KR102591464B1 - Cartridge and device for generating aerosol with the same - Google Patents

Abstract

A cartridge and an aerosol generating device including the same are disclosed. The cartridge of the present disclosure includes: a first chamber storing liquid; a second chamber having an inlet and an outlet; a wick located in the second chamber and connected to the first chamber; And, it may include a heater that heats the wick, and the second chamber may include: a curved surface forming at least a portion of the second chamber between the inlet and the outlet.

Description

Cartridge and aerosol generating device including the same {CARTRIDGE AND DEVICE FOR GENERATING AEROSOL WITH THE SAME}

The present disclosure relates to a cartridge and an aerosol generating device including the same.

An aerosol generating device is intended to extract certain components from a medium or material through aerosol. The medium may contain substances of various compositions. Substances included in the medium may be flavor substances of various ingredients. For example, substances included in the medium may include nicotine ingredients, herbal ingredients, and/or coffee ingredients. Recently, much research has been conducted on such aerosol generating devices.

The present disclosure aims to solve the above-described problems and other problems.

Another purpose may be to reduce flow resistance that occurs as air passes through the inside of the cartridge.

Another purpose may be to ensure that air uniformly entrains aerosols generated inside the cartridge.

Another purpose may be to prevent eddies from forming as air passes inside the cartridge.

Another goal may be to increase the amount or density of entrained aerosols in the inhaled air.

According to one aspect of the present disclosure for achieving the above-described object, there is provided a first chamber storing a liquid; a second chamber having an inlet and an outlet; a wick located in the second chamber and connected to the first chamber; And, a cartridge may be provided that includes a heater for heating the wick, and the second chamber includes: a curved surface forming at least a portion of the second chamber between the inlet and the outlet. .

According to at least one of the embodiments of the present disclosure, flow resistance that occurs as air passes through the inside of the cartridge can be reduced.

According to at least one of the embodiments of the present disclosure, it is possible to prevent eddy currents from occurring when air passes inside the cartridge.

According to at least one of the embodiments of the present disclosure, the air may be uniformly accompanied by the aerosol generated inside the cartridge.

According to at least one of the embodiments of the present disclosure, the amount or density of aerosol entrained in inhaled air can be increased.

Additional scope of applicability of the present disclosure will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the present disclosure may be clearly understood by those skilled in the art, the detailed description and specific embodiments such as preferred embodiments of the present disclosure should be understood as being given only as examples.

1 to 24 are diagrams showing examples of aerosol generating devices according to embodiments of the present disclosure.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the attached drawings. However, identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted.

The suffixes “module” and “part” for components used in the following description are given or used interchangeably only for the ease of preparing the specification, and do not have distinct meanings or roles in themselves.

Additionally, in describing the embodiments disclosed in this specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed descriptions will be omitted. In addition, the attached drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the attached drawings, and all changes included in the spirit and technical scope of the present disclosure are not limited. , should be understood to include equivalents or substitutes.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Singular expressions include plural expressions unless the context clearly dictates otherwise.

Hereinafter, the z-direction shown in the coordinate system may be defined as the upward direction, and the direction opposite to it may be defined as the downward direction. The x-axis direction can be defined as the posterior direction, and the direction opposite to it can be defined as the anterior direction. The y-axis direction can be defined as the right direction, and the direction opposite to it can be defined as the left direction.

Referring to FIG. 1, the aerosol generating device 100 may include at least one of a battery 10, a control unit 20, a heater 30, and a cartridge 40. At least one of the battery 10, the control unit 20, and the heater 30 may be disposed inside the case 110 of the aerosol generating device 100. The cartridge 40 may be detachably coupled to one side of the case 110.

The case 110 may have an insertion space 50 into which the stick 200 can be inserted. The insertion space 50 is open to the outside and may extend long. The heater 30 may be formed around the insertion space 50 . The cartridge 40 and the insertion space 50 may be arranged side by side to face each other. The internal structure of the aerosol generating device 100 is not limited to that shown. The stick 200 may be inserted into the insertion space 50 and protrude out of the case 110. The user can hold the stick 200 in his mouth and perform a suction motion.

The battery 10 may supply power to operate at least one of the control unit 20, the heater 30, and the cartridge 40. The battery 10 can supply power necessary for the display, sensor, motor, etc. installed in the aerosol generating device 100 to operate.

The control unit 20 can control the overall operation of the aerosol generating device 100. The control unit 20 may control the operation of at least one of the battery 10, heater 20, and cartridge 40. The control unit 20 can control the operation of displays, sensors, motors, etc. installed in the aerosol generating device 100. The control unit 20 may check the status of each component of the aerosol generating device 100 and determine whether the aerosol generating device 100 is in an operable state.

The heater 30 may generate heat by power supplied from the battery 10. The heater 30 may heat the stick 200 inserted into the aerosol generating device 100.

Cartridge 40 may generate an aerosol. The aerosol generated by the cartridge 40 may pass through the stick 200 inserted into the aerosol generating device 100 and be delivered to the user.

Referring to FIG. 2, the cartridge 40 may include a first container 41 and a second container 42. The second container 42 may be coupled to the upper side of the first container 41. The cartridge inlet 414 may be formed by opening one side of the cartridge 40. The cartridge inlet 414 may be formed by opening one side of the first container 41. The cartridge inlet 414 may be formed by opening one side of the second container 42. The cartridge inlet 414 may communicate with the outside. Air outside the cartridge 40 may flow into the interior of the cartridge 40 through the cartridge inlet 414.

Referring to FIG. 3, the first container 41 may have a first chamber C1 therein. The first chamber C1 can store liquid. The cartridge inlet 414 may be formed by opening the top of the first container 41.

The second container 42 may have a second chamber C2 therein. The second chamber C2 may be separated from the first chamber C1. The second chamber C2 may be disposed below the first chamber C1.

The wick 61 may be installed inside the second chamber (C2). The wick 61 may be connected to the first chamber (C1). The wick 61 may be supplied with the liquid stored in the first chamber C1 from the first chamber C1.

The heater 62 may be installed inside the second chamber C2. The heater 62 can wind the wick 61. The heater 62 can heat the wick 61. When the heater 62 heats the wick 61 supplied with liquid, an aerosol may be generated around the wick 61 inside the second chamber C2.

The chamber inlet 542 may be formed by opening one side of the second chamber C2. The chamber outlet 543 may be formed by opening the other side of the second chamber C2. The chamber inlet 542 may be in communication with the second chamber C2. The chamber outlet 543 may be in communication with the second chamber C2. The chamber inlet 542 and the chamber outlet 543 may be disposed opposite to each other with respect to the second chamber C2. The chamber inlet 542 and the chamber outlet 543 may be arranged opposite to each other with the wick 61 as the center. Chamber inlet 542 may be named inlet 542. The chamber outlet 543 may be named outlet 543.

The inlet channel 541 may be formed between the chamber inlet 542 and the cartridge inlet 414. The inlet channel 541 may connect the chamber inlet 542 and the cartridge inlet 414. The inlet channel 541 may extend long downward from the cartridge inlet 414 toward the chamber inlet 542. The inflow channel 541 may be separated from the first chamber (C1). The inflow channel 541 may be separated from the second chamber C2. The inlet channel 541 may be formed parallel to the first chamber (C1). The inlet channel 541 may be bent toward the chamber inlet 542 in the vicinity of the chamber inlet 542 and communicate with the chamber inlet 542.

The discharge channel 544 may be formed by opening the second container 42. The discharge channel 544 may be in communication with the chamber discharge port 543. The discharge channel 544 may communicate with the outside of the cartridge 40. The discharge channel 544 may be open in the front-to-back direction. The discharge channel 544 may extend long in the front-to-back direction. The discharge port 512 may be formed so that the front side of the second container 42 protrudes forward. The discharge channel 544 is formed inside the discharge port 512 and may be surrounded by the discharge port 512.

The air outside the cartridge 40 may sequentially pass through the cartridge inlet 414, the inlet channel 541, and the chamber inlet 542 to flow into the second chamber C2. The air introduced into the second chamber C2 may sequentially pass through the chamber outlet 543 and the discharge channel 544 and flow out of the cartridge 40. Air introduced into the second chamber C2 may be accompanied by aerosol.

Referring to Figures 4 and 5, the chamber inlet 542 may be open in the front-back direction. The chamber inlet 542 may be open toward the wick 61. The chamber outlet 543 may be open in the forward and backward directions. The chamber outlet 543 may be open toward the wick 61. The wick 61 may be disposed between the chamber inlet 542 and the chamber outlet 543. The chamber inlet 542 and the chamber outlet 543 are arranged side by side with the wick 61 in between, and may face each other.

The wick 61 may extend long in the left and right directions. The wick 61 may extend long in a direction crossing the direction in which the chamber inlet 542 is opened. The wick 61 may extend long in a direction crossing the direction in which the chamber outlet 543 is opened. The wick 61 may have an elongated cylindrical shape. The cross section of the wick 61 may be circular.

The center line (L) may be defined as an imaginary line extending from the center of the chamber inlet 542 and the center of the chamber outlet 543. The center line (L) may extend long from the chamber inlet 542 to the chamber outlet 543. The wick 61 may overlap the center line (L). The wick 61 may extend long in a direction crossing the longitudinal direction of the center line (L). The center of the wick 61 may coincide with the center line (L) or may be adjacent to the center line (L).

The width W2 in the left and right directions of the chamber inlet 542 may be larger than the width W1 in the vertical direction. The diameter of the chamber inlet 542 may be longer in the longitudinal direction of the wick 61. The width W4 in the left and right directions of the chamber outlet 543 may be larger than the width W3 in the vertical direction. The diameter of the chamber outlet 543 may be longer in the longitudinal direction of the wick 61. The chamber inlet 542 and/or the chamber outlet 543 may be opened long in the longitudinal direction of the wick 61 facing the wick 61.

The vertical width W1 of the chamber inlet 542 and the vertical width W3 of the chamber outlet 543 may be the same or similar to each other. The left-right width W2 of the chamber inlet 542 and the left-right width W4 of the chamber outlet 543 may be the same or similar to each other.

The width W0 of the wick 61 may be the same as or similar to the vertical width W1 of the chamber inlet 542. The width W0 of the wick 61 may be the same as or similar to the vertical width W3 of the chamber outlet 543.

The second chamber C2 may have a curved surface on at least one side. The curved surface may cover or surround at least a portion of the second chamber C2. The curved surface may constitute at least part of the external shape of the second chamber C2.

The second chamber C2 may have an inlet curved surface 52. The inlet curved surface 52 may be formed to be curved around the chamber inlet 542. The inlet curved surface 52 may cover one side of the second chamber C2 around the chamber inlet 542. The rear end of the inlet curved surface 52 may be connected to the perimeter of the chamber inlet 542. The inlet curved surface 52 may extend from the perimeter of the chamber inlet 542 toward the front and outward around the chamber inlet 542. The inflow curve surface 52 may have a bowl shape surrounding the rear space of the wick 61. The inflow curve surface 52 may surround the rear side of the wick 61. The inlet curved surface 52 may be formed as a continuous surface.

The second chamber (C2) may be provided with a discharge curve surface (53). The discharge curve surface 53 may be formed to be curved around the chamber discharge port 543. The discharge curve surface 53 may cover the other side of the second chamber C2 around the chamber discharge port 543. The front end of the discharge curve surface 53 may be connected to the circumference of the chamber discharge port 543. The outlet curve surface 53 may extend from the circumference of the chamber outlet 543 outwardly around the chamber outlet 543 toward the rear. The discharge curve surface 53 may have a bowl shape surrounding the front space of the wick 61. The discharge curve surface 53 may surround the front side of the wick 61. The discharge curve surface 53 may be formed as a continuous surface.

The second chamber C2 may have a connection surface 55. The connection surface 55 may be formed between the front end of the inlet curve surface 52 and the rear end of the outlet curve surface 53. The connection surface 55 can connect the front end of the inlet curve surface 52 and the rear end of the outlet curve surface 53. The connection surface 55 may form the perimeter of the vertical, left, and right planes of the second chamber C2. The connection surface 55 may extend in the front-to-back direction. The connecting surface 55 may have no curvature or may have very little curvature.

The second chamber C2 may be surrounded by an inlet curved surface 52, an outlet curved surface 53, and a connection surface 55. The rear of the second chamber C2 may be covered by the inlet curved surface 52. The front of the second chamber C2 may be covered by the discharge curve surface 53. The connection surface 55 may cover the upper and lower periphery of the wick 61. The connection surface 55 may cover the left and right sides of the wick 61.

The inflow channel 541 may be in communication with the chamber inlet 542. The inlet channel 541 may extend in a direction crossing the direction in which the chamber inlet 542 is opened. The inlet channel 541 extends long in the vertical direction and may be bent toward the chamber inlet 542 near the chamber inlet 542. The inlet channel surface 511 may surround the inlet channel 541. The inlet channel surface 511 may be bent and connected to the perimeter of the chamber inlet 542 and the inlet curved surface 52.

The channel curve surface 513 may be formed at a portion where the inlet channel surface 511 is bent. The channel curve surface 513 may be connected to the inlet curve surface 52.

The inlet curve surface 52 may be integrally connected to the inlet channel surface 511. The inlet curve surface 52 and the inlet channel surface 511 may form a continuous surface. The discharge curve surface 53 may be integrally connected to the inner surface of the discharge port 512. The discharge curve surface 53 and the inner surface of the discharge port 512 may form a continuous surface. The inner surface of the discharge port 512 may be referred to as the discharge channel surface 512.

Referring to Figures 6 and 7, the inlet curve surface 52 may include a first inlet curve surface 521 and a second inlet curve surface 522.

The first inlet curved surface 521 may surround the chamber inlet 542. The first inlet curved surface 521 may extend along the circumference of the chamber inlet 542. The chamber inlet 542 may be formed inside the first inlet curved surface 521. The rear end of the first inlet curve surface 521 may be connected to the inlet channel surface 511. The rear end of the first inflow curve surface 521 may be connected to the channel curve surface 513.

The first inlet curve surface 521 may be expanded from the rear of the chamber inlet 542 toward the front so that the circumference of the chamber inlet 542 gradually widens. The first inlet curve surface 521 may have a tapered shape. The first inflow curve surface 521 may be formed to be curved. The first inlet curved surface 521 may form a center of curvature outside the chamber inlet 542 and/or the second chamber C2. The first inlet curve surface 521 may be formed to be convex from the outside of the first inlet curve surface 521 to the inside. The first inlet curve surface 521 may have a bell-mouth shape.

The rear end of the second inlet curved surface 522 may be connected to the front end of the first inlet curved surface 521. The second inlet curve surface 522 may form a continuous surface with the first inlet curve surface 521. An inflection point and/or an inflection surface may be formed between the second inlet curve surface 522 and the first inlet curve surface 521. The front end of the second inlet curve surface 522 may be connected to the rear end of the connection surface 55.

The second inlet curved surface 522 may be expanded forward from the front end of the first inlet curved surface 521 so that the second chamber C2 gradually becomes wider. The second inlet curve surface 522 may have a tapered shape. The second inflow curve surface 522 may be formed to be curved. The second inflow curve surface 522 may form a center of curvature inside the second chamber C2. The second inlet curve surface 522 may be formed to be convex from the inside of the second inlet curve surface 522 to the outside. The center of curvature of the second inflow curve surface 522 may be adjacent to or overlap the core 61.

The channel curve surface 513 can gently guide the flow of air to the chamber inlet 542 and the second chamber C2 in the direction while reducing flow resistance. Air may flow from the inlet channel 541 to the chamber inlet 542 and flow into the second chamber C2. Air flowing through the inlet channel 541 may be guided to the chamber inlet 542 and the second chamber C2 along the inlet channel surface 511 and the channel curve surface 513.

Accordingly, resistance and flow loss for air flowing from the inlet channel 541 to the chamber inlet 542 can be reduced.

The first inflow curve surface 521 can gently guide air to spread around the wick 61 while reducing flow resistance. Air passing through the chamber inlet 542 may spread around the chamber inlet 542 along the first inlet curved surface 521 from the chamber inlet 542 toward the wick 61.

The second inflow curve surface 522 can gently guide air to pass around the wick 61 while reducing flow resistance. Air flowing in from the chamber inlet 542 may flow between the wick 61 and the second inlet curve surface 522 along the second inlet curve surface 522. The second inlet curved surface 522 can collect the air discharged and diffused from the chamber inlet 542 in the direction of flow. The second inlet curved surface 522 can prevent a decrease in flow efficiency or eddy currents that occur when air flowing from the chamber inlet 542 toward the periphery of the wick 61 suddenly changes direction.

Accordingly, diffusion efficiency for air flowing from the chamber inlet 542 to the second chamber C2 may be improved. Additionally, the diffusion efficiency of air around the wick 61 can be increased. Additionally, it is possible to prevent eddy currents from occurring around the wick 61 or near the corners of the second chamber C2. Additionally, the air can entrain aerosols more uniformly. Additionally, the amount of aerosol entrainment in the air can be improved.

Referring to Figures 6 and 8, the discharge curve surface 53 may include a first discharge curve surface 531 and a second discharge curve surface 532.

The first discharge curve surface 531 may surround the chamber discharge port 543. The first discharge curve surface 531 may extend along the circumference of the chamber discharge port 543. The chamber outlet 543 may be formed inside the first discharge curve surface 531. The front end of the first discharge curve surface 531 may be connected to the discharge channel surface 512.

The first discharge curve surface 531 may be expanded from the front to the rear of the chamber discharge port 543 so that the circumference of the chamber discharge port 543 gradually widens. The first discharge curve surface 531 may gradually become narrower from the rear of the chamber discharge port 543 toward the front. The first discharge curve surface 531 may have a tapered shape. The first discharge curve surface 531 may be formed to be curved. The first discharge curve surface 531 may form a center of curvature outside the chamber discharge port 543 and/or the second chamber C2. The first discharge curve surface 531 may be formed to be convex from the outside of the first discharge curve surface 531 to the inside. The first discharge curve surface 531 may have a bell-mouth shape.

The front end of the second discharge curve surface 532 may be connected to the rear end of the first discharge curve surface 531. The second discharge curve surface 532 may gradually become narrower toward the front of the second chamber C2. The second discharge curve surface 532 may form a continuous surface with the first discharge curve surface 531. An inflection point and/or an inflection surface may be formed between the second discharge curve surface 532 and the first discharge curve surface 531. The rear end of the second discharge curve surface 532 may be connected to the front end of the connection surface 55.

The second discharge curve surface 532 may be expanded backward from the rear end of the first discharge curve surface 531 so that the second chamber C2 gradually becomes wider. The second discharge curve surface 532 may have a tapered shape. The second discharge curve surface 532 may be formed to be curved. The second discharge curve surface 532 may form a center of curvature inside the second chamber C2. The second discharge curve surface 532 may be formed to be convex from the inside of the second discharge curve surface 532 to the outside. The center of curvature of the second discharge curve surface 532 may be adjacent to the wick 61 or may overlap with the wick 61.

The second discharge curve surface 532 can gently guide air to pass around the wick 61 and flow into the chamber discharge port 543 while reducing flow resistance. Air passing around the wick 61 may flow between the wick 61 and the second discharge curve surface 532 along the second discharge curve surface 532. The second discharge curve surface 532 can collect the air passing around the wick 61 around the chamber discharge port 543, which is the direction of flow. The second discharge curve surface 532 can prevent a decrease in flow efficiency or eddy currents that occur when air flowing from the periphery of the wick 61 to the chamber discharge port 543 suddenly changes direction.

The first discharge curve surface 531 can gently guide air from around the wick 61 to the chamber discharge port 543 while reducing flow resistance. Air passing around the wick 61 may travel along the first discharge curve surface 531 and collect inside the chamber outlet 543. The first discharge curve surface 531 is formed when the air flowing from around the chamber outlet 543 to the chamber outlet 543 changes direction sharply or due to collision resistance between the air gathering at the chamber outlet 543. Reduction of flow efficiency or eddy currents can be prevented.

Accordingly, the flow efficiency of air flowing from the second chamber C2 or around the wick 61 to the chamber inlet 543 can be improved. Additionally, it is possible to prevent eddy currents from occurring around the wick 61 or near the corners of the second chamber C2. Additionally, the air can entrain aerosols more uniformly. Additionally, the amount of aerosol entrainment in the air can be improved.

Referring to FIGS. 4 and 9 , the wick 61 may extend long in a direction crossing the center line (L). The wick 61 may be arranged perpendicular to the center line (L). The wick 61 may be arranged to extend long from side to side between the chamber inlet 542 and the chamber outlet 543.

The chamber inlet 542 may be open in the front-back direction toward the wick 61. The chamber inlet 542 may be open in a direction crossing the longitudinal direction of the wick 61. The chamber inlet 542 may be formed to have a longer width W2 along the longitudinal direction of the wick 61. The chamber inlet 542 may have a width W2 longer in the left and right directions than the width W1 in the vertical direction.

The chamber outlet 543 may be open in the front-back direction toward the wick 61. The chamber outlet 543 may be open in a direction crossing the longitudinal direction of the wick 61. The chamber outlet 543 may be formed to have a longer width W4 along the longitudinal direction of the wick 61. The chamber outlet 543 has a longer width W4 in the left and right directions than the width W3 in the vertical direction. can be formed.

The inlet curve surface 52 may gradually expand from the chamber inlet 542 toward the periphery of both ends of the wick 61 disposed in the second chamber C2. The width W2 of the first inlet curved surface 521 in the left and right directions may gradually expand from the rear end of the chamber inlet 542 toward the front end. The second inlet curve surface 522 may gradually expand in width from the chamber inlet 542 toward the periphery of both ends of the wick 61.

Accordingly, the air flowing into the second chamber C2 from the chamber inlet 542 can be uniformly spread toward the elongated wick 61. In addition, the flow resistance of air from the chamber inlet 542 to the vicinity of both ends of the wick 61 is reduced, and flow efficiency can be improved by preventing the generation of vortices. Additionally, the amount of aerosol entrainment in the air can be improved.

The discharge curve surface 53 may gradually become narrower toward the chamber discharge port 543 from around both ends of the wick 61 disposed in the second chamber C2. The width W4 of the first discharge curve surface 531 in the left and right directions may gradually become narrower from the rear end of the chamber discharge port 543 toward the front end. The second discharge curve surface 532 may gradually narrow in width from around both ends of the wick 61 toward the chamber discharge port 543.

Accordingly, the air flowing from the second chamber C2 to the chamber outlet 543 can be uniformly collected from the long extended wick 61. In addition, around both ends of the wick 61, the flow resistance of air toward the chamber outlet 543 is reduced, and flow efficiency can be improved by preventing the generation of vortices. Additionally, the amount of aerosol entrainment in the air can be improved.

Referring to FIGS. 10 to 13 , the curved surface may cover only a portion of the second chamber C2. The curved surface may be formed around the chamber outlet 543, and the periphery of the chamber inlet 542 may be covered by the plane 56. A curved surface may be formed around the lower side of the chamber outlet 543, and the remainder may be covered by the flat surface 56. A curved surface may be formed around the upper side of the chamber outlet 543, and the remainder may be covered by the flat surface 56.

The curved surface may be formed around the chamber inlet 542, and the periphery of the chamber outlet 543 may be covered by the plane 56. The curved surface may be formed around the lower side of the chamber inlet 542, and the remainder may be covered by the flat surface 56. The curved surface may be formed on the upper side of the chamber inlet 542, and the remainder may be covered by the flat surface 56.

The curved surface may cover one side of the second chamber C2, and the remaining side may be covered by the flat surface 56. The position where the curved surface is disposed is not limited to the above-described embodiment. The plane 56 may be entirely flat or most of its area may be flat.

Referring to FIG. 14, the second chamber C2 may have a spherical shape. The second inlet curve surface 522 and the second outlet curve surface 532 may be connected to each other. The curvature of the second inlet curve surface 522 and the curvature of the second outlet curve surface 532 may be the same or similar to each other. The center of curvature of the second inlet curve surface 522 and the center of curvature of the second outlet curve surface 532 may be the same or adjacent to each other. The center of curvature of the second inlet curve surface 522 and the center of curvature of the second outlet curve surface 532 may be the same as or adjacent to the center of the wick 61.

Accordingly, it is possible to prevent vortices due to air flow from occurring inside the second chamber C2. Additionally, flow resistance to air flowing around the wick 61 can be reduced and flow efficiency can be improved. Additionally, the amount of aerosol entrained in the air can be increased.

Referring to FIG. 15, the second chamber C2 may be formed in an ellipsoid shape. The second inlet curve surface 522 and the second outlet curve surface 532 may be connected to each other. The second inlet curve surface 522 and the outlet curve surface 532 may be convex outward from the second chamber C2. The front-to-back length D1 of the second chamber C2 may be longer than the vertical length D2 of the second chamber C2. The second chamber C2 may be formed to be longer from the chamber inlet 542 toward the chamber outlet 543. The second chamber C2 may be formed to be longer in the air flow direction. The upper and lower ends of the second chamber C2 may be disposed closer to the wick 61.

Accordingly, the straight flow of air passing through the second chamber C2 is improved, and the reduction in air flow efficiency due to turning in the path can be improved. Additionally, inside the second chamber C2, air flows closer to the wick 61, and the amount or density of aerosol in the air accompanying the aerosol may increase.

Referring to FIG. 16, the channel curve surface 513 and the lower portion of the second inlet curve surface 522 may be integrally connected. The lower portions of the channel curve surface 513 and the second inlet curve surface 522 may form a continuous surface. The channel curve surface 513 and the second inlet curve surface 522 may be convex to the outside of the second chamber C2. The curvature of the channel curve surface 513 and the curvature of the lower part of the second inlet curve surface 522 connected to the channel curve surface 513 may be the same. The curvature of the lower part of the second chamber C2 may be smaller than the curvature of the upper part of the second chamber C2. An inflection point and/or an inflection surface may not be formed between the second channel curve surface 513 and the second inlet curve surface 522.

Accordingly, the air flowing from the inflow channel 541 through the chamber inlet 542 into the second chamber C2 does not rotate, and the straightness of the flow can be improved. Additionally, since the air does not collide with the wall formed around the chamber inlet 542, resistance to flow can be reduced and air flow efficiency can be improved.

Referring to FIG. 17, the first inlet curve surface 521 may be absent. The first discharge curve surface 531 may be absent. Around the chamber inlet 542, the rear side of the second chamber C2 may be covered by the second inlet curved surface 522. Around the chamber discharge port 543, the front side of the second chamber C2 may be covered by the second discharge curve surface 532.

Referring to FIG. 18, the width of the first inlet curve surface 521 may gradually expand from the rear end to the front end of the chamber inlet 542. The width W1 of the rear end of the first inflow curve surface 521 may be the same as the wick 61 or may be similar to the width W0 of the wick 61. The front end width (W10) of the first inflow curve surface 521 may be larger than the width (W0) of the wick 61. The front end of the first inlet curved surface 521 may be connected to the rear end of the connection surface 55. The first inflow curve surface 521 may have a bell mouth shape extending toward the wick 61.

The width of the first discharge curve surface 531 may gradually become narrower from the rear end to the front end of the chamber discharge port 543. The front end width W3 of the first discharge curve surface 531 may be the same as or similar to the wick 61. The width W30 of the rear end of the first discharge curve surface 531 may be larger than the width W0 of the wick 61. The rear end of the first discharge curve surface 531 may be connected to the front end of the connection surface 55. The first discharge curve surface 531 may have a bell mouth shape extending toward the wick 61.

Referring to FIG. 19, the inlet slope 523 may be formed around the chamber inlet 542. The inlet slope 523 may gradually expand forward. The inlet slope 523 may gradually expand toward the wick 61. The inlet slope 523 may be formed to be inclined outward toward the wick 61. The inlet slope 523 may have a cone shape, such as a truncated cone or an elliptical truncated cone. The inlet slope 523 may not have curvature. The inlet slope 523 may be formed between the first inlet curve surface 521 and the second inlet curve surface 522. The inlet slope 523 may connect the first inlet curve surface 521 and the second inlet curve surface 522.

Discharge slope 533 may be formed around the chamber discharge port 543. The discharge slope 533 may gradually become narrower toward the front. The discharge slope 533 may gradually expand toward the wick 61. The discharge slope 533 may be formed to be inclined outward toward the wick 61. The discharge slope 533 may have a cone shape, such as a truncated cone or an elliptical truncated cone. Discharge slope 533 may not have curvature. The discharge slope 533 may be formed between the first discharge curve surface 531 and the second discharge curve surface 532. The discharge slope 533 may connect the first discharge curve surface 531 and the second discharge curve surface 532.

20 to 23, the inlet channel 5410 may be opened on one side of the second container 42 and communicate with the outside of the cartridge 40. The inlet channel 5410 may communicate with the rear end of the chamber inlet 542. The inlet channel 5410 may not be bent. The inlet channel 5410 may be open in the front-to-back direction. The inlet channel 5410 may extend long in the front-to-back direction. The inlet channel 5410 may be formed parallel to the outlet channel 544. The inlet channel 5410 and the outlet channel 544 may face each other.

Accordingly, the length of the flow path flowing into the second chamber C2 from the outside of the cartridge 40 is shortened, and the suction force required for the user to inhale air may be reduced. In addition, when flowing from the inlet channel 5410 toward the chamber inlet 542, the air does not rotate, and the straightness of the air flow inside the cartridge 40 is improved, thereby improving flow efficiency.

Referring to FIG. 24, the baffle 58 may be installed at the chamber inlet 542. The baffle 58 may be installed between the second chamber C2 and the inflow channel 541. The beple 58 may have a plurality of holes. The baffle 58 blocks the chamber inlet 542, and has a plurality of holes so that the second chamber C2 and the inlet channel 541 can communicate with each other. The baffle 58 may have a perforated plate or mesh shape. Air may flow from the inlet channel 541 through the baffle 58 into the second chamber C2. The baffle 58 can equalize the flow rate of air flowing into the second chamber C2.

Accordingly, the air can be evenly spread from the chamber inlet 542 to the surroundings of the second chamber C2 and the wick 61. Additionally, the amount or density of aerosol accompanying the air may increase.

1 to 24, a cartridge 40 according to an aspect of the present disclosure includes a first chamber C1 that stores liquid; a second chamber (C2) having an inlet (542) and an outlet (543); A wick (61) (61) located in the second chamber (C2) and connected to the first chamber (C1); And, it includes a heater 62 that heats the wick 61, and the second chamber C2 is: the second chamber C2 between the inlet 542 and the outlet 543. It may include a curved surface forming at least a portion of.

In addition, according to another aspect of the present disclosure, the second chamber C2 forms the second chamber C2 around the discharge port 543 and has a curved discharge curve surface 53. It can be included.

According to another aspect of the present disclosure, the discharge curve surface 53 surrounds the discharge port 543 and forms a center of curvature outside the second chamber C2, and the second chamber ( It may include a first discharge curve surface 531 that gradually narrows from the inside to the outside of C2).

Also, according to another aspect of the present disclosure, the first discharge curve surface 531 may have a bell-mouth shape.

According to another aspect of the present disclosure, the discharge curve surface 53 is formed to be convex from the inside to the outside of the second chamber C2, and the discharge port 543 is formed from the second chamber C2. ) may include a second discharge curve surface 532 that gradually narrows in the direction toward.

According to another aspect of the present disclosure, the outlet curve surface 53 surrounds the outlet 543 and forms a center of curvature outside the second chamber C2, and the outlet 543 A first discharge curve surface 531 that gradually narrows from the inside to the outside; and is convexly formed from the inside to the outside of the second chamber (C2), gradually narrows in the direction from the second chamber (C2) toward the outlet 543, and has the first discharge curve surface 531 and It may include a second discharge curve surface 532 that is connected to form a continuous surface.

According to another aspect of the present disclosure, the second chamber C2 forms the second chamber C2 around the inlet 542 and has a curved inlet curved surface 52. It can be included.

According to another aspect of the present disclosure, the inlet curved surface 52 surrounds the inlet 542 and forms a center of curvature outside the second chamber C2, and the second chamber ( It may include a first inlet curve surface 521 that gradually expands from the outside to the inside of C2).

Also, according to another aspect of the present disclosure, the first inlet curve surface 521 may have a bell mouth shape.

Also, according to another aspect of the present disclosure, the inlet curved surface 52 is formed to be convex from the inside to the outside of the second chamber C2, and extends from the inlet 542 to the second chamber C2. ) may include a second inlet curve surface 522 that gradually expands in the direction toward.

According to another aspect of the present disclosure, the inlet curved surface 52 surrounds the inlet 542 and forms a center of curvature outside the second chamber C2, and the second chamber ( A first inlet curve surface 521 that gradually narrows from the inside to the outside of C2); and is convexly formed from the inside to the outside of the second chamber (C2), gradually expands in the direction from the inlet 542 toward the second chamber (C2), and is connected to the first inlet curved surface 521. It may include a second inlet curved surface 522 that forms a continuous surface.

According to another aspect of the present disclosure, the wick 61 is disposed to extend long to one side between the inlet 542 and the outlet 543, and the inlet 542 is It is opened toward the wick 61 in a direction crossing the longitudinal direction of the wick 61, and the width W2 may be formed to be longer along the longitudinal direction of the wick 61.

According to another aspect of the present disclosure, the discharge port 543 is opened toward the wick 61 in a direction crossing the longitudinal direction of the wick 61, and the length of the wick 61 The width W4 may be formed to be longer along the direction.

According to another aspect of the present disclosure, the second chamber C2 gradually expands from the inlet 542 toward the periphery of both ends of the wick 61 to form the second chamber C2. It may include an inflow curve surface 52.

According to another aspect of the present disclosure, the second chamber C2 gradually narrows from around both ends of the wick 61 toward the outlet 543 to form the second chamber C2. It may include a discharge curve surface 53 that does.

Also, according to another aspect of the present disclosure, the second chamber C2 may have a spherical shape.

Also, according to another aspect of the present disclosure, the second chamber C2 may have an ellipsoid shape extending long from the inlet 542 toward the outlet 543.

According to another aspect of the present disclosure, the cartridge 40 extends long in a direction crossing the direction in which the inlet 542 is opened, and is bent toward the inlet 542 to open the inlet 542. ) an inflow channel (541) in communication with; And it may further include a channel curve surface 513 that is curved at a bent portion of the inlet channel 541 and covers one side of the inlet channel 541.

Also, according to another aspect of the present disclosure, the second chamber (C2) forms the second chamber (C2) around the inlet (542) and inside the second chamber (C2). It forms the center of curvature and may include a second inlet curve surface 522 that is connected to the channel curve surface 513 and has a portion that forms a continuous surface.

According to another aspect of the present disclosure, the cartridge 40 has the inlet 542 and the outlet 543 opened to face each other with the wick 61 in between, and the inlet ( 542) and the outside, and may further include an inflow channel 541 extending in one direction toward the wick 61.

According to another aspect of the present disclosure, the cartridge 40 may further include a baffle 58 installed in the inlet 542 and having a plurality of holes.

In addition, a cartridge 40 according to another aspect of the present disclosure includes a first chamber C1 for storing liquid; a second chamber (C2) having an inlet 542 and an outlet 543; A wick (61) located in the second chamber (C2) and connected to the first chamber (C1); And, it includes a heater 62 that heats the wick 61, and the second chamber C2 is: at least one of the inlet 542 and the outlet 543 from the periphery of the wick 61. It may include a surface that gradually narrows toward and forms the second chamber C2.

Any or other embodiments of the present disclosure described above are not exclusive or distinct from each other. Certain embodiments or other embodiments of the present disclosure described above may have their respective components or functions combined or combined (Certain embodiments or other embodiments of the disclosure described above are not mutually exclusive or distinct from each other. Any or all elements of the embodiments of the disclosure described above may be combined with another or combined with each other in configuration or function).

For example, this means that configuration A described in a particular embodiment and/or drawing may be combined with configuration B described in other embodiments and/or drawings. In other words, even if the combination between configurations is not directly explained, this means that the combination is possible except in cases where the combination is described as impossible (For example, a configuration "A" described in one embodiment of the disclosure and the drawings and a configuration "B" described in another embodiment of the disclosure and the drawings may be combined with each other. Namely, although the combination between the configurations is not directly described, the combination is possible except in the case where it is described that the combination is impossible).

The above detailed description should not be construed as restrictive in any respect and should be considered illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included within the scope of the present invention (Although embodiments have been described with reference to a number of illustrative embodiments Thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the scope of the principles of this disclosure.More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art).

Claims (21)

a first chamber storing liquid;
a second chamber having an inlet and an outlet;
a wick located in the second chamber and connected to the first chamber; and,
Including a heater that heats the wick,
The second chamber:
comprising a curved surface forming at least a portion of the second chamber between the inlet and the outlet;
The curved surface is,
The second chamber is formed around the outlet and has a curved discharge curve surface and
A cartridge forming the second chamber around the inlet and including at least one of a curved inlet curved surface. delete According to claim 1,
The discharge curve surface is,
A cartridge comprising a first discharge curve surface surrounding the discharge port, forming a center of curvature outside the second chamber, and gradually narrowing from the inside to the outside of the second chamber. According to clause 3,
The first discharge curve surface is,
A cartridge with a bell-mouth shape. According to claim 1,
The discharge curve surface is,
A cartridge comprising a second discharge curve surface that is convex from the inside to the outside of the second chamber and gradually narrows in a direction from the second chamber toward the discharge port. According to claim 1,
The discharge curve surface is,
a first discharge curve surface surrounding the outlet, forming a center of curvature outside the second chamber, and gradually narrowing from the inside to the outside of the outlet; and
A second discharge curve surface is formed to be convex from the inside of the second chamber toward the outside, gradually narrows in the direction from the second chamber toward the outlet, and is connected to the first discharge curve surface to form a continuous surface. A cartridge containing a. delete According to claim 1,
The inlet curve surface is,
A cartridge comprising a first inlet curved surface surrounding the inlet, forming a center of curvature outside the second chamber, and gradually expanding from the outside toward the inside of the second chamber. According to clause 8,
The first inlet curve surface is,
A cartridge with a bell mouth shape. According to claim 1,
The inlet curve surface is,
A cartridge comprising a second inlet curved surface that is convex from the inside to the outside of the second chamber and gradually expands in a direction from the inlet toward the second chamber. According to claim 1,
The inlet curve surface is,
a first inlet curved surface surrounding the inlet, forming a center of curvature outside the second chamber, and gradually narrowing from the inside to the outside of the second chamber; and
A second inlet curve surface is convexly formed from the inside to the outside of the second chamber, gradually expands in the direction from the inlet toward the second chamber, and is connected to the first inlet curve surface to form a continuous surface. Cartridges included. According to claim 1,
The wick is,
disposed to extend long to one side between the inlet and the outlet,
At least one of the inlet and the outlet,
A cartridge that opens toward the wick in a direction crossing the longitudinal direction of the wick and is formed to be longer in width along the longitudinal direction of the wick. According to claim 12,
The second chamber is,
A cartridge comprising an inlet curved surface that gradually extends from the inlet toward the periphery of both ends of the wick and forms the second chamber. According to claim 12,
The second chamber is,
A cartridge comprising a discharge curved surface that gradually narrows from around both ends of the wick toward the discharge port and forms the second chamber. According to claim 1,
The second chamber is,
A cartridge having a spherical shape. According to claim 1,
The second chamber is,
A cartridge having an ellipsoidal shape extending long from the inlet toward the outlet. According to claim 1,
an inlet channel extending long in a direction crossing the direction in which the inlet is opened, and being bent toward the inlet and communicating with the inlet; and
The cartridge further includes a channel curve surface that is curved at a bent portion of the inlet channel and covers one side of the inlet channel. According to claim 17,
The second chamber is,
It includes a second inlet curve surface that forms the second chamber around the inlet, forms a center of curvature inside the second chamber, and has a portion connected to the channel curve surface to form a continuous surface. A cartridge that does. According to claim 1,
The inlet and the outlet are,
are opened to face each other with the wick in between,
The cartridge communicates with the inlet and the outside, and further includes an inlet channel extending in one direction toward the wick. According to claim 1,
A cartridge installed in the inlet and further comprising a baffle having a plurality of holes. delete

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