ATOMIZATION CORE, ATOMIZER, AND ELECTRONIC ATOMIZATION DEVICE

Abstract

An atomization core includes: a seat comprising an atomization chamber; a liquid guiding member arranged inside the atomization chamber for guiding an aerosol-generating substrate; a heating component arranged on the liquid guiding member and for atomizing, when energized, the aerosol-generating substrate; and an electrode lead electrically connected to the heating component and fixing the heating component to the liquid guiding member.

Description

CROSS-REFERENCE TO PRIOR APPLICATION

This application is a continuation of International Patent Application No. PCT/CN2021/125395, filed on Oct. 21, 2021. The entire disclosure is hereby incorporated by reference herein.

FIELD

The present invention relates to the field of electronic atomization device technologies, and in particular, to an atomization core, an atomizer, and an electronic atomization device.

BACKGROUND

An atomization core is a device configured to heat and atomize, when energized, an aerosol-generating substrate, to form an aerosol that can be consumed by a user.

At present, the atomization core generally includes a liquid absorption sponge and a heating component. The liquid absorption sponge is configured to guide the aerosol-generating substrate. The heating component is arranged on the liquid absorption sponge and configured to heat and atomize, when energized, the aerosol-generating substrate, to form the aerosol.

However, it is difficult for the existing atomization core to ensure that the liquid absorption sponge and the heating component always fit each other, which may easily lead to the problem that dry heating of the heating component produces an inhaled burnt smell.

SUMMARY

In an embodiment, the present invention provides an atomization core, comprising: a seat comprising an atomization chamber; a liquid guiding member arranged inside the atomization chamber and configured to guide an aerosol-generating substrate; a heating component arranged on the liquid guiding member and configured to atomize, when energized, the aerosol-generating substrate; and an electrode lead electrically connected to the heating component and fixing the heating component to the liquid guiding member.

BRIEF DESCRIPTION OF THE DRAWINGS

Subject matter of the present disclosure will be described in even greater detail below based on the exemplary figures. All features described and/or illustrated herein can be used alone or combined in different combinations. The features and advantages of various embodiments will become apparent by reading the following detailed description with reference to the attached drawings, which illustrate the following:

FIG. 1 is a schematic structural diagram of an electronic atomization device according to an embodiment of this application;

FIG. 2 is a schematic structural diagram of an atomizer according to an embodiment of this application;

FIG. 3 is a cross-sectional view along a direction A-A of the atomizer shown in FIG. 2 according to a first embodiment of this application;

FIG. 4 is an exploded view of the atomizer shown in FIG. 2 according to the first embodiment of this application;

FIG. 5a is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 4 except for a first sealing member;

FIG. 5b is a cross-sectional view along a direction B-B of the atomization core shown in FIG. 5a;

FIG. 6 is a schematic structural diagram of a first seat body according to an embodiment of this application;

FIG. 7 is a schematic structural diagram of a liquid guiding member, a heating component, and an electrode lead being arranged inside a first groove according to an embodiment of this application;

FIG. 8 is a schematic structural diagram of a second seat body under a first view according to the first embodiment of this application;

FIG. 9 is a schematic structural diagram of a second seat body under a second view according to the first embodiment of this application;

FIG. 10 is a schematic structural diagram of a heating component according to an embodiment of this application;

FIG. 11 is a schematic diagram of a stress-bearing part of a heating component according to an embodiment of this application;

FIG. 12 is a diagram of deformation of the heating component corresponding to FIG. 11 after being stressed;

FIG. 13 is a schematic diagram of a stress-bearing part of a heating component according to another embodiment of this application;

FIG. 14 is a diagram of deformation of the heating component corresponding to FIG. 13 after being stressed;

FIG. 15a is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 4;

FIG. 15b is a perspective view of an atomization core of the atomizer shown in FIG. 4;

FIG. 15c is a cross-sectional view along a direction B-B of the atomization core shown in FIG. 15b;

FIG. 16 is an exploded view of the atomizer shown in FIG. 2 according to a second embodiment of this application;

FIG. 17a is a schematic exploded view of an atomization core in the atomizer shown in FIG. 16 according to an embodiment of this application;

FIG. 17b is a schematic exploded view of an atomization core in the atomizer shown in FIG. 16 according to another embodiment of this application;

FIG. 18 is a schematic structural diagram of a liquid guiding member, a heating component, and an electrode lead being arranged inside a first groove according to another embodiment of this application;

FIG. 19 is a top view of an atomization core according to an embodiment of this application;

FIG. 20 is a first schematic structural diagram of a fixing portion according to this application;

FIG. 21 is a second schematic structural diagram of a fixing portion according to this application;

FIG. 22 is a second schematic structural diagram of a fixing portion according to this application;

FIG. 23 is a fourth schematic structural diagram of a fixing portion according to this application;

FIG. 24 is a schematic diagram of positions between a liquid level and a liquid inlet hole when an atomization core according to an embodiment of this application is placed obliquely;

FIG. 25a is an exploded view of the atomizer shown in FIG. 2 according to a third embodiment of this application;

FIG. 25b is a cross-sectional view along a direction B-B of the atomizer shown in FIG. 25a;

FIG. 26 is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 25b;

FIG. 27a is a cross-sectional view along a direction B-B of the atomizer shown in FIG. 2 according to the second embodiment of this application;

FIG. 27b is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 27a;

FIG. 28a is a schematic structural diagram of an atomizer according to another embodiment of this application;

FIG. 28b is a cross-sectional view along a direction B-B of the atomizer shown in FIG. 28a; and

FIG. 28c is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 28b.

DETAILED DESCRIPTION

In an embodiment, the present invention provides an atomization core, an atomizer, and an electronic atomization device. The atomization core can resolve the problem that dry heating of the heating component producing an inhaled burnt smell is likely to occur because the existing atomization core cannot ensure that a liquid absorption sponge and a heating component always fit each other.

In an embodiment, the present invention provides an atomization core. The atomization core includes: a seat, a liquid guiding member, a heating component, and an electrode lead. The seat includes an atomization chamber. The liquid guiding member is arranged inside the atomization chamber, and configured to guide an aerosol-generating substrate. The heating component is arranged on the liquid guiding member, and configured to atomize, when energized, the aerosol-generating substrate. The electrode lead is electrically connected to the heating component and fixes the heating component to the liquid guiding member.

The heating component includes a heating element and a first pin and a second pin arranged on the two sides of the heating element. The electrode lead includes a positive electrode lead and a negative electrode lead. An abutting portion of the positive electrode lead is electrically connected to and abuts against the first pin, to fix the first pin of the heating component to the liquid guiding member; and/or an abutting portion of the negative electrode lead is electrically connected to and abuts against the second pin, to fix the second pin of the heating component to the liquid guiding member.

The seat further includes an air outlet opening in communication with the atomization chamber. The abutting portion of the positive electrode lead is arranged on the side of the heating element close to the air outlet opening along the air outlet path of the atomization core, and the abutting portion of the negative electrode lead is arranged on the side of the heating element away from the air outlet opening along the air outlet path of the atomization core; or the abutting portion of the negative electrode lead is arranged on the side of the heating element close to the air outlet opening along the air outlet path of the atomization core, and the abutting portion of the positive electrode lead is arranged on the side of the heating element away from the air outlet opening along the air outlet path of the atomization core.

The abutting portion of the positive electrode lead and the abutting portion of the negative electrode lead extend along the two side edges of the heating component respectively. The abutting portion of the positive electrode lead and the abutting portion of the negative electrode lead are parallel to each other.

The abutting portion of the positive electrode lead and the abutting portion of the negative electrode lead extend toward opposite directions.

The abutting portion of the positive electrode lead is bent into a first curved portion, and the first curved portion extends along the first pin and abuts against the first pin. The abutting portion of the negative electrode lead is bent into a second curved portion, and the second curved portion extends along the second pin and abuts against the second pin.

The first pin and the second pin are curved in the direction of the air outlet path of the atomization core. In addition, the radian of the first curved portion matches that of the first pin. The radian of the second curved portion matches that of the second pin.

The electrode lead includes an abutting portion and a lead portion. The abutting portion is the extension of the lead portion.

A lead portion of the positive electrode lead is bent relative to the abutting portion of the positive electrode lead and extend toward the direction of the atomization chamber facing away from the air outlet opening, and is configured to connect the positive electrode of the power supply assembly; and/or a lead portion of the negative electrode lead is bent relative to the abutting portion of the negative electrode lead and extend toward the direction of the atomization chamber facing away from the air outlet opening, and is configured to connect the negative electrode of the power supply assembly. The bending place of the positive electrode lead and the bending place of the negative electrode lead are located at two opposite corners of the heating component.

The seat includes a first seat body and a second seat body. The first seat body is provided with a first groove. The liquid guiding member and the heating component are arranged in the first groove. The second seat body forms the atomization chamber with the first seat body, and abuts against the heating component to fix the heating component to the liquid guiding member.

The first seat body is further provided with an air outlet opening in communication with the first groove. The second seat body abuts against a first side edge and a second side edge of the heating element respectively. The first side edge and the second side edge are located on two sides of the air outlet opening along a direction perpendicular to the air outlet path of the atomization core.

The side surface of the second seat body facing toward the first seat body includes a first sidewall and a second sidewall that are opposite to each other. The first sidewall and the second sidewall abut against the first side edge and the second side edge respectively.

The vertical distance between the first sidewall and/or the second sidewall and the bottom wall of the first groove is less than the thickness of the liquid guiding member.

The side surface of the first seat body facing toward the second seat body is further provided with a plurality of first liquid absorption slots; and/or the side surface of the second seat body facing toward the first seat body is further provided with a plurality of second liquid absorption slots. The first liquid absorption slots and the second liquid absorption slots are all in communication with the bottom of the atomization chamber, to guide, through the capillary force, the aerosol-generating substrate flowing out from the bottom of the atomization chamber into the first liquid absorption slots and/or the second liquid absorption slots.

The seat is further provided with an air outlet opening in communication with the atomization chamber. The plurality of first liquid absorption slots are located on the side of the first groove facing away from the air outlet opening; and the plurality of second liquid absorption slots are arranged opposite to the plurality of first liquid absorption slots.

The side surface of the second seat body facing toward the first seat body is further provided with a plurality of third liquid absorption slots. The plurality of third liquid absorption slots are in communication with the atomization chamber and are configured to guide, through the capillary force, the aerosol-generating substrate flowing from the sidewall of the atomization chamber to the third liquid absorption slots.

The side surface of the second seat body facing toward the first seat body includes a first sidewall and a second sidewall that are opposite to each other, where the first sidewall and the second sidewall abut against the first side edge and the second side edge of the heating component, and the plurality of third liquid absorption slots are provided on the side of the first sidewall facing away from the second sidewall, and/or are provided on the side of the second sidewall facing away from the first sidewall.

One of the first seat body and the second seat body includes a buckle, the other seat body includes a buckle hole, and the second seat body abuts against the heating component through engagement between the buckle and the buckle hole.

The liquid guiding member is a curved liquid absorption sponge; and the heating component is a curved metal heating mesh. The radian range of the liquid guiding member is 20° to 55°.

To resolve the foregoing technical problems, another technical solution adopted by this application is to provide an atomizer. The atomizer includes a housing and an atomization core. The atomization core is arranged inside the housing, and cooperates with the housing to form a liquid storage chamber. The atomization core is the atomization core mentioned above.

To resolve the foregoing technical problems, still another technical solution adopted by this application is to provide an electronic atomization device. The electronic atomization device includes the atomizer mentioned above and a power supply assembly. The power supply assembly is connected to the atomizer and configured to supply power to the atomizer.

This application provides the atomization core, the atomizer, and the electronic atomization device. For the atomization core, the seat and the liquid guiding member are arranged such that the liquid guiding member is arranged inside the atomization chamber of the seat, to guide the aerosol-generating substrate through the liquid guiding member. In addition, the heating component is arranged such that the heating component is arranged on the liquid guiding member, to atomize the aerosol-generating substrate when the heating component is energized. Moreover, the electrode lead is arranged such that the electrode lead is electrically connected to the heating component and fixes the heating component to the liquid guiding member. Fixing the heating component to the liquid guiding member through the electrode lead can effectively improve the fit between the heating component and the liquid guiding member, to avoid the problem that dry heating of the heating component produces an inhaled burnt smell. Moreover, compared with another fixing member, the electrode lead has less impact on suction resistance of airflows.

DESCRIPTION OF REFERENCE SIGNS

electronic atomization device 100; atomizer 101/101a; housing 10a; mouthpiece 11; air outlet channel 12; atomization core 20; liquid storage chamber 201a; power supply assembly 102;

first type of atomization core 20a; base 21, seat 22, atomization chamber 220; first seat body 221, wire outlet hole 2211; first groove 2212; first liquid inlet hole 2213; air outlet opening 2214; first liquid absorption slot 2215; positioning post 2216; positioning hole 2217; fixing hole 2218; second seat body 222; first sidewall 2221; second sidewall 2222; second groove 2223; second liquid absorption slot 2224; third liquid absorption slot 2225; ventilation slot 2226; material reduction slot 2227; liquid guiding member 23, heating component 24, heating element 241; first pin 242; second pin 243; electrode lead 25a; positive electrode lead 251a, abutting portion 2511a of the positive electrode lead, lead portion 2512a of the positive electrode lead; negative electrode lead 252a; abutting portion 2521a of the negative electrode lead; lead portion 2522a of the negative electrode lead;

second type of atomization core 20b; first sealing member 26a; second liquid inlet hole 261; ventilation hole 262; liquid injection port steel ring 27; mouthpiece cover 28; second sealing member 29; third sealing member 30; ejector pin 31; magnet 32;

third type of atomization core 20c; electrode lead 25b; positive electrode lead 251b, abutting portion 2511b of the positive electrode lead, lead portion 2512b of the positive electrode lead; negative electrode lead 252b; abutting portion 2521b of the negative electrode lead; lead portion 2522b of the negative electrode lead; extending portion 253 of the positive electrode lead; extending portion 254 of the negative electrode lead;

atomizer 101b; fourth type of atomization core 20d; fixing portion 33; first extending wall 33a; second extending wall 33b; first through hole 331b; third extending wall 33c; second through hole 331c; bump 33d;

atomizer 101c; atomization core 20e; liquid inlet hole 34; bottom surface D of the liquid storage chamber; highest position E of the bottom surface of the liquid storage chamber; lowest position F of the liquid inlet hole; sleeve portion 200a; atomization portion 200b; groove 35; communication hole 36; first communication hole 36a; second communication hole 36b; third communication hole 36c;

atomizer 101d/101e; housing 10b; atomization core 20f/20g; sleeve portion 200c; atomization portion 200d.

The technical solutions in embodiments of this application are clearly and completely described below with reference to the accompanying drawings in the embodiments of this application. Apparently, the described embodiments are merely some rather than all of the embodiments of this application. All other embodiments obtained by a person of ordinary skill in the art based on embodiments of this application without creative efforts shall fall within the protection scope of this application.

The terms “first”, “second”, and “third” in this application are merely intended for a purpose of description, and shall not be understood as an indication or implication of relative importance or implicit indication of the number of indicated technical features. Therefore, features defining “first”, “second”, and “third” can explicitly or implicitly include at least one of the features. In the description of this application, “a plurality of” means at least two, such as two and three unless it is specifically defined otherwise. All directional indications (for example, up, down, left, right, front, back . . . ) in the embodiments of the present disclosure are only used for explaining relative position relationships, movement situations or the like between the various components in a specific posture (as shown in the accompanying drawings). If the specific posture changes, the directional indications change accordingly. In addition, the terms “including”, “having”, or any other variant thereof are intended to cover a non-exclusive inclusion. For example, a process, a method, a system, a product, or a device that includes a series of steps or units is not limited to the listed steps or units, but optionally further includes unlisted steps or units, or optionally further includes other inherent steps or units of the process, the method, the product, or the device.

An “embodiment” mentioned in this specification means that a particular feature, structure, or characteristic described with reference to this embodiment may be included in at least one embodiment of this application. The phrase appear at various positions in this specification may neither necessarily mean a same embodiment, nor mean an independent or optional embodiment exclusive from another embodiment. It is explicitly and implicitly understood by a person skilled in the art that embodiments described in the specification may be combined with another embodiment.

This application is described below in detail with reference to the accompanying drawings and specific embodiments.

Referring to FIG. 1, FIG. 1 is a schematic structural diagram of an electronic atomization device according to an embodiment of this application. In this embodiment, an electronic atomization device 100 is provided. The electronic atomization device 100 may be configured to atomize an aerosol-generating substrate, to form an aerosol for a user to inhale. The aerosol-generating substrate may be a plant grass substrate, a paste substrate, or the like. Specifically, the electronic atomization device 100 includes an atomizer 101 and a power supply assembly 102.

The atomizer 101 may be used in different fields, for example, the medical atomization field and the electronic atomization field. The atomizer 101 is specifically configured to heat and atomize, when energized, the aerosol-generating substrate, to form the aerosol. Specifically, the atomizer 101 may be an atomizer 101 involved in any one of the following embodiments. For the specific structures and functions of the atomizer 101, reference may be made to the descriptions of the specific structures and functions of the atomizer 101 in the following embodiments. In addition, the same or similar technical effects may be achieved. For details, reference may be made to the following text.

The power supply assembly 102 is connected to the atomizer 101 and configured to supply power to the atomizer 101. The atomizer 101 and the power supply assembly 102 may be detachably connected, to facilitate replacing the atomizer 101, thereby improving the utilization of the power supply assembly 102. Certainly, in another embodiment, the power supply assembly 102 and the atomizer 101 may also be integrally arranged, which is not limited in this application.

Referring to FIG. 2 to FIG. 4, FIG. 2 is a schematic structural diagram of an atomizer according to an embodiment of this application; FIG. 3 is a cross-sectional view along a direction A-A of the atomizer shown in FIG. 2 according to a first embodiment of this application; and FIG. 4 is an exploded view of the atomizer shown in FIG. 2 according to the first embodiment of this application. In this embodiment, an atomizer 101a is provided. The atomizer 101a includes a housing 10a and an atomization core 20.

As shown in FIG. 3 and FIG. 4, the housing 10a includes an accommodating cavity. The atomization core 20 is arranged inside the accommodating cavity, and cooperates with a surface of an inner wall of the housing 10a to form a liquid storage chamber 201a. The liquid storage chamber 201a is configured to store an aerosol-generating substrate. In a specific embodiment, the atomization core 20 is configured to heat and atomize, when energized, the aerosol-generating substrate from the liquid storage chamber 201a, to form an aerosol. Specifically, referring to FIG. 3, the housing 10a further includes a mouthpiece 11 and an air outlet channel 12. The mouthpiece 11 may be formed above the atomizer 101a along the length direction of the atomizer 101a. The air outlet channel 12 is in communication with the mouthpiece 11 and the atomization core 20. The aerosol obtained after the aerosol-generating substrate is atomized flows out from the mouthpiece 11 through the air outlet channel 12 for the user to inhale. The atomization core 20 may be an atomization core involved in any one of the following embodiments. For the specific structures and functions of the atomization core 20, reference may be made to the following related text descriptions.

Referring to FIG. 3 to FIG. 5b, FIG. 5a is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 4 except for a first sealing member; and FIG. 5b is a cross-sectional view along a direction B-B of the atomization core shown in FIG. 5a. In this embodiment, a first type of atomization core 20a is provided. The atomization core 20a includes: a base 21, a seat 22 arranged on the base 21, a liquid guiding member 23, a heating component 24, and an electrode lead 25a.

As shown in FIG. 5b, the base 21 includes a receiving groove, and the seat 22 is embedded in the receiving groove of the base 21. In addition, an atomization chamber 220 and a first liquid inlet hole 2213 in communication with the atomization chamber 220 are formed on the seat 22. An aerosol-generating substrate specifically enters the atomization chamber 220 through the first liquid inlet hole 2213. In an implementation, one first liquid inlet hole 2213 is provided on the seat 22, and the first liquid inlet hole 2213 is formed on a side surface of the seat 22, that is, the first liquid inlet hole 2213 is opposite to a side surface of the housing 10a, to implement one-way liquid inlet from the side surface of the atomization core 20a, which is used as an example in all the following embodiments. Certainly, a plurality of first liquid inlet holes 2213 may 2213 may alternatively be provided on the seat 22, and the plurality of first liquid inlet holes 2213 may be opposite to a side surface of the housing 10a. The liquid guiding member 23 is arranged inside the atomization chamber 220, and configured to guide the aerosol-generating substrate that enters the atomization chamber 220 from the first liquid inlet hole 2213. The heating component 24 is arranged on the side surface of the liquid guiding member 23 facing away from the first liquid inlet hole 2213 and configured to atomize, when energized, the aerosol-generating substrate, to form the aerosol for the user to inhale. The electrode lead 25a includes an abutting portion and a lead portion that are connected to each other. In an implementation, the abutting portion is the extension of the lead portion. The abutting portion of the electrode lead 25a is electrically connected to the heating component 24 and fixes the heating component 24 to the liquid guiding member 23, to improve the fit between the two to avoid the problem of dry heating of the heating component 24. The lead portion is connected to one end of the abutting portion, configured to connect to the power supply assembly 102.

Since the liquid guiding member 23 is arranged in the whole circumferential direction of the atomization chamber 220, that is, the liquid guiding member 23 is in a closed loop shape, when the size of the liquid guiding member 23 is small, a liquid film is easily formed on the liquid guiding member 23, resulting in the problem of inhaling the leaked liquid. Therefore, the liquid guiding member 23 may be curved, and the radian range of the liquid guiding member 23 may be 20° to 55°. The liquid guiding member 23 may be specifically a curved liquid absorption sponge. The heating component 24 may be a curved metal heating mesh, and the radian of the curved liquid absorption sponge is consistent with that of the curved metal heating mesh, to help the two fit perfectly and reduce the probability of the dry heating problem of the heating component 24.

As shown in FIG. 4, the seat 22 includes a first seat body 221 and a second seat body 222. The first seat body 221 and the second seat body 222 have a curved structure, and the first seat body 221 and the second seat body 222 are detachably connected and cooperate to form the atomization chamber 220.

As shown in FIG. 6, FIG. 6 is a schematic structural diagram of a first seat body 221 according to an embodiment of this application. The first seat body 221 includes a first installation portion and a first engagement portion. The first installation portion is embedded in the receiving groove, to be installed and fixed onto the base 21. In addition, the first installation portion is provided with a wire outlet hole 2211 for the electrode lead 25a to pass through. The first engagement portion and the first installation portion are integrally formed, and a first groove 2212 is provided on the side surface of the first engagement portion facing toward the second seat body 222. The second seat body 222 cooperates with the first groove 2212 of the first seat body 221 to form the atomization chamber 220.

The first groove 2212 may be a curved groove, and the first liquid inlet hole 2213 is specifically provided on the bottom wall of the first groove 2212. In a specific embodiment, as shown in FIG. 7, FIG. 7 is a schematic structural diagram of the liquid guiding member 23, the heating component 24, and the electrode lead 25a being arranged inside the first groove 2212 according to an embodiment of this application. The liquid guiding member 23 is arranged in fit with the bottom wall of the first groove 2212 and covers the first liquid inlet hole 2213, to guide the aerosol-generating substrate in the first liquid inlet hole 2213 to the side of the liquid guiding member 23 facing away from the first liquid inlet hole 2213.

In an implementation, the first liquid inlet hole 2213 overlaps with a high-temperature region of the heating component 24. That is, the projection of the high-temperature region of the heating component 24 along the stacking direction of the heating component 24 and the liquid guiding member 23 is at least partially located in the region in which the first liquid inlet hole 2213 is located, to increase the atomization amount.

The high-temperature region of the heating component 24 refers to the middle region of the heating component 24, and the temperature corresponding to the high-temperature region is greater than is equal to 240°. In a specific embodiment, the area of the first liquid inlet hole 2213 is greater than or equal to the area of the high-temperature region of the heating component 24, and the projection of the high-temperature region of the heating component 24 along the stacking direction of the heating component 24 and the liquid guiding member 23 is completely located in the region in which the first liquid inlet hole 2213 is located. In addition, it has been proved by experiments that the first liquid inlet hole 2213 is a place at which the aerosol-generating substrate is densest. Therefore, maintaining the high temperature at the position of the first liquid inlet hole 2213 is conducive to the atomization of the aerosol-generating substrate, thereby sufficiently generating the aerosol.

Further, referring to FIG. 6 or FIG. 7, the first engagement portion is further provided with an air outlet opening 2214. The air outlet opening 2214 is in communication with the first groove 2212 and is specifically located on a sidewall of the first groove 2212. In a specific embodiment, the aerosol formed through atomization inside the atomization chamber 220 specifically flows out through the air outlet opening 2214. The air outlet opening 2214 may be arranged at a position above the first groove 2212 along the direction of the air outlet path C of the atomization core 22a.

Further, as shown in FIG. 6 or FIG. 7, a plurality of first liquid absorption slots 2215 are provided on the side surface of the first installation portion facing toward the second seat body 222. The plurality of first liquid absorption slots 2215 are in communication with the bottom of the atomization chamber 220, and the plurality of first liquid absorption slots 2215 may be specifically located on the side of the first groove 2212 facing away from the air outlet opening 2214, to guide, through the capillary force, the aerosol-generating substrate flowing out from the bottom of the atomization chamber 220 into the first liquid absorption slots 2215, to avoid the leakage problem. The first liquid absorption slot 2215 mayextend in the direction facing away from the air outlet opening 2214, and the plurality of first liquid absorption slots 2215 may be spaced apart along the circumferential direction of the first seat body 221. It should be noted that in the embodiments involved in this application, the bottom of the atomization chamber 220 specifically refers the lower part of the atomization chamber 220 according to the orientation shown in FIG. 3. The sidewall of the atomization chamber 220 specifically refers to the left and right sides of the atomization chamber 220 according to the orientation shown in FIG. 3.

Referring to FIG. 8, FIG. 8 is a schematic structural diagram of the second seat body 222 under a first view according to the first embodiment of this application. The second seat body 222 includes a second installation portion and a second engagement portion. The second installation portion is embedded in the receiving groove, to be installed and fixed onto the base 21. The second engagement portion and the second installation portion are integrally formed, and the side surface of the second engagement portion facing toward the first seat body 221 includes a first sidewall 2221 and a second sidewall 2222 that are opposite to each other. In addition, the first sidewall 2221, the second sidewall 2222, and the second engagement portion define a second groove 2223. The second groove 2223 is a curved groove.

After the second seat body 222 is connected and fixed to the first seat body 221, the first sidewall 2221 abuts against a first side edge of the heating component 24, and the second sidewall 2222 abuts against the second side edge of the heating component 24, to fix the first side edge and the second side edge at the two edges of the heating component 24 to the liquid guiding member 23 through the second seat body 222, to prevent the liquid guiding member 23 from being separated from the heating component 24 and causing the problem that dry heating of the heating component 24 produces an inhaled burnt smell. Referring to FIG. 7, the first side edge and the second side edge of the heating component 24 are respectively located on the two sides of the air outlet opening 2214 along the circumferential direction of the first seat body 221. In this case, the first sidewall 2221 and the second sidewall 2222 of the second seat body 222 are also located on the two sides of the air outlet opening 2214 along the circumferential direction of the first seat body 221, to fix the heating component 24 from the two sides of the air outlet opening 2214, thereby avoiding, while fixing the heating component 24, the first sidewall 2221 and the second sidewall 2222 from blocking the suction airflow in the atomization chamber 220.

Further, the first side edge and the second side edge of the heating component 24 are arranged correspondingly to a first side edge and a second side edge of the liquid guiding member, to prevent, while fixing the heating component 24 to the liquid guiding member 23 at the first sidewall 2221 and the second sidewall 2222, the two sides of the liquid guiding member 23 from bulging.

Further, the vertical distance between the first sidewall 2221 and/or second sidewall 2222 and the bottom wall of the first groove 2212 is less than the thickness of the heating component 24, to ensure that the heating component 24 perfectly fits the liquid guiding member 23.

As shown in FIG. 8, a plurality of second liquid absorption slots 2224 are further provided on the side surface of the second installation portion facing toward the first seat body 221. The plurality of second liquid absorption slots 2224 are also in communication with the bottom of the atomization chamber 220, and the plurality of second liquid absorption slots 2224 may be located at the bottom of the second groove 2223 along the direction in which the second installation portion is connected to the second engagement portion and are arranged opposite to the plurality of first liquid absorption slot 2215, to guide, through the capillary force, the aerosol-generating substrate flowing out from the bottom of the atomization chamber 220 into the second liquid absorption slots 2224 for storage, thereby further reducing the probability of the leakage problem.

In an embodiment, as shown in FIG. 8, the side surface of the second engagement portion of the second seat body 222 facing toward the first seat body 221 is further provided with a plurality of third liquid absorption slots 2225. The plurality of third liquid absorption slots 2225 are provided on the side of the first sidewall 2221 facing away from the second sidewall 2222, and/or provided on the side of the second sidewall 2222 facing away from the first sidewall 2221. That is, the plurality of third liquid absorption slots 2225 are provided on one side and/or two sides of the second groove 2223, to guide, through the capillary force, the aerosol-generating substrate flowing out from the sidewall of the atomization chamber 220 to the third liquid absorption slots 2225 for storage, avoid the leakage problem on the sidewall of the atomization chamber 220. The sidewall of the atomization chamber 220 specifically refers to the left and right sides of the atomization chamber 220 according to the orientation shown in FIG. 3.

In an embodiment, as shown in FIG. 9, FIG. 9 is a schematic structural diagram of the second seat body 222 under a second view according to the first embodiment of this application.

A ventilation slot 2226 is further formed on the side surface of the second installation portion of the second seat body 222 facing away from the first seat body 221. A first end of the ventilation slot 2226 is in communication with the side surface (hereinafter defined as a first surface) of the second installation portion facing toward the second engagement portion, and a second end of the ventilation slot 2226 is in communication with the side surface (hereinafter defined as a second surface) of the second installation portion facing away from the second engagement portion. The ventilation slot 2226 may be specifically in a bent shape, and along the ventilation path of the ventilation slot 2226, the width of the part of the ventilation slot 2226 closer to the first end may be greater than the width of the part of the ventilation slot 2226 farther from the first end, to avoid formation of a liquid film.

In a specific embodiment, the side surface of the second installation portion facing away from the first seat body 221 fits the inner sidewall of the receiving groove of the base 21 to form a straight liquid ventilation channel, to utilize the straight liquid ventilation channel to control the pressure balance inside the liquid storage chamber 201a, thereby avoiding the problem that the liquid storage chamber 201a cannot discharge the liquid because the pressure is less than the atmospheric pressure. It may be understood that, one end of the straight liquid ventilation channel is in communication with the first surface, and an other end is in communication with the second surface. In an alternative embodiment, the straight liquid ventilation channel may alternatively be a through hole running through the first surface and the second surface of the second installation portion.

Still referring to FIG. 9, a material reduction slot 2227 is also provided on the side surface of the second engagement portion facing away from the first seat body 221, to control the wall thickness of the second engagement portion through the material reduction slot 2227 and prevent deformation of the second engagement portion. Specifically, the material reduction slot 2227 extends along the circumferential direction of the second engagement portion, that is, the radian direction. In addition, a plurality of material reduction slots 2227 are distributed spaced apart along the axial direction of the second seat body 222.

In a specific embodiment, referring to FIG. 6, two positioning posts 2216 are arranged on the first installation portion. The two positioning posts 2216 are located on two sides of the first liquid absorption slot 2215 respectively. Referring to FIG. 8, the second installation portion is provided with two positioning holes 2217 at positions corresponding to the positioning posts 2216. During specific assembly, the two positioning posts 2216 on the first seat body 221 are respectively inserted into the two positioning holes 2217 on the second seat body 222, to fix the relative positions of the first seat body 221 and the second seat body 222, to prevent relative displacement between the two from affecting the sealing of the atomization chamber 220 and the fixing effect of the second seat body 222 on the heating component 24.

In an alternative embodiment, two buckles may be arranged on the side surface of the first engagement portion of the first seat body 221 facing toward the second seat body 222, and the two buckles are respectively located on the two side edges of the first groove 2212. The second engagement portion of the second seat body 222 is provided with two buckle holes at positions corresponding to the buckles. During specific assembly, the two buckles of the first seat body 221 are respectively engaged with the two buckle holes on the second seat body 222, to tightly abut, while implementing the connection between the first seat body 221 and the second seat body 222, the first sidewall 2221 and the second sidewall 2222 against the heating component 24, to fix the heating component 24 and connect the first seat body 221 and the second seat body 222.

The buckles and the positioning posts 2216 may alternatively be arranged on the second seat body 222, and the buckle holes and the positioning holes 2217 may be provided on a first housing. Alternatively, one of the buckle and the positioning post 2216 is provided on the first housing, and the other is arranged on the second seat body 222. The buckle holes and the positioning holes 2217 corresponding to the buckles and the positioning posts 2216 are provided on another housing.

Referring to FIG. 7 and FIG. 10, FIG. 10 is a schematic structural diagram of the heating component 24 according to an embodiment of this application. The heating component 24 includes a heating element 241 and a first pin 242 and a second pin 243 that are connected to the heating element 241. The heating element 241 is configured to heat and atomize, when energized, the aerosol-generating substrate. The first pin 242 and the second pin 243 are located on two sides of the heating element 241 respectively, and form a third side edge and a fourth side edge of the heating component 24. The third side edge and the fourth side edge of the heating component 24 are respectively arranged adjacent to the first side edge and the second side edge of the heating component 24. The electrode lead 25a specifically includes a positive electrode lead 251a and a negative electrode lead 252a. An abutting portion 2511a of the positive electrode lead is electrically connected to and abuts against the first pin 242, to fix the first pin 242 of the heating component 24 to the liquid guiding member 23, and an abutting portion 2521a of the negative electrode lead is electrically connected to and abut against the second pin 243, to fix the second pin 243 of the heating component 24 to the liquid guiding member 23, to prevent the heating component 24 from being separated from the liquid guiding member 23 and causing the problem of dry heating of the heating component 24.

In an embodiment, as shown in FIG. 7, after the heating component 24 is installed on the first groove 2212, the first pin 242 is located on the side of the heating element 241 close to the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a, and the second pin 243 is located on the side of the heating element 241 away from the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a. In this case, the abutting portion 2511a of the positive electrode lead abutting against the first pin 242 is located on the side of the heating element 241 close to the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a, and the abutting portion 2521a of the negative electrode lead abutting against the second pin 243 is located on the side of the heating element 241 away from the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a, which is used as an example in all the following embodiments. In an alternative embodiment, the first pin 242 is located on the side of the heating element 241 away from the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a, and the second pin 243 is located on the side of the heating element 241 close to the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a. In this case, the abutting portion 2511a of the positive electrode lead abutting against the first pin 242 is located on the side of the heating element 241 away from the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a, and the abutting portion 2521a of the negative electrode lead abutting against the second pin 243 is located on the side of the heating element 241 close to the air outlet opening 2214 along the direction of the air outlet path C of the atomization core 20a.

Fixing the heating component 24 to the liquid guiding member 23 through the electrode lead 25a can effectively improve the fit between the heating component 24 and the liquid guiding member 23, to avoid the probability that dry heating of the heating component 24 produces an inhaled burnt smell. Moreover, compared with the manner of fixing the first pin 242 and the second pin 243 of the heating component 24 using another fixing member, the electrode lead 25a has less impact on suction resistance of airflows. It may be understood that, the first side edge and the second side edge of the heating component 24 mentioned above specifically refer to two side edges that are of the heating element 241 and that are different from the two side edges connected to the first pin 242 and the second pin 243.

The abutting portion 2511a of the positive electrode lead and the abutting portion 2521a of the negative electrode lead extend along the third side edge and the fourth side edge of the heating component 24 respectively, and extend in opposite directions, to ensure as much as possible that positions on the heating component 24 are evenly stressed. Further, the abutting portion 2511a of the positive electrode lead and the abutting portion 2521a of the negative electrode lead are parallel to each other.

The heating element 241, the first pin 242, and the second pin 243 are all curved along the direction perpendicular to the air outlet path C of the atomization core 20a, to come into better contact with the liquid guiding member 23. In this embodiment, still referring to FIG. 7, the abutting portion 2511a of the positive electrode lead is bent into a first curved portion, and the first curved portion extends along the first pin 242 and abuts against the first pin 242. In this way, the contact area between the positive electrode lead 251a and the first pin 242 can be effectively increased, thereby enabling the first pin 242 of the heating component 24 to come into better contact with the liquid guiding member 23. Specifically, the radian of the first curved portion matches the radian of the first pin 242, to ensure that the two can fit perfectly.

The abutting portion 2521a of the negative electrode lead is bent into a second curved portion, and the second curved portion extends along the second pin 243 and abuts against the second pin 243. In this way, the contact area between the negative electrode lead 252a and the second pin 243 can be effectively increased, thereby enabling the second pin 243 of the heating component 24 to come into better contact with the liquid guiding member 23. Specifically, the radian of the second curved portion matches the radian of the second pin 243, to ensure that the two can fit perfectly.

A lead portion 2512a of the positive electrode lead is bent relative to the first curved portion and extend toward the direction of the atomization chamber 220 facing away from the air outlet opening 2214. A lead portion 2522a of the negative electrode lead is bent relative to the second curved portion and extend toward the direction of the atomization chamber 220 facing away from the air outlet opening 2214. In addition, the bending place of the positive electrode lead 251a and the bending place of the negative electrode lead 252a are located at two opposite corners of the heating component 24. That is, the joint between the abutting portion 2511a of the positive electrode lead and the lead portion 2512a of the positive electrode lead and the joint between the abutting portion 2521a of the negative electrode lead and the lead portion 2522a of the negative electrode lead are located at two opposite corners of the heating component 24, to further strengthen the fixation effect of the electrode lead 25a on the heating component 24.

In a specific embodiment, the lead portion 2512a of the positive electrode lead is located on the side of the second side edge of the heating component 24 facing away from the first side edge, and the lead portion 2522a of the negative electrode lead is located on the side of the first side edge of the heating component 24 facing away from the second side edge. In an alternative embodiment, the lead portion 2512a of the positive electrode lead may alternatively be located on the side of the first side edge of the heating component 24 facing away from the second side edge, and the lead portion 2522a of the negative electrode lead may alternatively be located on the side of the second side edge of the heating component 24 facing away from the first side edge.

Referring to FIG. 11 to FIG. 14, FIG. 11 is a schematic diagram of a stress-bearing part of the heating component 24 according to an embodiment of this application; FIG. 12 is a diagram of deformation of the heating component 24 corresponding to FIG. 11 after being stressed; FIG. 13 is a schematic diagram of a stress-bearing part of the heating component 24 according to another embodiment of this application; and FIG. 14 is a diagram of deformation of the heating component 24 corresponding to FIG. 13 after being stressed. A position C1/C2, a position D1/D2, a position E2, and a position F2 in the figures refer to stress-bearing positions of the second pin 243, the first pin 242, the first side edge, and the second side edge respectively. Upon comparison between FIG. 12 and FIG. 14, it can be learned that an evenly distributed normal stress F′ is applied to a stress-bearing surface. For example, a resultant force to which the stress-bearing surface is subjected is 1 N, the maximum center deformation amount of the heating component 24 corresponding to FIG. 11 is 2.83e-7, and the maximum center deformation amount of the heating component 24 corresponding to FIG. 13 is 3.3981e-8. In view of the above, the center deformation amount of the heating component 24 corresponding to FIG. 13 is one order of magnitude smaller than the center deformation amount of the heating component 24 corresponding to FIG. 11. Therefore, the positive electrode lead 251a and the negative electrode lead 252a are used to fix the first pin 242 and the second pin 243 of the heating component 24 respectively, and the second seat body 222 is used to fix the first side edge and the second side edge of the second pin 243 that is of the heating component 24 and that is different from the first pin 242, to enable the heating component 24 better fit the liquid guiding member 23.

For the atomization core 20a provided in this embodiment, the seat 22 and the liquid guiding member 23 are arranged such that the liquid guiding member 23 is arranged inside the atomization chamber 220 of the seat 22, to guide the aerosol-generating substrate through the liquid guiding member 23. In addition, the heating component 24 is arranged such that the heating component 24 is arranged on the liquid guiding member 23, to atomize the aerosol-generating substrate when the heating component 24 is energized. Moreover, the electrode lead 25a is arranged such that the electrode lead 25a is electrically connected to the heating component 24 and fixes the heating component 24 to the liquid guiding member 23. Fixing the heating component 24 to the liquid guiding member 23 through the electrode lead 25a can effectively improve the fit between the heating component 24 and the liquid guiding member 23, to avoid the probability that dry heating of the heating component 24 produces an inhaled burnt smell. Moreover, compared with another fixing member, the electrode lead 25a has less impact on suction resistance of airflows. In addition, the first sidewall 2221 and the second sidewall 2222 of the second seat body 222 are pressed against two side edges of the heating component 24, and the first sidewall 2221 and the second sidewall 2222 are arranged on two sides of the air outlet opening 2214 along the direction perpendicular to the air outlet path C of the atomization core 20a, which not only can better fix the heating component 24 to the liquid guiding member 23, but also can prevent the first sidewall 2221 and the second sidewall 2222 from blocking airflows.

To improve the sealing effect of the atomization chamber 220, in an embodiment, referring to FIG. 4 and FIG. 15a to FIG. 15c, FIG. 15a is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 4. FIG. 15b is a perspective view of an atomization core of the atomizer shown in FIG. 4; and FIG. 15c is a cross-sectional view along a direction B-B of the atomization core shown in FIG. 15b. A second type of atomization core 20b is provided. Different from the first type of atomization core 20a provided by the embodiments corresponding to FIG. 5a to FIG. 14, the second type of atomization core 20b further includes a first sealing member 26a. The first sealing member 26 is sleeved over the outer sides of the first seat body 221 and the second seat body 222, to seal the gap between the first seat body 221 and the second seat body 222, thereby sealing the atomization chamber 220 enclosed by the two.

In this embodiment, the housing 10a is specifically sleeved over the outer sides of the base 21 and the first sealing member 26a, and parts of the housing 10a and the first sealing member 26a are spaced apart to cooperate to form a liquid storage chamber 201a. In addition, the first sealing member 26a is further provided with a second liquid inlet hole 261 at a position corresponding to the first liquid inlet hole 2213. The aerosol-generating substrate inside the liquid storage chamber 201a specifically enters the atomization chamber 220 through the second liquid inlet hole 261 and the first liquid inlet hole 2213, and then, is guided using the liquid guiding member 23.

Specifically, as shown in FIG. 15a, the first sealing member 26a is provided with a ventilation hole 262 at a position corresponding to a port of a straight liquid ventilation channel, and the ventilation hole 262 is arranged corresponding to the liquid storage chamber 201a. The liquid storage chamber 201a is in communication with the atmosphere outside through the ventilation hole 262 and the straight liquid ventilation channel, to implement the ventilation function of the liquid storage chamber 201a and control the air pressure inside the liquid storage chamber 201a.

In a specific embodiment, referring to FIG. 4, the atomizer 101a further includes a liquid injection port steel ring 27, a mouthpiece cover 28, a second sealing member 29, a third sealing member 30, two ejector pins 31, and a magnet 32. The liquid injection port steel ring 27 is sleeved over a liquid injection port of the first sealing member 26a, and the second sealing member 29 is sleeved over the liquid injection port steel ring 27. The mouthpiece cover 28 covers the end of the first sealing member 26a facing away from the base 21, and forms an inhalation opening in communication with the air outlet opening 2214. The aerosol formed through atomization inside the atomization chamber 220 is sucked to the inhalation opening through the air outlet opening 2214, to enter the mouth of the user. The two ejector pins 31 are embedded in the base 21 and connected to the positive electrode lead 251a and the negative electrode lead 252a respectively, for the two ejector pins 31 to electrically connect the positive electrode lead 251a and the negative electrode lead 252a to the power supply assembly 102 when being in electrical contact with the positive electrode and the negative electrode of the power supply assembly 102. The magnet 32 is embedded in the base 21, and is located on the side surface of the base 21 facing away from the seat 22 and configured to be installed and fixed onto a host.

The following describes the specific assembly process of the atomizer 101a provided by this embodiment: First, the heating component 24 that is initially flat during delivery from the factory is placed in a forming jig for the heating component 24, and an indenter is pressed on the heating component 24, to deform the heating component 24 into a curved shape. The radian R of the heating component 24 may be 7 to 10 mm, and the arc length thereof may be 5 to 7 mm. Specifically, the radian of the heating component 24 may be 9 mm, and the arc length thereof may be 6.4 mm. In addition, the positive electrode lead 251a and the negative electrode lead 252a are bent according to a preset shape. Then, the liquid guiding member 23 is placed into the first groove 2212, and further, the heating component 24 is placed on the liquid guiding member 23. Afterward, the second seat body 222 and the first seat body 221 are fixed and assembled using the buckles and the positioning posts 2216. The first sealing member 26a is sleeved over the outer sides of the foregoing assembled assembly. Afterward, the ejector pins 31 and the magnet 32 are assembled on the base 21 and assembled with the foregoing formed assembly. Finally, the housing 10a, the liquid injection port steel ring 27, the mouthpiece cover 28, the second sealing member 29, and the third sealing member 30 are assembled with the foregoing assembly, to complete the assembly. The first sealing member 26a, the second sealing member 29, and the third sealing member 30 may be elastic silica gel parts such as silica gel or rubber.

Compared with the first type of atomization core 20a, the atomization core 20b provided by this embodiment can better seal the atomization chamber 220 by further arranging the first sealing member 26a, to avoid the problem that leakage of the atomization chamber 220 causes damage to another electronic device. In addition, the atomizer 101a corresponding to the second type of atomization core 20b can simplify the assembly process and improve the assembly consistency of the liquid guiding member 23 without changing the materials of the liquid guiding member 23 and the heating component 24.

Referring to FIG. 16 to FIG. 17b, FIG. 16 is an exploded view of the atomizer shown in FIG. 2 according to a second embodiment of this application; FIG. 17a is a schematic exploded view of an atomization core 20c in the atomizer 101b shown in FIG. 16 according to an embodiment of this application; and FIG. 17b is a schematic exploded view of an atomization core 20c in the atomizer 101b shown in FIG. 16 according to another embodiment of this application. In this embodiment, a third type of atomization core 20c is provided. Different from the foregoing two types of atomization cores 20a/20b, the electrode lead 25b of the third type of atomization core 20c is further fixed to the seat 22 to strengthen the supporting effect of the electrode lead 25b on the heating component 24 and prevent the heating component 24 from bulging and deforming. For the specific structure of the atomizer 101b corresponding to this embodiment, reference may be made to FIG. 16.

Specifically, referring to FIG. 17a to FIG. 18, FIG. 18 is a schematic structural diagram of the liquid guiding member 23, the heating component 24, and the electrode lead 25b being arranged inside the first groove 2212 according to another embodiment of this application. The electrode lead 25b further includes an extending portion connected to the abutting portion. The extending portion may be connected to the end of the abutting portion facing away from the lead portion, is linear, and is fixedly connected to the seat 22. Specifically, an extending portion 253 of the positive electrode lead is connected to the end of the abutting portion 2511b of the positive electrode lead facing away from the lead portion 2512b of the positive electrode lead, and an extending portion 254 of the negative electrode lead is connected to the end of the abutting portion 2521b of the negative electrode lead facing away from the lead portion 2522b of the negative electrode lead.

In an embodiment, as shown in FIG. 18, the seat 22 is provided with two fixing holes 2218. The extending portion 253 of the positive electrode lead and the extending portion 254 of the negative electrode lead respectively penetrate through the two fixing holes 2218, to be fixed to the seat 22. In a specific embodiment, the extending portion is the extension of abutting portion. Certainly, in another embodiment, the extending portion may also be connected to another position of the abutting portion, for example, the middle position of the abutting portion, and the extending portion may also be fixed to the seat 22 by welding, buckling, or the like, which is not limited in this application.

Further, referring to FIG. 18, different from the foregoing two types of atomization cores 20a/20b, in this embodiment, the abutting portion 2511b of the positive electrode lead and the abutting portion 2521b of the negative electrode lead are located on two sides of the air outlet opening 2214 along a direction perpendicular to the air outlet path C of the atomization core 20c, and the two fixing holes 2218 are specifically provided on the first seat body 221, and are located on the two sides of the air outlet opening 2214 along a direction perpendicular to the air outlet path C of the atomization core 20c.

In addition, as shown in FIG. 17b, the heating component 24 is bent into a curved shape along the direction of the air outlet path C of the atomization core 20c. That is, the heating element 241 of the heating component 24, the first pin 242, and the second pin 243 are all bent into a curved shape along the direction of the air outlet path C of the atomization core 20c. The abutting portion 2511b of the positive electrode lead is bent to form a first curved portion, and the first curved portion extends along and abuts against the first pin 242 of the heating component 24. The abutting portion 2521b of the negative electrode lead is bent to form a second curved portion, and the second curved portion extends along and abuts against the second pin 243 of the heating component 24. In this way, the fit between the first pin 242 and second pin 243 of the heating component 24 and the liquid guiding member 23 is enhanced through the arc-shaped stress, and prevent the heating component 24 from bulging and deforming.

After the assembly of the liquid guiding member 23 and the heating component 24 is completed, because the liquid guiding member 23 applies a stress facing toward the heating component 24 to the heating component 24, the heating component 24 is forced to bulge and deform. In the atomization core 20c provided by this embodiment, not only the curved heating component 24 itself can provide a bending moment, but also the interaction between the curved abutting portion of the electrode lead 25b abutting against the first pin 242 and second pin 243 of the heating component 24, as well as the extending portion of the electrode lead 25b, and the seat 22 can further provide a specific reverse moment to the heating component 24, thereby further preventing the heating component 24 from bulging and deforming.

Compared with the foregoing two types of atomization cores 20a/20b, the third type of atomization core 20c provided by this embodiment can effectively improve the bending moment of the heating component 24 by further fixing the electrode lead 25b to the seat 22. In addition, the abutting portion 2511b of the positive electrode lead and the abutting portion 2521b of the negative electrode lead are further arranged on the two sides of the air outlet opening 2214 respectively along the direction perpendicular to the air outlet path C of the atomization core 20c, to further prevent the electrode lead 25b from blocking airflows.

Referring to FIG. 19, FIG. 19 is a top view of an atomization core according to an embodiment of this application. To prevent the heating component 24 from bulging and deforming at another position other than edge positions, in an embodiment, a fourth type of atomization core 20d is provided. Different from the foregoing three types of atomization cores 20a/20b/20c, the fourth type of atomization core 20d further includes a fixing portion 33. The fixing portion 33 is arranged at a position opposite to another position of the heating component 24 other than edge positions, to prevent the heating component 24 from bulging and deforming. In some implementations, the fixing portion 33 is not in contact with the heating component 24, and there is a specific gap, to reduce the impact of the temperature of the heating component 24 on the fixing portion 33. In some other implementations, the fixing portion 33 is in contact with the heating component 24 to support and limit the heating component 24, to prevent the heating component 24 from bulging and deforming.

The radian of the side surface of the fixing portion 33 close to the heating component 24 matches the radian of the heating component 24 at a corresponding position, thereby further preventing the heating component 24 from bulging and deforming.

In an embodiment, the fixing portion 33 is provided at the middle part of the second seat body 222. The middle part of the second seat body 222 refers to a position of the second seat body 222 different from its ends (or edges). In this way, after the two side edges of the heating component 24 and the two side edges of the liquid guiding member 23 are clamped by the seat 22 respectively, the middle part of the heating component 24 can be limited by the fixing portion 33, to prevent the middle part of the heating component 24 other than the two side edges from bulging and causing the problem of deformation.

The fixing portion 33 is specifically formed on the side surface of the second seat body 222 facing toward the first seat body 221, and is located between the first sidewall 2221 and the second sidewall 2222. In this embodiment, the fixing portion 33 may be integrally formed with the second seat body 222, for the specific arrangements between the second seat body 222, the heating component 24, and the electrode lead 25b, reference may be made to FIG. 17a to FIG. 18 and the corresponding text descriptions, and this is used as an example in the following embodiments. Certainly, the fixing portion 33 may alternatively be formed on the first seat body 221 and bent toward the heating component 24 to abut against the heating component 24. The electrode lead 25b and/or the first sidewall 2221 and second sidewall 2222 of the second seat body 222 may also be arranged oppositely along the direction of the air outlet path C of the atomization core.

In one embodiment, referring to FIG. 20, FIG. 20 is a schematic structural diagram of the second seat body 222 of the fourth type of atomization core 20d according to the first embodiment of this application. The fixing portion 33 includes at least one first extending wall 33a. The at least one first extending wall 33a is located between the first sidewall 2221 and the second sidewall 2222, and is spaced apart between the first sidewall 2221 and the second sidewall 2222. Each first extending wall 33a extends in parallel to the direction of the air outlet path C of the atomization core 20d. Certainly, the first extending wall 33a may alternatively be arranged at a specific angle to the direction of the air outlet path C of the atomization core 20d. In this case, a through hole may be provided on the first extending wall 33a along the direction of the air outlet path C of the atomization core 20d, to allow airflows to pass through and avoid blocking the airflows.

In an embodiment, there is one first extending wall 33a, and the first extending wall 33a is located at the middle position between the first sidewall 2221 and the second sidewall 2222. Specifically, the first extending wall 33a may be arranged in parallel to the first sidewall 2221 and the second sidewall 2222, and cooperates with the first sidewall 2221 and the second sidewall 2222 to form two air outlet channels in communication with the air outlet opening 2214. It may be understood that, in this embodiment, the first sidewall 2221, the first extending wall 33a, and the second sidewall 2222 are distributed in a “ ” shape. In some implementations, the first extending wall 33a is not in contact with the heating component 24, and there is a specific gap, to reduce the impact of the temperature of the heating component 24 on the first extending wall 33a.

In another embodiment, referring to FIG. 21, FIG. 21 is a schematic structural diagram of the second seat body 222 of the fourth type of atomization core 20d according to the second embodiment of this application. The fixing portion 33 further includes a second extending wall 33b. The second extending wall 33b and the first extending wall 33a are arranged in an intersecting manner. The second extending wall 33b is provided with at least one first through hole 331b along the air outlet path C of the atomization core 20d for airflows to pass through, thereby avoiding blocking the airflows. Specifically, the second extending wall 33b and the first extending wall 33a are distributed in a “cross” shape. At least one first through hole 331b is evenly distributed on two sides of the first extending wall 33a.

Specifically, the second extending wall 33b is provided with two first through holes 331b along the air outlet path C of the atomization core 20d, and the two first through holes 331b are respectively located on two sides of the first extending wall 33a. The radians of the side surfaces of the first extending wall 33a and/or the second extending wall 33b close to the heating component 24 match the radian of the heating component 24, thereby further preventing the heating component 24 from bulging and deforming. In some implementations, neither of the first extending wall 33a and the second extending wall 33b is in contact with the heating component 24, and there are specific gaps, to reduce the impact of the temperature of the heating component 24 on the first extending wall 33a and the second extending wall 33b.

In still another embodiment, referring to FIG. 22, FIG. 22 is a schematic structural diagram of the second seat body 222 of the fourth type of atomization core 20d according to a third embodiment of this application. The fixing portion 33 includes a plurality of third extending walls 33c. The plurality of third extending walls 33c are spaced apart along the direction of the air outlet path C of the atomization core 20d. In addition, each third extending wall 33c is provided with at least one second through hole 331c for airflows to pass through, thereby avoiding blocking the airflows. Specifically, the plurality of third extending walls 33c are parallel to each other.

Specifically, as shown in FIG. 22, each third extending wall 33c extends along the direction perpendicular to the air outlet path C of the atomization core 20d, and abuts against the first sidewall 2221 and the second sidewall 2222 respectively. In a specific embodiment, there may be three third extending walls 33c, and the three third extending walls 33c are distributed in a “ ” shape. Certainly, each third extending wall 33c may alternatively be arrange obliquely at an angle between the first sidewall 2221 and the second sidewall 2222, and the angle may be specifically 30 to 60 degrees.

The radian of the side surface of the third extending wall 33c close to the heating component 24 matches the radian of the heating component 24, thereby further preventing the heating component 24 from bulging and deforming. In some implementations, the third extending wall 33c is not in contact with the heating component 24, and there is a specific gap, to reduce the impact of the temperature of the heating component 24 on the third extending wall 33c.

In another embodiment, referring to FIG. 23, FIG. 23 is a schematic structural diagram of the second seat body 222 of the fourth type of atomization core 20d according to a fourth embodiment of this application. The fixing portion 33 includes a plurality of bumps 33d, and the plurality of bumps 33d are spaced apart and arranged opposite to the heating component 24 respectively. Specifically, the bump 33d may be a cylinder. The plurality of bumps 33d may be evenly distributed between the first sidewall 2221 and the second sidewall 2222 to correspond to different positions of the heating component 24, thereby preventing the problem of local bulging of the heating component 24. It should be noted that the extending wall is strip-shaped, and the bump 33d is dot-shaped or column-shaped. In some implementations, the bump 33d is not in contact with the heating component 24, and there is a specific gap, to reduce the impact of the temperature of the heating component 24 on the bump 33d. Certainly, the bump 33d may also abut against the heating component 34.

Compared with the foregoing three types of atomization cores 20a/20b/20c, by further arranging the fixing portion 33 and providing through hole on the fixing portion 33 arranged along the direction perpendicular to the air outlet path C of the atomization core 20d, the fourth type of atomization core 20d provided by this embodiment not only can effectively prevent the heating component 24 from bulging and deforming, but also can effectively avoid blocking airflows.

A plane perpendicular to the outflow direction of the mouthpiece 11 (that is, the direction of the air outlet path C of the atomization core 20d) is used as a reference plane in the following embodiments, and the outflow direction of the mouthpiece 11 is the forward direction. As shown in FIG. 24, FIG. 24 is a schematic structural diagram of an atomization core according to an embodiment of this application being arranged obliquely.

Because a liquid inlet hole 34 of the atomization core is generally located on one side of the atomization core, and there is no liquid inlet hole 34 on an other side of the atomization core, when the atomization core is along the inclination direction shown in FIG. 24, if there is a small amount of less aerosol-generating substrate in the liquid storage chamber 201a corresponding to the atomization core, there may be a problem of insufficient liquid supply inside the atomization chamber 220 or dry heating of the heating component 24, and the part of aerosol-generating substrate cannot be fully utilized, resulting in waste.

Therefore, referring to FIG. 25a to FIG. 26, FIG. 25a is an exploded view of the atomizer shown in FIG. 2 according to the third embodiment of this application; FIG. 25b is a cross-sectional view along a direction B-B of an atomizer 101c corresponding to FIG. 25a; and FIG. 26 is a schematic overall structural diagram of an atomization core 20e of the atomizer 101c shown in FIG. 25b. In an embodiment, another atomizer 101c is provided. The atomizer 101c differs from the atomizer 101a/101b corresponding to the atomization core 20a/20b/20c/20d involved in any one of the foregoing embodiments in that: The bottom surface D of the liquid storage chamber 201a is constructed such that the aerosol-generating substrate can enter the liquid inlet hole 34 when the atomizer 101c is tilted at any angle.

Specifically, the atomizer 101c includes a housing 10a and an atomization core 20e. The atomization core 20e is arranged inside the housing 10a, and cooperates with the housing 10a to form a liquid storage chamber 201a. The liquid storage chamber 201a is configured to store an aerosol-generating substrate. The atomization core 20e includes an atomization chamber 220 and a liquid inlet hole 34 in communication with the atomization chamber 220. The liquid inlet hole 34 is opposite to a side surface of the housing 10a and is exposed inside the liquid storage chamber 201a. The aerosol-generating substrate enters the atomization chamber 220 through the liquid inlet hole 34, to implement one-side liquid inlet of the atomization core 20e. It should be noted that the liquid inlet hole 34 refers to a port making the liquid storage chamber 201a in communication with the atomization chamber 220. The liquid inlet hole 34 involved in this embodiment may be the foregoing first liquid inlet hole 2213. When the atomization core 20e is sheathed with a first sealing member 26b, if a second liquid inlet hole 261 is provided on the first sealing member 26b, the liquid inlet hole 34 may be the second liquid inlet hole 261, or the first liquid inlet hole 2213 and the second liquid inlet hole 261 form a through hole.

In an embodiment, the distance between at least a part of the bottom surface D of the liquid storage chamber 201a and the mouthpiece 11 is less than the maximum distance between the liquid inlet hole 34 and the mouthpiece 11. The vertical distance between the lowest position F of the liquid inlet hole 34 and mouthpiece 11 is the maximum distance between the liquid inlet hole 34 and the mouthpiece 11. In this embodiment, it may be understood that, at least a part of the bottom surface D of the liquid storage chamber 201a is higher than the lowest position F of the liquid inlet hole 34. In this way, the aerosol-generating substrate inside the liquid storage chamber 201a can be forced to have a tendency to flow toward a position at which the lowest position F of the liquid inlet hole 34 is located. Therefore, when there is a small amount of less aerosol-generating substrate in the liquid storage chamber 201a, the aerosol-generating substrate is enabled to converge as much as possible toward the position at which the lowest position F of the liquid inlet hole 34 is located, to enter the atomization chamber 220 for atomization, thereby not only fully atomizing the aerosol-generating substrate inside the liquid storage chamber 201a and reducing the residue of the aerosol-generating substrate inside the liquid storage chamber 201a, to improve the product utilization, but also supplying the atomization chamber 220 with the sufficient aerosol-generating substrate and reducing the risk of dry heating of the heating component 24, to improve the product safety.

In a specific embodiment, the side surface of the atomization core 20e facing toward the mouthpiece 11 forms the bottom surface D of the liquid storage chamber 201a. As shown in FIG. 26, the atomization core 20e includes a sleeve portion 200a and an atomization portion 200b. The sleeve portion 200a is configured to be sleeved over the housing 10a, and the sleeve portion 200a includes a first surface. The first surface forms the bottom surface D of the liquid storage chamber 201a. The atomization portion 200b is arranged on the first surface of the sleeve portion 200a. The atomization portion 200b includes a first side surface G and a second side surface H that are opposite to each other, and an atomization chamber 220 is provided inside the atomization portion 200b. In a specific embodiment, the liquid inlet hole 34 is specifically formed on a first side surface G of the atomization portion 200b. Certainly, the bottom surface D of the liquid storage chamber 201a can also be formed by the housing 10a, which is not limited in this application.

In an implementation, the other specific structures and functions of the atomization core 20e are the same as or similar to the specific structures and functions of the first type of atomization core 20a. In addition, the same or similar technical effects may be achieved. For details, reference may be made to the foregoing related descriptions. In this embodiment, the base 21 forms the sleeve portion 200a of the atomization core 20e, the seat 22 forms the atomization portion 200b of the atomization core 20e, and the housing 10a is sleeved over the base 21 and cooperates with the outer wall surface of the seat 22 to form the liquid storage chamber 201a.

In an implementation, the specific structures and functions of the atomization core 20e are the same as or similar to the specific structures and functions of the second type of atomization core 20b. In addition, the same or similar technical effects may be achieved. For details, reference may be made to the foregoing related descriptions. In this embodiment, the first sealing member 26b cooperates with the housing 10a to form the liquid storage chamber 201a, and the first sealing member 26b forms the outer surface of the atomization core 20e. It may be understood that, in this embodiment, the first sealing member 26b forms the bottom surface D of the liquid storage chamber 201a, which is used as an example in all of the following embodiments.

In an embodiment, as shown in FIG. 26, the bottom surface D of the liquid storage chamber 201a is an inclined surface relative to the reference plane, and the lowest position of the inclined surface is close to the liquid inlet hole 34. That is, the lowest position of the inclined surface is located on the side of the atomization core 20e on which the liquid inlet hole 34 is provided, to help the aerosol-generating substrate enter the liquid inlet hole 34 after converging. When the first sealing member 26b forms the bottom surface D of the liquid storage chamber 201a, the liquid inlet hole 34 is located on the first side surface G of the first sealing member 26b. In addition, in an embodiment, the distance between the lowest position F of the inclined surface and the mouthpiece 11 is the same as the distance between the lowest position F of the liquid inlet hole 34 and the mouthpiece 11, to enable the aerosol-generating substrate to directly enter the liquid inlet hole 34 as much as possible.

Specifically, the angle between the inclination surface and the forward direction is greater than 0 degrees and less than 90 degrees. In a specific embodiment, the angle between the inclined surface and the forward direction may be 30 to 60 degrees. Therefore, when the user inhales, and the atomizer 101c is obliquely arranged, the aerosol-generating substrate can also enter the liquid inlet hole 34. Further, referring to FIG. 26, in this embodiment, the atomization core 20e differs from the foregoing atomization core 20a/20b/20c/20d in that: The vertical distance between the ventilation hole 262 and the mouthpiece 11 is less than the minimum distance between the liquid inlet hole 34 and the mouthpiece 11, that is, the position of the ventilation hole 262 is higher than the position of the liquid inlet hole 34. The ventilation hole 262 is correspondingly arranged at a higher position of the bottom surface D of liquid storage chamber 201a, to avoid, when there is a small amount of less aerosol-generating substrate the problem, that the aerosol-generating substrate blocks the ventilation hole 262, thereby improving the ventilation performance and facilitating the liquid discharge.

By making the bottom surface D of the liquid storage chamber 201a be an inclined surface relative to the reference plane and the lowest position of the inclined surface close to the liquid inlet hole 34, the atomizer 101c provided by this embodiment can help the aerosol-generating substrate to converge toward the liquid inlet hole 34, to help the aerosol-generating substrate to enter the liquid inlet hole 34 after the converging, thereby improving the utilization of the aerosol-generating substrate and reducing the occurrence of the problem of dry heating of the heating components 24.

In another embodiment, the distance between at least a part of the bottom surface D of the liquid storage chamber 201a and the mouthpiece 11 is greater than the minimum distance between the liquid inlet hole 34 and the mouthpiece 11. The vertical distance between the highest position F of the liquid inlet hole 34 and mouthpiece 11 is the minimum distance between the liquid inlet hole 34 and the mouthpiece 11. In this embodiment, it may be understood that the highest position of the liquid inlet hole 34 is higher than at least a part of the bottom surface D of the liquid storage chamber 201a.

Referring to FIG. 27a and FIG. 27b, FIG. 27a is a cross-sectional view along a direction B-B of an atomizer 101d shown in FIG. 2 according to the second embodiment of this application; and FIG. 27b is a schematic overall structural diagram of an atomization core 20f of the atomizer 101d shown in FIG. 27a. The bottom surface D of the liquid storage chamber 201a is entirely higher than the lowest position F of the liquid inlet hole 34 and lower than the highest position of the liquid inlet hole 35. Further, a groove 35 is formed at a position corresponding to the liquid inlet hole 34 and on the bottom surface D of the liquid storage chamber 201a, and the lowest position F of the liquid inlet hole 34 is located in the groove 35. In this way, when there is a small amount of less aerosol-generating substrate, the aerosol-generating substrate converges in the groove 35, which can increase the relative height of the aerosol-generating substrate compared with the solution that the aerosol-generating substrate is dispersed throughout the bottom surface D of the liquid storage chamber 201a. Therefore, a small amount of aerosol-generating substrate can also flow into the atomization chamber 220 through the liquid inlet hole 34, thereby improving the utilization rate of the aerosol-generating substrate and preventing the problem of dry heating of the heating components 24. The atomizer 101d corresponding to this embodiment may be an open atomizer. That is, the user can re-inject the aerosol-generating substrate after using up the aerosol-generating substrate in the liquid storage chamber 201a, to reuse the atomizer 101d.

In a specific embodiment, as shown in FIG. 27a and FIG. 27b, a novel atomization core 20f is provided, and the bottom surface D of the liquid storage chamber 201a is formed on the side surface of a sleeve portion 200c of the atomization core 20f facing toward the atomization portion 200d, and the side surface of the surface corresponding to the liquid inlet hole 34 is recessed in a direction facing away from the atomization portion 200d, to form a groove 35. The liquid inlet hole 34 is specifically provided on the sidewall corresponding to the groove 35 and is in communication with the atomization chamber 220.

In an embodiment, the height of the bottom surface of the groove 35 is the same as the height of the lowest position F of the liquid inlet hole 34. Therefore, when the atomizer 101c is vertically placed, it can also ensure that a small amount of aerosol-generating substrate in the liquid storage chamber 201a can pass through the liquid inlet hole 34 to enter the atomization chamber 220, thereby effective ensuring the utilization of the aerosol-generating substrate.

Further, in this embodiment, the bottom surface D of the liquid storage chamber 201a is lower than the highest position of the liquid inlet hole 34, and the radial size of the groove 35 along the direction perpendicular to the air outlet path C of the atomization core 20a may be greater than the aperture of the liquid inlet hole 34 along the direction perpendicular to the air outlet path C of the atomization core 20a, to fully expose the liquid inlet hole 34. The radial size of the groove 35 specifically refers to the width size of the groove 35 along the circumferential direction of the atomization core 20e.

Further, the bottom surface D of the liquid storage chamber 201a may be a plane and perpendicular to the forward direction, and the radial size of the groove 35 may gradually decrease in the direction facing away from the liquid storage chamber 201a, to help the aerosol-generating substrate inside the liquid storage chamber 201a to converge. Certainly, the bottom surface D of the liquid storage chamber 201a may also be in a concave-convex shape with specific roughness, an inclined shape, or the like.

In one embodiment, referring to FIG. 28a to FIG. 28c, FIG. 28a is a schematic structural diagram of an atomizer according to another embodiment of this application; FIG. 28b is a cross-sectional view along a direction B-B of the atomizer shown in FIG. 28a; and FIG. 28c is a schematic overall structural diagram of an atomization core of the atomizer shown in FIG. 28b. Another atomizer 101e is provided. This atomizer 101e may be a closed atomizer. That is, the liquid storage chamber 201a cannot be refilled.

Specifically, the atomizer 101e include a housing 10b and an atomization core 20g. The atomization core 20g is arranged inside the housing 10b, and cooperates with the housing 10b to form a liquid storage chamber 201b. Different from the atomizers 101c and 101d corresponding to FIG. 26 and FIG. 27b, the entire outer sidewall of the atomization core 20g is in contact with and sheathed with the housing 10b.

In this embodiment, as shown in FIG. 28c, the liquid inlet hole 34 is specifically provided on the outer sidewall of the atomization core 20g, and the bottom surface D of the liquid storage chamber 201b is higher than the highest position of the liquid inlet hole 34. In addition, the atomization core 20g includes at least one communication hole 36. The communication hole 36 is in communication with different positions of the liquid inlet hole 34. The liquid storage chamber 201b is specifically in communication with the liquid inlet hole 34 through the at least one communication hole 36. For the specific structures of the atomization core 20g corresponding to the atomizer 101e, reference may be made to FIG. 28a and FIG. 28b.

In a specific embodiment, as shown in FIG. 28c, the communication hole 36 may be a slot formed on the outer sidewall of the atomization core 20g, and the slot runs through the side surface of the atomization core 20g facing toward the mouthpiece 11 and the liquid inlet hole 34, and cooperates with the housing 10b to form a liquid inlet channel. The liquid storage chamber 201b is specifically in communication with the liquid inlet hole 34 through the liquid inlet channel.

Specifically, in this embodiment, as shown in FIG. 28b and FIG. 28c, the outer sidewall of the atomization core 20g may still be sheathed with the first sealing member 26c, to seal the atomization chamber 220. The first sealing member 26c may be a silica gel sleeve. In this embodiment, the slot is specifically provided on the outer sidewall of the first sealing member 26c, and the housing 10 specifically cooperates with the first sealing member 26c to form the liquid storage chamber 201b and the liquid inlet channel, to improve the sealing effect of the liquid inlet channel and avoid the leakage problem. It may be understood that, the entire outer sidewall of the first sealing member 26c is sheathed with the housing 10b, and the upper surface of the first sealing member 26c forms the bottom surface D of the liquid storage chamber 201b.

Certainly, in another embodiment, the communication hole 36 may also be a through hole provided at the middle position of the atomization core 20g, and the through hole is in direct communication with the atomization chamber 220, to make the liquid storage chamber 201b and the atomization chamber 220 in communication with each other.

Specifically, as shown in FIG. 28c, the communication hole 36 may include a first communication hole 36a and a second communication hole 36b. The first communication hole 36a and the second communication hole 36b are respectively located on opposite sides of the liquid inlet hole 34 along the circumferential direction of the atomization core 20g, and are respectively in communication with the lowest positions of two opposite sides of the liquid inlet hole 34 in the circumferential direction of the atomization core 20g. Compared with the solution in which only a single communication hole 36 is provided, the probability of the problem that bubbles are formed in the communication hole 36 and prevent the liquid from being discharged can be reduced.

Further, the communication hole 36 may further include a third communication hole 36c. The third communication hole 36c is located between the first communication hole 36a and the second communication hole 36b and is in communication with the highest position of the liquid inlet hole 34. In addition, the radial size of the third communication hole 36c may gradually increase in the direction away from the liquid inlet hole 34, to prevent bubbles from being formed inside the third communication hole 36c, and bubbles formed inside the first communication hole 36a or the second communication hole 36b may be broken through the third communication hole 36c, to further reduce the probability of the problem of forming bubbles inside the communication hole 36. In some implementations, the plurality of communication holes 36 are connected to the liquid inlet hole 34 in different directions.

It should be noted that the other structures and functions of the atomizers 101c, 101d, and 101e are the same as or similar to the structures and functions of the foregoing atomizers 101a and 101b. In addition, the same or similar technical effects may be achieved. For details, reference may be made to the foregoing descriptions. Details are not described herein again.

For the atomizer 101e provided by this embodiment, the housing 10b and the atomization core 20g are arranged such that the atomization core 20e is arranged inside the housing 10a, and cooperates with the housing 10b to form the liquid storage chamber 201b. The liquid storage chamber 201b is configured to store the aerosol-generating substrate. In addition, by making the liquid inlet hole 34 opposite to a side surface of the housing 10b, the bottom surface D of the liquid storage chamber 201b is higher than the liquid inlet hole 34. The atomization core 20g includes at least one communication hole 36, for the liquid storage chamber 201b to communicate with the liquid inlet hole 34 through the communication hole 36 and further communicate with the atomization chamber 220, thereby not only implementing the lateral one-surface liquid inlet of the atomization core 20g, but also using the at least one communication hole 36 to guide a small amount of aerosol-generating substrate on the bottom surface D of the liquid storage chamber 201b to the liquid inlet hole 34 and to the atomization chamber 220 for atomization. Further, the aerosol-generating substrate in the liquid storage chamber 201b is fully atomized, and the residue of the aerosol-generating substrate in the liquid storage chamber 201b is reduced, to improve the product utilization. In addition, the sufficient aerosol-generating substrate is supplied inside the atomization chamber 220, to reduce the risk of dry heating of the heating component 24.

The foregoing descriptions are merely embodiments of the present invention, and the patent scope of the present invention is not limited thereto. All equivalent structure or process changes made according to the content of this specification and accompanying drawings in the present invention or by directly or indirectly applying the present invention in other related technical fields shall fall within the protection scope of the present invention.

While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. It will be understood that changes and modifications may be made by those of ordinary skill within the scope of the following claims. In particular, the present invention covers further embodiments with any combination of features from different embodiments described above and below. Additionally, statements made herein characterizing the invention refer to an embodiment of the invention and not necessarily all embodiments.

The terms used in the claims should be construed to have the broadest reasonable interpretation consistent with the foregoing description. For example, the use of the article “a” or “the” in introducing an element should not be interpreted as being exclusive of a plurality of elements. Likewise, the recitation of “or” should be interpreted as being inclusive, such that the recitation of “A or B” is not exclusive of “A and B,” unless it is clear from the context or the foregoing description that only one of A and B is intended. Further, the recitation of “at least one of A, B and C” should be interpreted as one or more of a group of elements consisting of A, B and C, and should not be interpreted as requiring at least one of each of the listed elements A, B and C, regardless of whether A, B and C are related as categories or otherwise. Moreover, the recitation of “A, B and/or C” or “at least one of A, B or C” should be interpreted as including any singular entity from the listed elements, e.g., A, any subset from the listed elements, e.g., A and B, or the entire list of elements A, B and C.

Claims

1. An atomization core, comprising:

a seat comprising an atomization chamber;

a liquid guiding member arranged inside the atomization chamber and configured to guide an aerosol-generating substrate;

a heating component arranged on the liquid guiding member and configured to atomize, when energized, the aerosol-generating substrate; and

an electrode lead electrically connected to the heating component and fixing the heating component to the liquid guiding member.

2. The atomization core of claim 1, wherein the heating component comprises a heating element and a first pin and a second pin arranged on two sides of the heating element,

wherein the electrode lead comprises a positive electrode lead and a negative electrode lead,

wherein an abutting portion of the positive electrode lead is electrically connected to and abuts against the first pin to fix the first pin of the heating component to the liquid guiding member, and/or

wherein an abutting portion of the negative electrode lead is electrically connected to and abut against the second pin to fix the second pin of the heating component to the liquid guiding member.

3. The atomization core of claim 2, wherein the seat comprises an air outlet opening in communication with the atomization chamber,

wherein the abutting portion of the positive electrode lead is arranged on a side of the heating element close to the air outlet opening along an air outlet path of the atomization core, and the abutting portion of the negative electrode lead is arranged on a side of the heating element away from the air outlet opening along the air outlet path of the atomization core, or

wherein the abutting portion of the negative electrode lead is arranged on a side of the heating element close to the air outlet opening along the air outlet path of the atomization core, and the abutting portion of the positive electrode lead is arranged on a side of the heating element away from the air outlet opening along the air outlet path of the atomization core.

4. The atomization core of claim 2, wherein the abutting portion of the positive electrode lead and the abutting portion of the negative electrode lead extend along two side edges of the heating component, respectively.

5. The atomization core of claim 2, wherein the abutting portion of the positive electrode lead and the abutting portion of the negative electrode lead are parallel to each other.

6. The atomization core of claim 5, wherein the abutting portion of the positive electrode lead and the abutting portion of the negative electrode lead extend toward opposite directions.

7. The atomization core of claim 3, wherein the abutting portion of the positive electrode lead is bent into a first curved portion, and the first curved portion extends along the first pin and abuts against the first pin, and

wherein the abutting portion of the negative electrode lead is bent into a second curved portion, and the second curved portion extends along the second pin and abuts against the second pin.

8. The atomization core of claim 7, wherein the first pin and the second pin are curved in a direction of the air outlet path of the atomization core,

wherein a radian of the first curved portion matches a radian of the first pin, and

wherein a radian of the second curved portion matches a radian of the second pin.

9. The atomization core of claim 1, wherein the electrode lead comprises an abutting portion and a lead portion, and

wherein the abutting portion comprises an extension of the lead portion.

10. The atomization core of claim 3, wherein a lead portion of the positive electrode lead is bent relative to the abutting portion of the positive electrode lead and extends toward a direction of the atomization chamber facing away from the air outlet opening, and is configured to connect the positive electrode of the power supply assembly, and/or

wherein a lead portion of the negative electrode lead is bent relative to the abutting portion of the negative electrode lead and extends toward a direction of the atomization chamber facing away from the air outlet opening, and is configured to connect the negative electrode of the power supply assembly, and

wherein a bending place of the positive electrode lead and a bending place of the negative electrode lead are located at two opposite corners of the heating component.

11. The atomization core of claim 1, wherein the seat comprises:

a first seat body provided with a first groove, the liquid guiding member and the heating component being arranged in the first groove, and

a second seat body forming the atomization chamber with the first seat body, and abutting against the heating component to fix the heating component to the liquid guiding member.

12. The atomization core of claim 11, wherein the first seat body includes an air outlet opening in communication with the first groove,

wherein the second seat body abuts against a first side edge and a second side edge of the heating element, respectively, and

wherein the first side edge and the second side edge are located on two sides of the air outlet opening along a direction perpendicular to the air outlet path of the atomization core.

13. The atomization core of claim 12, wherein a side surface of the second seat body facing toward the first seat body comprises a first sidewall and a second sidewall that are opposite to each other, and

wherein the first sidewall and the second sidewall abut against the first side edge and the second side edge, respectively.

14. The atomization core of claim 13, wherein a vertical distance between the first sidewall and/or the second sidewall and a bottom wall of the first groove is less than a thickness of the liquid guiding member.

15. The atomization core of claim 13, wherein the side surface of the first seat body facing toward the second seat body includes a plurality of first liquid absorption slots, and/or

wherein the side surface of the second seat body facing toward the first seat body includes a plurality of second liquid absorption slots, and the plurality of first liquid absorption slots and the plurality of second liquid absorption slots are all in communication with a bottom of the atomization chamber, to guide, through capillary force, the aerosol-generating substrate flowing out from the bottom of the atomization chamber into the plurality of first liquid absorption slots and/or the plurality of second liquid absorption slots.

16. The atomization core of claim 15, wherein the seat includes an air outlet opening in communication with the atomization chamber,

wherein the plurality of first liquid absorption slots are located on a side of the first groove facing away from the air outlet opening, and

wherein the plurality of second liquid absorption slots are arranged opposite the plurality of first liquid absorption slots.

17. The atomization core of claim 1, wherein the liquid guiding member comprises a curved liquid absorption sponge, and

wherein the heating component comprises a curved metal heating mesh.

18. The atomization core of claim 1, wherein a radian range of the liquid guiding member is 20° to 55°.

19. An atomizer, comprising:

a housing; and

the atomization core of claim 1 arranged inside the housing and cooperating with the housing to form a liquid storage chamber.

20. An electronic atomization device, comprising:

the atomizer of claim 19; and

a power supply assembly connected to the atomizer and configured to supply power to the atomizer.