RU2808406C1 - Aerosol generating device - Google Patents

Abstract

FIELD: aerosol generating device.

SUBSTANCE: aerosol generating device comprises an elongated container consisting of an inner wall and an outer wall, in which the inner wall defines an insertion space configured to accommodate an aerosol generating element, in which a chamber configured to store liquid is defined between the inner wall and the outer wall; a wick located at the end of the insertion space; a heater configured to heat the wick; a passage formed between the insertion space and the wick; and an infrared sensor located adjacent to the insertion space.

EFFECT: aerosol generating device is proposed.

11 cl, 22 dwg

Description

Field of technology

The present invention relates to a device for generating an aerosol.

Prior Art

An aerosol generating device is a device that extracts certain components from a medium or substrate by generating an aerosol. The medium may contain a multicomponent substrate. The substrate contained in the medium may be a multi-component flavoring agent. For example, the substrate contained in the medium may contain a nicotine component, a plant component, and/or a coffee component. Recently, various studies have been carried out on aerosol generating devices.

The essence of the invention

Technical problem

The objective of the present invention is to develop a device for generating an aerosol, characterized by increased efficiency in the use of space, configured to store liquid therein.

Another object of the present invention is to provide an aerosol generating apparatus in which a wick and a heater are located close to the stick to improve the heat transfer efficiency of the aerosol.

It is a further object of the present invention to provide an aerosol generating apparatus having an enlarged liquid storage space and a space located on the outer surface of the liquid storage space in which various components such as a sensor are housed and is easy to be grasped by a user.

It is a further object of the present invention to provide an aerosol generating device capable of detecting the state of a stick without entering the space in which the stick is inserted or without interfering with the insertion process of the stick.

Technical solution

According to a first aspect of the present invention, to solve the above and other objects, there is provided an aerosol generating device comprising an elongated container consisting of an inner wall and an outer wall, wherein the inner wall defines an insertion space configured to accommodate an aerosol generating element, in which a chamber , configured to store liquid, is defined between the inner wall and the outer wall; a wick located at the end of the insertion space; a heater configured to heat the wick; a passage formed between the insertion space and the wick; and an infrared sensor located adjacent to the insertion space.

Beneficial effects of the invention

In at least one embodiment of the present invention, it is possible to provide an aerosol generating device configured to insert a stick into a container containing a chamber configured to store liquid, thereby increasing the efficiency of use of the space configured to store liquid.

In addition, according to at least one embodiment of the present invention, it is possible to provide an aerosol generating device configured to reduce the distance between a heater configured to heat a wick connected to a chamber in which a liquid is stored to generate an aerosol, and stick to thereby reduce the distance traveled by the aerosol, thereby increasing the efficiency of heat transfer for aerosol formation.

Moreover, in at least one embodiment of the present invention, in the aerosol generating apparatus, preferably the container containing the liquid storage chamber has variously shaped external surfaces to form spaces in which various components are housed to increase storage space liquid and ease of grip of the device by the user.

Moreover, in at least one embodiment of the present invention, in the aerosol generating device, the sensor is preferably located outside the container, that is, does not enter the insertion space into which the stick is inserted and does not interfere with the insertion of the stick, and light penetrates into the camera and is reflected, allowing you to determine the state of the stick based on the value recognized by the sensor.

Additional embodiments of the present invention will become apparent from the following detailed description. However, while various changes and modifications will be readily apparent to those skilled in the art without departing from the spirit and scope of the present invention, it is to be understood that the detailed description and specific embodiments, including preferred embodiments, of the present invention are given by way of example only. .

Description of drawings

The above and other objects, features and other advantages of the present invention will be better understood from the following description of the invention with reference to the accompanying drawings, in which:

In FIG. 1-22 are views illustrating an aerosol generating apparatus according to one embodiment of the present invention.

Best Mode for Carrying Out the Invention

The following will be a detailed description in accordance with the illustrative embodiments of the present invention disclosed herein with reference to the accompanying drawings. For brevity of description with reference to the drawings, the same or equivalent components have the same reference numerals and their description will not be repeated.

In general, names such as "module" and "block" can be used to refer to elements or components. The use of such names in this document is intended only to facilitate the description of characteristics, and these names do not have any special meaning or function.

In the present description, those details that are well known to those skilled in the art have generally been omitted for the sake of brevity. The accompanying drawings are used to facilitate understanding of various technical features, and it should be understood that the embodiments of the invention presented herein are not limited to the accompanying drawings. Therefore, the present specification should be considered to cover any modifications, equivalents and substitutes in addition to those shown in the accompanying drawings.

It should also be understood that although the terms "first", "second", etc. may be used to describe various elements, the elements described may not be limited to these terms. These terms are used solely to distinguish one element from another.

It should be understood that when an element is referred to as being "connected to" another element, intermediate elements may be present. In contrast, it should be understood that when an element is referred to as being “directly related to” another element, there are no intervening elements.

A singular representation may contain a plural representation unless the context clearly indicates otherwise.

Further, the directions of the aerosol generating device can be determined based on the orthogonal coordinate system shown in FIG. 1-10. In an orthogonal coordinate system, the x-axis direction can be defined as the left and right directions of the aerosol generating device. Herein, based on the origin, the +x-axis direction may be the right direction, and the -x-axis direction may be the left direction. In addition, the y-axis direction can be defined as the up and down directions of the aerosol generating device. Herein, based on the origin, the +y-axis direction may be an upward direction and the -y-axis direction may be a downward direction.

As shown in FIG. 1, the container 10 may be configured to extend vertically. The container 10 may be hollow. The container 10 may be in the form of a cylinder extending vertically.

Container 10 may include an outer wall 11 and an inner wall 12. The outer wall 11 may extend vertically. The outer wall 11 may extend along the outer surface of the container 10. The outer wall 11 may extend circumferentially so as to have a cylindrical shape. The container 10 can extend in a longitudinal direction. Therefore, the "longitudinal direction" of the container 10 may be understood to mean the direction in which the container 10 runs. The longitudinal direction of the container 10 may be vertical.

The inner wall 12 may extend vertically. The inner wall 12 may extend along the inner surface of the container 10. The inner wall 12 may extend circumferentially so as to have a cylindrical shape.

The inner wall 12 may be spaced inwardly from the outer wall 11. The inner wall 12 may be spaced radially inward from the outer wall 11. The outer wall 11 and the inner wall 12 may be connected to each other at their tops.

The chamber 101 may be defined between the outer wall 11 and the inner wall 12. The chamber 101 may extend vertically. The chamber 101 may extend circumferentially along the outer wall 11 and the inner wall 12. The chamber 101 may have a cylindrical shape. The chamber 101 may store liquid.

The passage 20 may be provided in the inner and lower portion of the inner wall 12. Intake air may flow through the passage 20.

The wick 31 may be coupled to the interior of the chamber 101. The wick 31 may absorb liquid contained in the chamber 101. The wick 31 may be located adjacent one end of the space 102 for insertion in the longitudinal direction of the container 10.

Stick 40 can be passed vertically. Stick 40 may have a cylindrical shape. Stick 40 may be inserted into container 10. Stick 40 may be inserted into inner wall 12 of container 10. Aerosol generated at wick 31 may be transferred to stick 40 through passage 20. Stick 40 may be referred to as aerosol generating element 40.

Therefore, the chamber in the container 10 in which the liquid is stored may surround the stick 40 to improve the efficiency of the liquid storage space.

Accordingly, since the distance between the wick 31 connected to the chamber 101 or the heater 32 (see FIG. 2) configured to heat the liquid to generate an aerosol and the stick 40 is reduced, the efficiency of heat transfer to the aerosol can be improved.

The main body 50 may extend vertically. The main body 50 may be hollow in shape. The main body 50 may be in the form of a cylinder extending vertically.

The container 10 and the main body 50 can be connected to each other. The container 10 may be located above the main body 50. The container 10 may be detachably connected to the main body 50. The container 10 and the main body 50 may form a continuous surface.

The controller 50 may be located within the main body 50. The controller 50 may activate and deactivate the aerosol generating device. The controller 51 may be electrically coupled to the heater 32 (see FIG. 2) so as to control the supply of power to the heater 32 to heat the wick 31. The controller 51 may be located below the heater 32. The controller 51 may be located adjacent to the heater 32.

The battery 52 may be located within the main body 50. The battery 52 may supply power to the aerosol generating device. Battery 52 may be electrically coupled to controller 51 and/or terminal 53. Battery 52 may be located below controller 51. Battery 52 may extend vertically.

Terminal 53 may be located at the end of the main body 50. Terminal 53 may be electrically coupled to an external power source to receive and transmit power to the battery 52. Terminal 53 may be located at the bottom of the main body 50. Terminal 53 may be located below the battery 52. .

As shown in FIG. 2, the inner wall 12 may extend circumferentially and vertically so as to create an insertion space 102 inside. The insertion space 102 can be formed by opening the upper and lower ends of the inner portion of the inner wall 12. A stick 40 (see FIG. 1) can be inserted into the insertion space 102. An inner wall 12 may be located between the chamber 101 and the insertion space 102. The inner wall 12 may define an insertion space.

The insertion space 102 may be shaped to correspond to a portion of the stick 40 inserted into the insertion space 102. The insertion space 102 may extend vertically. The insertion space 102 may be cylindrical in shape. When stick 40 is inserted into insertion space 102, stick 40 may be surrounded by inner wall 12 and in close contact with the inner wall.

The outer wall 11 and the inner wall 12 may be connected to each other through the top 15 of the container 10. The chamber 101 may be formed by the outer wall 11, the inner wall 12, the top 15 and the bottom 16 of the container 10.

The wick 31 may be located below the insertion space 102. The wick 31 may be located below the passage 20. The wick 31 may be connected to the chamber 101 to absorb liquid stored in the chamber 101. The wick 31 may be located between the inner wall 12 and the bottom 16 of the container 10. The wick 31 may extend in one direction . The wick 31 may be oriented horizontally.

Heater 32 may be located around wick 31. Heater 32 may be wound around wick 31 in a direction in which wick 31 extends. Heater 32 may heat the wick. The heater 32 can generate an aerosol from the liquid absorbed by the wick 31 by heating with electrical resistance. Heater 32 may be coupled to controller 51 (see FIG. 1) to control power supply thereto.

A passage 20 may be formed between the injection space 102 and the wick 31. The aerosol generated at the wick 31 may be supplied to the injection space 102 through the passage 20. The passage 20 may be configured to narrow and then widen in the direction of movement of the aerosol . The direction of movement of the aerosol can be oriented upward.

The passage 20 may be surrounded by an upper passage wall 220 projecting inwardly from the inner wall 12. The upper portion of the passage 20 may be surrounded by an upper passage wall 220, and the lower portion of the passage 20 may be surrounded by a lower passage wall 210. The lower passage wall 210 may be connected to the bottom of the upper passage wall 220. The wick 31 may be located between the bottom wall 210 of the passage and the bottom 16 of the container 10.

As shown in FIG. 3, passage 20 may be divided into a first passage 21, a second passage 22, and a third passage 23.

The first passage 21 may be located adjacent to the wick 31. The first passage 21 may be located above the wick 31. The second passage 22 may be located adjacent to the insertion space 102. The second passage 22 may be connected to the insertion space 102.

The third passage 23 may be located between the first passage 21 and the second passage 22. The third passage 23 may be located above the first passage 21. The second passage 22 may be located above the third passage 23. The third passage 23 may be connected to the first passage 21 by a second passage 22.

The width W3 of the third passage 23 may be smaller than the width W1 of the first passage 21. The width W3 of the third passage 23 may be less than the width W2 of the second passage 22. The maximum width of the first passage 21 and the maximum width W2 of the second passage 22 may be equal or nearly equal to each other. The maximum width W1 of the first passage 21 may be greater than the maximum width W2 of the second passage 22. The width W2 of the second passage 22 may be less than the width W0 of the insertion space 102.

The passage 20 may narrow towards the third passage 23 from the first passage 21. The passage 20 may widen towards the second passage 22 from the third passage 23. The width W2 of the second passage 22 may gradually increase towards the insertion space 102.

As a result, the aerosol can be collected in the third passage 23, which has a small width, from the first passage 21, and can then be sprayed through the second passage 22. Accordingly, even if the aerosol is not generated uniformly on the wick 31, the aerosol can be uniformly introduced through the bottom of the stick 40 (See FIGS. 1 and 6).

The width W1 of the first passage 21 may decrease towards the third passage 23. The width W2 of the second passage 22 may decrease towards the third passage 23.

The slope with which the width W1 of the first passage 21 decreases in the direction of the third passage 23 may be less than the slope with which the width W2 of the second passage 22 decreases in the direction of the third passage 23. The distance L1 between the maximum width W1 of the first passage 21 and the width W3 of the third passage 23 may be less than the distance L2 between the maximum width W2 of the second passage 22 and the width W3 of the third passage 23. In other words, the change in width relative to length may be greater in the direction towards the third passage 23 from the first passage 21 than in the direction towards the third passage 23 from the second pass 22.

If we assume that the horizontal width of the first passage 21 is equal to W1, the horizontal width of the second passage 22 is equal to W2, the horizontal width of the third passage 23 is equal to W3, the vertical length of the first passage 21 is equal to L1 and the vertical length of the second passage 22 is equal to L2, then we can derive the equation (W1-W3)/(L1) > (W2-W3)/(L2) relating these variables.

The vertical length L1 of the first pass 21 may be less than the vertical length L2 of the second pass 22 (L1 < L2).

Accordingly, a space can be created to direct the atomized liquid to the third passage 23 if the length of the first passage 21 is shortened, and the aerosol that accumulates in the third passage 23 can flow through the second passage 22 into the injection space 102 while being uniformly atomized (see Fig. FIGURE 6).

The vertical length of the third passage 23 may be less than the vertical length L1 of the first passage 21. The vertical length of the third passage 23 may be less than the vertical length L2 of the second passage 22.

The second passage 22 may be configured such that its horizontal width W2 gradually increases toward the insertion space 102 and subsequently remains substantially constant from the point of maximum width W2 toward the insertion space 102 .

The first passage 21 may be surrounded by a first passage surface 211. The second passage 22 may be surrounded by a second passage surface 221. The third passage 23 may be surrounded by a third passage surface 231.

The first passage surface 211 may define the interior surface of the bottom passage wall 210. The second passage surface 221 and the third passage surface 231 may define the inner surface of the upper passage wall 220.

The first pass surface 211 and the third pass surface 231 may be separate from each other rather than forming a continuous surface. The first pass surface 211 may be circumferential. The first pass surface 211 may be in the shape of a ring.

The first passage 21 may extend toward the third passage 23 while having a substantially constant width W1, and may gradually narrow to the width W3 of the third passage 23 in the region of the third passage 23.

Therefore, since the space in the first passage 21 is formed between the first passage surface 211 and the wick 31, the aerosol can be efficiently generated and easily pass into the portion between the first passage surface 211 and the wick 31.

The third pass surface 231 and the second pass surface 221 may form a continuous surface. The third passage surface 231 may extend vertically. The third passage surface 231 may extend circumferentially. The third passage surface 231 may be shaped like a ring.

The second passage surface 221 may include a portion that extends toward the insertion space 102 while gradually expanding radially outward. The second passage surface 221 may include a portion that slopes radially outward toward the insertion space 102. The second passage surface 221 may include a portion that extends toward the insertion space 102 while gradually expanding radially outward. The second passage surface 221 may be configured to be shaped to approximate the shape of a funnel or venturi.

The second passage surface 221 may extend to the insertion space 102 from the third passage surface 231 while gradually expanding outward, and may then extend to the insertion space 102 from a point of maximum width W2 while maintaining said width W2 substantially constant.

The second passage surface 221 may include a portion that extends toward the insertion space 102 while being curved outward. The second passage surface 221 may extend upward from the third passage surface 231 while being curved outward in a radial direction.

Consequently, the flow resistance may decrease as the aerosol is sprayed in the direction of the second passage 22 from the third passage 23.

The width W2 of the second passage 22 may be larger at the upper end of the second passage 22, which interfaces with the lower end of the insertion space 102. The width W2 of the upper end of the second passage 22 may be smaller than the width W0 of the insertion space 102.

The shoulder surface 17 may be located at the lower end of the insertion space 102 and the upper end of the second passage 22. The shoulder surface 17 may project inwardly from the inner wall 12 of the container 10. The shoulder surface 17 may serve as a support for the lower end surface of the stick 40. Surface 17 with a ledge can protrude inward and can determine the maximum width W2 of the second pass 22.

The stepped surface 17 may define an upper surface of the upper passage wall 220 that projects inwardly from the inner wall 12. The stepped surface 17 may extend substantially perpendicular to the inner surface 121 of the inner wall 12. The stepped surface 17 and the inner surface 121 may face the space 102 for introduction. The second passage surface 221 may extend downward from the stepped surface 17.

The protrusion length L3 of the shoulder surface 17 may preferably be determined such that the shoulder surface 17 supports the lower end of the stick 40 (see FIG. 1) and to minimize resistance to aerosol flow.

The wick 31 may be positioned to extend in a transverse direction of the first passage 21, and the heater 32 may be wrapped around the wick 31 in the direction in which the wick 31 extends.

The width W1 of the first passage 21 may be greater than the width W4 of the heater 32. The width W3 of the third passage 23 may be less than the width W4 of the heater 32. If the container 10 extends vertically, the lateral direction of the passage 20 may be a right-to-left direction.

Accordingly, even when a deviation in the amount of aerosol occurs in the aerosol generating portion of the wick 31, when the heater 32 heats the liquid absorbed by the wick 31 to generate an aerosol, the aerosol can be collected in the third passage 23 and can be uniformly sprayed toward the injection space 102 from the second passage 22.

As shown in FIG. 3 and 4, the first curved zone 222 and the second curved zone 223 formed on the second passage surface 221 may have a concave shape.

The first curved zone 222 may be formed at the bottom of the second passage surface 221. The first curved zone 222 may be formed adjacent the third passage 23. The first curved zone 222 may be curved to form a convexity towards the interior of the container 10 from the surface 231 of the third passage.

A second curved zone 223 may be formed at the top of the second passage surface 221. A second curved zone 223 may be formed adjacent the insertion space 102. The second curved zone 223 may be curved to form a convexity in the outward direction of the container 10 from the first curved zone 222. The second curved zone 223 may be curved to form a convexity in the outward direction of the container 10 and may include a portion adjacent the insertion space 102 and flared toward the insertion space 102 while maintaining a substantially constant width.

Therefore, the aerosol can be sprayed outward along the first curved zone 222 of the second passage surface 221, and can be introduced directly into the injection space 102 along the second curved zone 223 of the second passage surface 221 (see FIG. 6).

Accordingly, it is possible to reduce the resistance to the flow of aerosol sprayed into the second passage 22 from the third passage 23.

An upper passage wall 220 may extend downward from the inner wall 12. An upper passage wall 220 may extend inwardly from the inner wall 12. A second passage surface 221 and a third passage surface 231 may define an interior surface of the upper passage wall 220.

The lower passage wall 210 may be connected to the bottom of the upper passage wall 220. The first passage surface 211 may define the interior surface of the bottom passage wall 210.

A groove 226 may be provided at the bottom of the upper wall 220 of the passage. The groove 226 may be formed in an upward direction as a recess at the bottom of the upper wall 220 of the passage.

The insertion portion 216 may be formed on the top of the lower passage wall 210. An insertion portion 216 may be formed above the first passage surface 211.

The insertion portion 216 may be configured as an upward projection from the top of the bottom wall 210 of the passage. The insertion portion 216 may be inserted into the groove 226 so as to be in close contact therewith. When the insertion portion 216 is inserted into the groove 226, the upper passage wall 220 and the lower passage wall 210 can be connected to each other. The lower passage wall 210 may be releasably connected to the lower portion of the upper passage wall 220.

The bottom passage wall 210 may define the width W1 (see FIG. 3) of the first passage 21. The width W1 of the first passage 21 may vary depending on the degree of recess in the first passage surface 211 defining the inner surface of the bottom passage wall 210, in the right and left directions. .

The closer to the axis the first passage surface 211 of the bottom passage wall 210 is made, the smaller the width W1 of the first passage 21. The farther from the axis the first passage surface 211 of the bottom passage wall 210 is made, the larger the width W1 of the first passage 21. Accordingly, the width W1 of the first passage 21 may be defined or modified by inserting a bottom passage wall 210 having a certain size into the top passage wall 220.

As a result, the area of the wick 31 on which the liquid is sprayed can be determined by changing the length W1 of the portion of the wick 31 (see FIG. 3) located in the first pass 21 and the width W4 of the portion of the heater 32 (see FIG. 3) wound around the wick 31.

The first pass surface 211 may extend vertically. The first pass surface 211 may be formed substantially perpendicular to the wick 31. The first pass surface 211 may determine the length L1 of the first pass 21.

The expanded surface 212 may be a portion of the interior surface of the upper passage wall 220 and a portion of the interior surface of the bottom passage wall 210 . An expanded surface 212 may be formed between the first pass surface 211 and the third pass surface 231.

The expanded surface 212 may be connected to the upper end of the first pass surface 211. The expanded surface 212 may be connected to the lower end of the third passage surface 231. The expanded surface 212 may extend horizontally from the upper end of the first pass surface 211. The expanded surface 212 may extend horizontally from the lower end of the third passage surface 231.

The flared surface 212 may be located some distance upward from the wick 31. The flared surface 212 may be oriented in the transverse direction of the first passage 21. The flared surface 212 may extend toward the third passage 23 from the upper end of the first passage surface 211. The expanded surface 212 may connect the first pass surface 211 to the third pass surface 231. The elongated surface 212 may be located some distance from the wick 31 and may face the wick 31.

The distance between the flared surface 212 and the wick 31 may be substantially equal to the height L1 of the first passage 21. The flared surface 212 may face the wick 31, with the first passage 21 located between them. The flared surface 212 may be oriented substantially parallel to the wick 31. surface 212 may be formed substantially perpendicular to first pass surface 211. The expanded surface 212 may be formed substantially perpendicular to the third passage surface 231.

The end of the first pass 21 may be surrounded by a first pass surface 211, a wick 31, and an expanded surface 212. The aerosol sprayed at the end of the wick 31 may stagnate at the end of the first pass 21.

Accordingly, a collection space for the aerosol sprayed at the end of the wick 31 can be formed, and a suction force can be easily applied to the end of the wick 31.

Here, since turbulent flow occurs at the end of the first pass 21 by the aerosol sprayed at the end of the wick 31, it is possible to mix the aerosol evenly even when the amount of aerosol in the aerosol generating portion of the wick 31 changes (see FIG. 6).

A first edge portion 213 may be formed between the first pass surface 211 and the expanded surface 212. The first edge portion 213 may be adjacent to an edge portion of the upper end of the first pass 21. The first edge portion 213 may extend toward the expanded surface 212 from the first pass surface 211, with wrapping this up.

A second edge portion 214 may be formed between the expanded surface 212 and the third passage surface 231. A second edge portion 214 may be formed between the first passage 21 and the third passage 23. The second edge portion 214 may extend toward the third passage surface from the expanded surface 212, with wrapping this up.

Therefore, it is possible to reduce the resistance to the flow of aerosol sprayed into the third passage 23 from the first passage 21.

The wick insertion surface 215 may define a lower end of the lower passage wall 210. The wick insertion surface 215 may extend in the transverse direction of the first passage 21. The wick insertion surface 215 may define an opening corresponding to the shape of the end of the wick 31, so that the wick 31 is inserted into the opening. The wick insertion surface 215 may be connected to the first pass surface 211.

The wick 31 may be inserted between the wick insertion surface 215 and the bottom 16 of the container 10. When the wick 31 is inserted, the wick insertion surface 215 may be in direct contact with the upper end of the wick 31. The wick insertion surface 215 may be in close contact with wick 31, thereby preventing liquid from flowing out.

As shown in FIG. 5, the upper passage wall 220 (see FIG. 4) and the lower passage wall 210 (see FIG. 4), which were described above, may not be connected to each other, but integrated so as to form the passage wall 220a. The passage wall 220a may have substantially the same shape as the combination body, in which the upper passage wall 220 is connected to the bottom passage wall 210.

Therefore, the step of connecting the components to each other can be omitted, thereby preventing liquid from leaking through the gap between the connected components.

As shown in FIG. 7, the first extended surface 212a may be a portion of the inner surface of the lower passage wall 210b. The first flared surface 212a may be adjacent to the first passage 21. The first flared surface 212a may be coupled to the upper end of the first passage surface 211. The first expanded surface 212a may extend horizontally from the upper end of the first pass surface 211. Between the first pass surface 211 and the first expanded surface 212a, a first edge portion 213 may be formed.

The second extended surface 212b may be a portion of the inner surface of the upper passage wall 220b. The second expanded surface 212b may be adjacent to the first passage 21. The second expanded surface 212b may be connected to the lower end of the third passage surface 231. The second extended surface 212b may extend horizontally from the lower end of the third passage surface 231. A second edge portion 214 may be formed between the first expanded surface 212b and the third passage surface 231.

A recess 212c may be formed between the first flared surface 212a and the second flared surface 212b and pressed upward to a predetermined depth. A recess 212c may be formed between the lower passage wall 210b and the upper passage wall 220b. The recess 212c may face the top of the first passage 21.

Therefore, since the turbulent flow at the location adjacent to the recess 212c is enhanced by the aerosol sprayed at the end of the wick 31, uniform mixing of the aerosol is possible even when the amount of aerosol in the aerosol generating portion of the wick 31 changes.

As shown in FIG. 8, the top 15 of the container 10 may be formed on the upper sides of the outer wall 11 and the inner wall 12 so that it connects the outer wall 11 and the inner wall 12. The top 15 of the container 10 may cover the top side of the chamber 101. The top 15 of the container 10 may extend circumferentially and surround the insertion space 102.

The inner surface 121 of the container 10 may be the inner surfaces of the inner wall 12 and the top 15. The inner surface 121 of the container 10 may extend vertically.

An inclined surface 152 may be formed between the upper end surface 151 and the inner surface 121 of the container 10 to connect the upper end surface 151 to the inner surface 121. The inclined surface 152 may extend toward the inner surface 121 from the upper end surface 151 of the container 10 in a smooth curve. The inclined surface 152 may extend toward the upper end surface 151 from the inner surface 121, continuously increasing radially outward. The ramp 152 may be inclined outward such that the opening defined by the ramp 152 tapers in a downward direction. The inner surface 121, the upper end surface 151 and the inclined surface 152 may form a continuous surface.

The width W0 of the lower end of the inclined surface 152 may be smaller than the width W5 of the upper end of the inclined surface 152. The width W0 of the lower end of the inclined surface 152 may be substantially equal to the width W0 of the inner surface 121.

This makes it easier to insert the stick 40 into the insertion space 102.

As shown in FIG. 9, a plug 41 is located at the bottom of the stick 40. A filter portion 43 may be located at the top of the stick 40. Between the plug 41 and the filter portion 43, a granule portion 42 may be placed in the stick 40. The granule portion 42 may contain a medium.

The user can inhale air while holding the filter portion 43 of the stick 40 inserted into the container 10 in the mouth. When the user inhales air through the stick 40, the aerosol generated on the wick 31 may enter the bead portion 42 through passage 20 and plug 41. The aerosol introduced into the bead portion 42 may contain the media in the bead portion and is introduced into the filter portion. 43, thereby passing through it with filtration. Filtered air can be supplied to the user.

As shown in FIG. 10, the main body 50' can extend horizontally. The container 10 may be connected to the right or left side of the main body 50'. The container 10 may be connected to the interior of the main body 50'.

The controller 51' may be housed in the main body 50'. The controller 51' may be located below the heater 32. The controller 51' may be located adjacent to the heater 32.

The battery 52' may be located in the main body 50'. The battery 52' may be located on one side surface of the container 10. The battery 52' may extend vertically along the container 10.

The terminal 53' may be located inside the main body 50'. Terminal 53' may be located adjacent to controller 51' and battery 52'.

As shown in FIG. 11, the upper housing 60 may be positioned adjacent the container 10 or 100. The upper housing 60 may be located adjacent one side surface of the outer wall 11 or 110. The upper housing 60 may be integral with the main body 50. The upper housing 60 may be located above the main body 50. The upper body 60 and the container 10 or 100 may be located parallel to each other above the main body 50.

The container 10 or 100 may be replaceable. The container 10 or 100 may be removably connected to an upper end surface of the main body 50 and one surface of the upper body 60.

A receiving space 63 may be defined in the upper housing 60. A sensor 62 may be located in a receiving space 63 in the upper housing 60. Various components may be located in a receiving space 63 in the upper housing 60.

The sensor 62 may be located on the outside of the outer wall 11 or 111. The sensor 62 may be positioned to face the outer wall 11 or 110. The sensor 62 may sense light emitted from inside the container 100.

Controller 51 may be electrically coupled to sensor 62. Controller 51 may control operation of sensor 62. Controller 51 may receive information received from sensor 62. Controller 51 may determine stick information based on information received by sensor 62.

The outer wall 11 or 110 and the inner wall 12 may be made of a translucent material. The outer wall 11 or 110 and the inner wall 12 may preferably be made of a material with low optical reflectivity and refraction and high light transmittance. The outer wall 11 or 110 and the inner wall 12 may be made of a polymer material for the light sensor. The outer wall 11 or 110 and the inner wall 12 may be made of polyethylene, polystyrene, Teflon, or other similar material. However, the material constituting the outer wall 11 or 110 and the inner wall 12 is not limited to this embodiment.

The lid 70 may be located above the main body 50. The lid 70 may be located outside the container 10 or 100 and the upper body 60 so that it surrounds the container 10 or 100 and the upper body 60. The outer surface of the lid 70 may be flush with the outer surface the main body 50. The outer surface of the cover 70 may form a surface extending the outer surface of the main body 50. The outer surface of the cover 70 may be located on an imaginary plane extending from the outer surface of the main body 50.

The cover 70 can be detachably connected to the upper side of the main body 50. Replacement of the container 10 or 100 may be possible with the lid 70 removed.

As shown in FIG. 12 and 13, the z-axis direction can be defined as the forward-backward direction of the aerosol generating apparatus. Based on the origin, the +z-axis direction may be the forward direction, and the -z-axis direction may be the backward direction.

The container 100 may be configured to extend vertically. The container 100 may be hollow. The container 100 may have a right surface that is flat and extends vertically.

Container 100 may include an outer wall 110. The outer wall 110 may be located some distance from the inner wall 12. The outer wall 110 may extend vertically along the outer surface of the container 100.

The first surface 111 may be formed on the right side of the outer wall 110. The first surface 111 may extend vertically.

A second surface 112 may be formed on the left side of the outer wall 112. A second surface 112 may be positioned opposite the first surface 111.

The first surface 111 and the second surface 112 may have different shapes. The second surface 112 may be rounded to form an outward convexity. The first surface 111 may not have a curve. The first surface 111 may include a flat portion. The first surface 111 may have a portion extending in an up-down and/or back-to-back direction.

The upper housing 60 may be formed adjacent the first surface 111. The upper housing 60 may face the first surface 111. The upper housing 60 may be in contact with the container 100.

The third surface 611 may be formed on the left surface of the upper housing 60. The third surface 611 may be adjacent to the first surface 111 and facing the first surface 111. The third surface 611 may extend vertically. The third surface 611 may be shaped to match the first surface 111 and contact the first surface 111. The third surface 611 may include a portion extending in an up-down and/or back-to-back direction. The first surface 111 and the third surface 611 may be parallel to each other.

The fourth surface 612 may be formed on the right surface of the upper housing 60. The fourth surface 612 may be located opposite the third surface 611. The fourth surface 612 may be rounded to form an outward convexity.

The sensor 62 may be located in the upper housing adjacent the third surface 611 of the upper housing 60. A portion of the sensor 62 may extend outward from the upper housing 60. The sensor 62 may be exposed to the third surface 611. The sensor 62 may face the first surface 111.

Therefore, the user can comfortably hold the aerosol generating device in his hand, and the volume of the chamber 101 (see FIG. 11) can be increased, thereby increasing the size of the liquid storage space and providing sufficient space to accommodate the sensor 62.

As shown in FIG. 14, the vibration motor 54 can transmit various information by vibration, such as the activation/deactivation of the power supply, the activation or deactivation of the heater 32, the state of the stick, and the state of the liquid. The controller 51 may be electrically coupled to the vibration motor 54. The controller 51 may control the vibration motor 54 to communicate various information received from the components to the user through vibration.

The user can input various commands, such as commands to activate/deactivate the power supply and operation of the heater 32, through the input device 57. The controller 51 may be electrically connected to the input device 57. The controller 51 may control the operation of the components in response to commands transmitted from the input device 57.

The output device 55 can display various information about the activation/deactivation of the power supply, activation or deactivation of the heater 32, the state of the stick and the state of the liquid, and transmit the information to the user. The controller 51 may be electrically connected to the output device 55. The controller 51 may control the output device 550 to display various information transmitted from the components, thereby communicating information to the user.

The storage device 56 may store data containing information. The controller 51 may be electrically coupled to the storage device 56. The storage device 56 may receive data about various information from the controller 51 and store it. In addition, the storage device 56 may transmit stored data to the controller 51. The controller 51 may control the operation of components based on data received from the storage device 56.

The sensor 62 (see FIG. 11) may be an infrared sensor 62. The infrared sensor 62 may sense infrared rays emitted from inside the container 100. The infrared sensor 62 may include a light-emitting portion 621 and a light-receiving portion 622. The light-emitting portion 621 may emit infrared rays inwardly. container 100. Infrared rays emitted by the light emitting portion 621 can pass through the outer wall 110, the chamber 101, and the inner wall 12 in that order and be reflected from the stick. The reflected infrared rays may be transmitted to the light receiving portion 622 through the inner wall 12, chamber 101, and outer wall 110 in that order. The light receiving portion 622 can detect infrared rays reflected from an object.

When the liquid is stored in the chamber 101, infrared rays can pass through the liquid. The liquid can have a given coefficient of reflection and refraction with respect to the infrared ray. The amount of infrared radiation transmitted to the light receiving portion 622 when the infrared rays pass through the liquid may be less than the amount of infrared radiation transmitted to the light receiving portion 622 when the infrared rays do not pass through the liquid.

The value detected by the light receiving portion 622 may vary depending on the amount of infrared radiation detected by the light receiving portion 622. For example, the greater the amount of infrared radiation reflected to the light receiving portion 622, the larger the detected value. In addition, the smaller the amount of infrared radiation reflected to the light receiving portion 622, the smaller the detected value. The amount of infrared radiation reflected can depend on the reflectivity and refractive index of the object.

The controller 51 may be coupled to the infrared sensor 62. The controller 51 may receive a signal related to the detected value from the infrared sensor 61. The controller 51 may determine information based on the value detected by the infrared sensor 62. The controller 51 may determine information by comparing the value found infrared sensor 62, with reference value. Both the reference and the found value can be the current value.

As shown in FIG. 14 and 15, the light emitting portion 621 may emit infrared rays toward the object 623. The infrared rays may be reflected from the object 623 and transmitted to the light receiving portion 622.

The light receiving portion 622 can detect infrared rays reflected from an object and detect the amount of current. The light receiving portion 622 may be a phototransistor. The light receiving portion 622 may include a collector 622a and an emitter 622b.

The light receiving portion 622 may convert the detected value into a current value. For example, the greater the amount of infrared radiation reflected from the light receiving portion 622, the greater the current flowing in the collector 622a of the light receiving portion 622. Conversely, the smaller the amount of infrared radiation reflected from the light receiving portion 622, the smaller the current flowing in the collector 622a of the light receiving portion 622.

The controller 51 may determine the state of the stick and/or the state of the liquid based on the amount of current corresponding to the detected value. The controller 51 can determine the state of the stick and/or the state of the liquid by comparing the current value corresponding to the detected value with a reference current value.

As shown in FIG. 16, a plug 41 may be located at the bottom of the stick 40'. A granule portion 42 may be placed between the plug 41 and the filter portion 43. The 40' stick may be referred to as the aerosol generating element 40'.

The filter 411 may be located in the plug 41. The filter 411 may be made of paper. The filter 411 can be formed by creasing a long paper sheet. Since the filter 411 is wrinkled, gaps may form between the folds of the wrinkled paper.

Therefore, as the aerosol passes through the filter 411, a portion of the aerosol may enter the bead portion 42, wetting the filter 411, and the remainder of the aerosol may enter the bead portion 42 by passing through the gaps between the pleats in the filter 411.

Accordingly, as the aerosol moves, it may wet the filter 411 and thereby wet a portion of the surface of the stick 40'.

The bead portion 42 may contain a medium. The aerosol generating device can extract a certain ingredient from a medium using an aerosol. The granule portion 42 may be positioned above the plug 41.

The filter portion 43 may be located above the granule portion 42. The filter may be included in the filter portion 43. The filter may be a cellulose acetate filter.

The hollow portion 44 may be positioned above the filter portion 43. The hollow portion 44 may be in the form of a hollow tube.

A mouthpiece 45 may be located at the upper end portion of the stick 40'. The mouthpiece 45 may be positioned above the hollow portion 44. The mouthpiece 45 may include a filter. The filter may be a cellulose acetate filter. The plug 41, the bead portion 42, the filter portion 43, the hollow portion 44, and the mouthpiece 45 may be wrapped with a casing. The shell can be made of paper. The shell may be white.

As shown in FIG. 16 and 17, when the stick 40' is inserted into the insertion space 102 (see FIG. 2), a plug 41 may be located at the lower end of the insertion space 102. When the stick 40' is inserted into the insertion space 102, the bead portion 42 may be positioned in the insertion space 102. When the stick 40' is inserted into the insertion space 102, at least a portion of the filter portion 43 may be located in the insertion space 102.

When the stick 40' is inserted into the insertion space 102, the hollow portion 44 can be opened outward. When the stick 40' is inserted into the insertion space 102, the mouthpiece 45 can be opened outward.

The insertion space 102 may be configured with a height H such that at least a portion of the filter portion 43 is located in the insertion space 102 when the stick 40' is fully inserted into the insertion space 102. The height H of the insertion space 102 may exceed the distance between the lower end of the plug 41 and the upper end of the bead portion 42. The height H of the insertion space 102 may be less than the distance between the lower end of the plug 41 and the upper end of the filter portion 43.

The vertical length L1 of the plug 41 may be about 7 mm. The vertical length L2 of the granule portion 42 may be about 10 mm. The vertical length L3 of the filter portion 43 may be about 7 mm. The vertical length L4 of the hollow portion 44 may be about 12 mm. The vertical length L5 of the mouthpiece 45 may be about 12 mm.

The height H of the insertion space 102 may be 17 mm or more. The height H of the insertion space 102 may be 24 mm or less. The height H of the insertion space 102 may be 22 mm.

The stick 40' may be divided into a first zone A1 and a second zone A2. The first zone A1 may be located in the insertion space 102 when the stick 40' is inserted into the insertion space 102. The second zone A2 can be opened outward when the stick 40' is inserted into the insertion space 102. The length of the first zone A1 may correspond to the height H of the insertion space 102.

The first zone A1 may contain a plug 41 and a granule portion 42. The first zone A1 may include at least a portion of the filter portion 43. The second zone A2 may include a hollow portion 44 and a mouthpiece 45. The second zone A2 may include at least a portion of the filter portion 43.

A marker 46 may be formed on the stick shell 40'. The marker 46 may be printed on a portion of the shell or over the entire surface of the shell.

The marker 46 may be located on the surface of at least that portion of the stick 40' that is inserted into the insertion space 102. A marker 46 may be formed in the first zone A1 of the stick 40'. The marker 46 may be formed at a location corresponding to the plug 41 and/or the bead portion 42 and/or the filter portion 43 in the first zone A1.

The marker 46 may have a color different from the color of the stick shell 40'. The marker 46 and the shell may have different infrared reflective abilities. For example, the shell may be white and marker 46 may be blue.

The infrared sensor 62 may be positioned at a height corresponding to the marker 46 when the stick 40' is inserted into the insertion space 102.

For example, marker 46 may represent a shell zone. Alternatively, the marker 46 may be an area that receives light emitted by the light emitting portion of the infrared sensor 62.

For example, the marker 46 may be a stripe formed along the surface of the stick 40'. Therefore, the infrared sensor 62 is able to recognize the marker 46 regardless of the orientation of the stick 40' inserted into the insertion space 102.

As shown in FIG. 17, the infrared sensor 62 may be located on the outside of the container 10 or 100. The infrared sensor 62 may be located on the outside of the outer wall 11 or 110 of the container 10 or 100. The infrared sensor 62 may be positioned to face the outer wall 11 or 110. The infrared sensor 62 may be positioned adjacent to the outer wall 11 or 110. The infrared sensor 62 may face the insertion space 102 (see FIG. 2). The infrared sensor 62 may sense infrared rays emitted from inside the container 10 or 100.

The infrared sensor 62 may be located at a height similar to the height of the marker 46. At least one infrared sensor 62 may be located between the upper and lower ends of the camera 101 on the outside of the container 10 or 100. At least one infrared sensor 62 may be located between the upper and lower ends of the camera 101. the lower ends of the insertion space 102 on the outside of the container 10 or 100. At least one infrared sensor 62 may be located above the step surface 17 on the outside of the container 10 or 100.

As shown in FIG. 18, the infrared sensor 62 may include a light-emitting portion 621 configured to emit infrared rays into the interior of the container 10 or 100. The infrared sensor 62 may include a light-receiving portion 622 configured to receive infrared rays.

The light emitting portion 621 may emit infrared rays into the insertion space 102. The light emitting portion 621 may emit infrared rays toward the stick 40 or 40' inserted into the insertion space 102. The light emitting portion 621 may emit infrared rays towards the marker 46 of the stick 40'.

Infrared rays emitted from the light emitting portion 621 may be reflected from the object. Infrared rays may be reflected from the 40 or 40' stick. Infrared rays can be reflected by the marker 46 of the stick 40'. The light receiving portion 622 can receive the reflected infrared beam.

The outer wall 11 or 110 and the inner wall 12 may be made of an infrared-transmitting material. The outer wall 11 or 110 and the inner wall 12 may preferably be made of a material with low reflectance and refraction and high infrared transmittance.

Infrared rays emitted by the light emitting portion 621 may pass through the outer wall 11 or 110, the chamber 101, and the inner wall 12 in that order. Infrared rays passing through the components may be reflected by the stick 40 or 40' and then pass through the inner wall 12, chamber 101, and outer wall 11 or 110 in that order. The reflected infrared rays may enter the light receiving portion 622.

As shown in FIG. 19, the amount of reflected infrared radiation may vary depending on the reflectivity and refractive index of the object. The light receiving portion 622 can determine a value corresponding to the amount of reflected infrared radiation.

According to (a) in FIG. 19, when the stick 40 or 40' is not inserted into the insertion space 102, the amount of reflected infrared radiation may be zero or close to zero.

Stick 40 not having marker 46 may be referred to as first stick 40, and stick 40' having marker 46 may be referred to as second stick 40'. The first stick 40 may be referred to as a first type aerosol generating element 40. The second stick 40' may be referred to as a second type aerosol generating element 40'.

According to parts (b) and (c) of FIG. 19, infrared rays emitted by the infrared sensor 62 may be reflected from the stick 40 or 40' and transmitted to the infrared sensor 62 when the stick 40 or 40' is inserted into the insertion space 102. The amount of infrared radiation reflected by the marker 46 of the second stick 40' ((c) in FIG. 19) may be less than the amount of infrared radiation reflected by the first stick 40 ((b) in FIG. 19).

Therefore, the value detected by the infrared sensor 62 may vary depending on whether the stick 40 or 40' is inserted, as well as the type of stick 40 or 40'.

As shown in FIG. 20, when the aerosol enters the second stick 40', the marker 46 may be wetted by the aerosol and thus may change color. The greater the amount of aerosol administered, the richer the color of the marker 46. The ability of the marker 46 to react to infrared rays may change due to changes in the color of the marker 46.

In the case of the second stick 40', which is not used ((a) in FIG. 20), the color of the marker 46a may not change and thus the marker may have maximum brightness. In the case of the second stick 40' into which the aerosol is introduced ((b) in FIG. 20), the color of the marker 46b may be richer than the color of the marker in (a) in FIG. 20, that is, the reflectivity may be reduced. In the case of the second stick 40', which contains a larger amount of aerosol ((c) in FIG. 20), the color of the marker 46c may be richer than the color of the marker in (b) in FIG. 20, that is, the reflectivity can be further reduced.

Therefore, the value detected by the infrared sensor 62 may vary depending on the level of use of the stick 40'.

As shown in FIG. 21, when the infrared sensor 62 is activated (S10), the infrared sensor 62 can detect the infrared beam. In addition, when the infrared sensor 62 is activated (S10), the controller 51 may receive the X value detected by the infrared sensor 62. The detected X value may vary depending on the amount of infrared radiation transmitted to the infrared sensor 62.

The controller 51 may compare the X value detected by the infrared sensor 62 with the reference values RSn (n=1, 2, 3,...) (S20). Memory 56 may store a reference value RSn. The controller 51 may obtain the reference value RSn from the storage device 56 and process the reference value RSn. The stick reference value may be called the reference value.

The controller 51 may compare the detected value X with the reference value RSn (S20) and determine the state of the stick (S30). The controller 51 may compare the detected X value with a reference value RSn and determine a range to which the detected X value belongs.

The controller 51 can control components connected to it based on the information found in step S30. The controller 51 may control the output device 55 to display the information obtained in step S30.

When the infrared sensor 62 is deactivated (“Yes” in step S40) after the controller 51 determines the state of the stick (S30), the controller 51 may complete the step. When the infrared sensor 62 is deactivated (“No” in step S40), after the controller 51 determines the state of the stick, the controller 51 may compare the detected value X with the reference value RSn of the stick (S20), and determine the state of the stick (S30).

As shown in FIG. 22, when the infrared sensor 62 is activated (S10) and detects infrared rays, the controller 51 may compare the detected value X with the reference value RSn (S20). The controller 51 can determine whether the stick is inserted, the type of stick inserted, and the degree of use of the stick based on the result of comparing the detected value X with the reference value RSn.

When the stick 40 or 40' is inserted into the insertion space 102, the detected X value may exceed the stick reference value RS1. When the detected value X exceeds the reference value RS1 of the first stick (“Yes” in step S21), the controller 51 may determine that the stick 40 or 40' is inserted into the insertion space 102.

When the stick 40 or 40' is not inserted into the insertion space 102, the detected value X may be equal to or less than the first stick reference value RS1. When the detected value X is equal to or lower than the reference value RS1 of the first stick (No in step S21), the controller 51 may determine that the stick 40 or 40' is not inserted into the insertion space 102 (S312).

When the first stick 40 is inserted into the insertion space 102, the detected X value may exceed the second stick reference value RS2. When the detected value X exceeds the second stick reference value RS2 (“Yes” in step S22), the controller 51 may determine that the first stick 40 is inserted into the insertion space 102 (S321).

When the second stick 40' is inserted into the insertion space 102, the detected X value may be equal to or lower than the second stick reference value RS2. In other words, when the second stick 40' is inserted into the insertion space 102, the detected X value may be greater than the first stick reference value RS1, but may be equal to or lower than the second stick reference value RS2.

The detected X value when the second stick 40' is inserted into the insertion space 102 may be the detected X value due to the reflection of infrared rays by the marker 46 on the second stick 40'. When the detected value X is equal to or lower than the second stick reference value RS2 (“No” in step S22), the controller 51 may determine that the second stick 40' is inserted into the insertion space 102 (S322).

In the stick state determination step, the controller 51 can determine the stick reference value range RSn in which the detected X value is located, and there is no need to perform the step in the above sequence.

The reference value RS1 of the first stick may be set to distinguish the case where the stick 40 or 40' is inserted into the insertion space 102 from the case where the stick 40 or 40' is not inserted into the insertion space 102. The amount of infrared radiation reflected onto the infrared sensor 62 may be less when the stick 40 or 40' is not inserted into the insertion space 102 than when the stick 40 or 40' is inserted into the insertion space 102. The reference value RS1 of the first stick may be set to be in the range between the detected X value when the stick 40 or 40' is inserted into the insertion space 102 and the detected X value when the stick 40 or 40' is not inserted into the insertion space 102 introduction.

The second stick reference value RS2 may be set to distinguish the case where the first stick 40 is inserted into the insertion space 102 from the case where the second stick 40' is inserted into the insertion space 102. The amount of infrared radiation reflected onto the infrared sensor 62 may be less when the second stick 40' is inserted into the insertion space 102 than when the first stick 40 is inserted into the insertion space 102. The second stick reference value RS2 may be set to be in the range between the detected X value when the first stick 40 is inserted into the insertion space 102 and the detected X value when the second stick 40' is inserted into the insertion space 102.

When the infrared sensor 62 is deactivated after the controller 51 determines the state of the stick (“Yes” in step S40), the controller 51 may complete the step. When the infrared sensor 62 is deactivated after the controller 51 determines the stick state (“No” in step S40), the controller 51 can again determine the stick state by comparing the stick reference value RSn with the detected X value.

The amount of infrared radiation that is transmitted to the infrared sensor 62 when infrared rays pass through the liquid in the chamber 101 and the amount of infrared radiation that is transmitted to the infrared sensor 62 when the infrared rays do not pass through the liquid in the chamber 101 may be different from each other. When infrared rays pass through the liquid in the chamber 101, the amount of infrared radiation that is transmitted to the infrared sensor 62 may change due to the refractive index of the liquid. The reference value RSn can be set to correspond to the found value of X, which varies depending on the presence of liquid.

As such, according to FIG. 1-22, an aerosol generating device according to one aspect of the present invention includes an elongated container 10 or 100 consisting of an inner wall 12 and an outer wall 11 or 110, wherein the inner wall defines an insertion space 102 configured to accommodate an aerosol generating element wherein a chamber 101 configured to store liquid is defined between the inner wall 12 and the outer wall 11 or 110; a wick 31 located at the end of the insertion space 102; a heater 32 configured to heat the wick 31; a passage 20 formed between the insertion space 102 and the wick 31; and an infrared sensor 62 located externally adjacent to the insertion space 102.

In another aspect of the present invention, the outer wall of the container includes: a first surface located adjacent to the infrared sensor; and a second surface opposite the first surface and having a different shape from the first surface.

In another aspect of the present invention, the second surface is rounded.

In another aspect of the present invention, the aerosol generating device further comprises an upper housing located adjacent the first surface and containing a receiving space, a third surface of the upper housing facing the first surface, and an infrared sensor located in the receiving space of the upper housing so as to face to the first surface.

In another aspect of the present invention, the first surface and the third surface are parallel to each other.

In another aspect of the present invention, the upper body includes a fourth surface located opposite the third surface and having a different shape from the third surface.

In another aspect of the present invention, the fourth surface is rounded.

In another aspect of the present invention, the aerosol generating device further comprises a controller configured to determine the state of the aerosol generating element based on a comparison of a value detected by the infrared sensor and a reference value.

In another aspect of the present invention, wherein the controller is configured to determine the presence of an aerosol generating element in the introduction space based on a detected value greater than a first reference value, and determine the absence of an aerosol generating element in the introduction space based on a detected value less than or equal to the first reference value.

In another aspect of the present invention, the controller is configured to:

determining the presence of a first type of aerosol generating element in the insertion space based on a detected value greater than both the first reference value and the second reference value; and determining the presence of a second type of aerosol generating element in the insertion space based on the detected value greater than the first reference value but less than or equal to the second reference value.

In another aspect of the present invention, the position of the infrared sensor relative to the length of the insertion space corresponds to the position of the marker on the surface of the aerosol generating element when the aerosol generating element is inserted into the insertion space.

In another aspect of the present invention, the aerosol generating device according to claim 1, wherein the outer wall and the inner wall of the container are made of a translucent material.

Certain embodiments or other embodiments of the invention described above are not mutually exclusive or different from each other. Any or all of the elements of the embodiments of the invention described above may be combined with each other or with other elements in configuration or function.

For example, configuration "A" described in one embodiment and drawings and configuration "B" described in another embodiment and drawings may be combined with each other. Even if a combination of configurations is not expressly described, it remains possible unless the combination is explicitly stated not to be possible.

Although embodiments of the invention have been described with reference to a number of illustrative embodiments of the invention, it should be understood that those skilled in the art can develop many other modifications and embodiments of the invention that will fall within the principles of the present invention. In particular, various variants and changes to the components and/or arrangements of the combination device in question are possible within the scope of the description, drawings and the attached claims. In addition to variations and changes in component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.

Claims (23)

1. A device for generating an aerosol, containing: an elongated container comprising an inner wall and an outer wall, in which the inner wall defines an insertion space configured to accommodate an aerosol generating element, and in which a chamber configured to store liquid is defined between the inner wall and the outer wall; a wick located at the end of the insertion space; a heater configured to heat the wick; a passage formed between the insertion space and the wick; an upper body located on the outer wall side of the container and containing a receiving space; And an infrared sensor located in the receiving space of the upper body facing the side of the outer wall and configured to sense an infrared beam reflected by the aerosol generating element that is located in the introduction space, wherein The outer wall and inner wall of the container are made of translucent material. 2. A device for generating an aerosol according to claim 1, in which the outer wall of the container contains: a first surface adjacent the infrared sensor; And a second surface located opposite the first surface and having a different shape from the first surface. 3. A device for generating an aerosol according to claim 2, in which the second surface is rounded. 4. The aerosol generating device according to claim 3, wherein the upper body is located adjacent the first surface, wherein the third surface of the upper body faces the first surface, wherein the infrared sensor is located in the receiving space of the upper housing so that it faces the first surface. 5. The aerosol generating device according to claim 4, wherein the first surface and the third surface are parallel to each other. 6. The aerosol generating device according to claim 4, wherein the upper body includes a fourth surface opposite the third surface and having a different shape from the third surface. 7. An aerosol generating device according to claim 6, in which the fourth surface is rounded. 8. The aerosol generating device according to claim 1, further comprising a controller configured to determine the state of the aerosol generating element based on a comparison of the value detected by the infrared sensor and the reference value. 9. The aerosol generating device according to claim 8, wherein the controller is configured to determine the presence of an aerosol generating element in the introduction space based on a detected value greater than the first reference value, and determine the absence of an aerosol generating element in the introduction space based on the detected value , less than or equal to the first reference value. 10. A device for generating an aerosol according to claim 9, in which the controller is configured to: determining the presence of a first type of aerosol generating element in the insertion space based on a detected value greater than both the first reference value and the second reference value; And determining the presence of a second type of aerosol generating element in the injection space based on the detected value greater than the first reference value but less than or equal to the second reference value. 11. The aerosol generating device according to claim 10, wherein the position of the infrared sensor relative to the length of the insertion space corresponds to the position of the marker on the surface of the aerosol generating element when the aerosol generating element is inserted into the insertion space.