator having a rotation axis, comprising: a flow generator rotatable about the rotation axis and configured to generate a flow from the closed space to the mouthpiece via the open space;
Including,
At least one source of the nicotine source and the organic acid source is disposed upstream of the flow path relative to the flow generator, and wherein the flow generator is activated to promote vaporization of the at least one source.
The method of claim 8,
The flow generator includes a wing configured to rotate about the axis of rotation, the wing extending along the axial direction of the axis of rotation and the nicotine-related material of the nicotine source and the organic acid of the organic acid source from the closed space to the open space. An aerosol inhaler having a profile for guiding the substance.
The method of claim 9,
The flow generator further comprises an additional wing configured to rotate about the axis of rotation, wherein the additional wing extends from the outside of the housing toward the center of the housing in a direction crossing the axis of rotation.
The method of claim 9,
The flow generator further comprises an enclosure surrounding the wing,
The enclosure of the flow generator having a profile for guiding nicotine-related material of the nicotine source and organic acid material of the organic acid source along the profile of the wing from the confined space to the open space.
A smoking article cartridge having an air inlet and an air outlet,
Nicotine source;
Organic acid sources; And
A flow generator configured to generate a flow of nicotine-related material of the nicotine source and organic acid material of the organic acid source in a flow path through which air flows from the air inlet to the air outlet;
Including,
The nicotine source and the organic acid source are disposed on the flow path,
At least one source of the nicotine source and the organic acid source is disposed upstream of the flow path relative to the flow generator, and wherein the flow generator is activated to facilitate vaporization of the at least one source.
The method of claim 12,
A source of either the nicotine source or the organic acid source is disposed at the rear of the flow generator and the other source is disposed at the front of the flow generator.
The method of claim 13,
A reservoir comprising a source disposed in front of said flow generator, said reservoir having a profile for guiding the flow generated by said flow generator.
The method of claim 12,
Wherein said nicotine source and said organic acid source are disposed behind said flow generator.

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