CN220277302U - Atomizing subassembly and atomizer - Google Patents

Abstract

The application discloses an atomization assembly and an atomizer, wherein the atomization assembly comprises a bracket, a heating structure and an electrode column, and the bracket is provided with an installation area with an opening on the side wall; the heating structure is arranged in the installation area; the side wall of the electrode column is abutted against the heating structure; the support is also provided with a limit structure matched with the electrode column in the mounting area, and the limit structure is abutted against at least part of the side wall of the electrode column outside the electric contact with the heating structure so as to provide the pressing force for the lamination of the electrode column and the heating structure. In the atomizing subassembly, the electrode post withholds the lateral wall of electrode post with the installation zone of support by limit structure to be fixed in the installation zone with the electrode post, and under limit structure to electrode post's pressure solid, the electrode post can compress tightly the heating structure, so that the heating structure is fixed in the installation zone, with fixed electrode post of the mode of avoiding welding withholding and heating structure, simplify the operation of equipment.

Description

Atomizing subassembly and atomizer

Technical Field

The application relates to the technical field of atomization, in particular to an atomization assembly and an atomizer.

Background

The atomizer generally adopts electrode column and heating structure to contact and conduct electricity, and the common mode is that electrode column and heating structure are fixed in a welded mode, and then electrode column, heating structure and oil guide component are assembled into the bracket. The welding operation increases manpower and material resources, increases manufacturing cost, and the welding spot that the welding formed contacts with atomizing medium in addition, probably can lead to atomizing medium to discolour. On the other hand, the common atomizer also has the problem of insufficient pressure between the heating structure and the oil guide part, and has insufficient tightness, so that liquid leakage is caused.

Disclosure of Invention

In order to solve at least one of the above technical problems, the present application provides an atomization assembly and an atomizer, and the adopted technical scheme is as follows.

The atomizer provided by the application comprises an atomization assembly and an oil cup, wherein the atomization assembly is arranged in the oil cup.

The atomization assembly comprises a bracket, a heating structure and an electrode column, wherein the bracket is provided with an installation area with an opening on the side wall; the heating structure is arranged in the installation area; the side wall of the electrode column is abutted against the heating structure; the support is arranged in the mounting area, and is further provided with a limiting structure matched with the electrode column, wherein the limiting structure is abutted to at least part of side walls, except for electric contact with the heating structure, on the electrode column, so as to provide pressing force for bonding the electrode column with the heating structure.

In certain embodiments of the present application, the spacing structure applies a compressive force to the side wall of the electrode column in a first direction perpendicular to the bottom surface of the mounting region.

In some embodiments of the present application, at least two limit structures are disposed on an inner side wall on the same side in the mounting region, and the limit structures are distributed at intervals along an axial direction of the electrode column.

In some embodiments of the present application, one of the limiting structures is pressed against a side wall of the electrode column tip.

In some embodiments of the present application, the mounting area has a first wall facing the opening and a second wall connected to two opposite sides of the first wall, where the limiting structure is disposed on at least one of the first wall and the second wall, and in a first direction perpendicular to the first wall, the limiting structure and the first wall are spaced apart and define a limiting space, and the electrode column is at least partially disposed in the limiting space.

In some embodiments of the present application, the limiting structure is disposed as an elastic clamping arm protruding on an inner wall of the mounting area, and the elastic clamping arm is used for being buckled and connected with the electrode column.

In some embodiments of the present application, a side of each of the limiting structures facing away from the heating structure is provided with an inclined guiding surface.

In some embodiments of the present application, a side of the heat generating structure facing the opening abuts against the electrode column, and at least one of the heat generating structure and the electrode column is provided with a first protrusion structure at a position corresponding to the other one.

In some embodiments of the present application, the heat generating structure is provided with first protrusion structures protruding toward the electrode columns, and at least two first protrusion structures are disposed at intervals in an axial direction corresponding to each electrode column, and/or the first protrusion structures are disposed along an axial extension of the corresponding electrode column.

In certain embodiments of the present application, the atomization component further comprises an oil guiding component and an air passage structure, wherein the oil guiding component is arranged on one side, away from the opening, of the heating structure, the air passage structure is arranged on one side, facing the opening, of the heating structure, a second protruding structure is further arranged between the heating structure and the air passage structure, and the air passage structure enables the heating structure to compress the oil guiding component through the second protruding structure.

In some embodiments of the present application, the heat generating structure is provided with the second protrusion structures protruding toward one side of the air passage structure at two opposite ends along the axial direction of the electrode column.

In certain embodiments of the present application, the support includes a top structure and a surrounding structure, the surrounding structure is located at the bottom end of the top structure, the limiting structure is disposed on the surrounding structure, and the side surface of the surrounding structure forms the installation area with an opening.

Embodiments of the present application have at least the following beneficial effects: in the atomizing subassembly, the electrode post withholds the lateral wall of electrode post with the installation zone of support by limit structure to be fixed in the installation zone with the electrode post, and under limit structure to electrode post's pressure solid, the electrode post can compress tightly the heating structure, so that the heating structure is fixed in the installation zone, with fixed electrode post of the mode of avoiding welding withholding and heating structure, simplify the operation of equipment.

Drawings

The aspects and advantages described and/or appended to the embodiments of the present application will become apparent and readily appreciated from the following drawings. It should be noted that the embodiments shown in the drawings below are exemplary only and are not to be construed as limiting the application.

FIG. 1 is a schematic view showing an exploded structure of a atomizer according to an embodiment of the present application;

FIG. 2 is a block diagram of a bracket in an embodiment of the present application;

FIG. 3 is a schematic view of the partial structure of the area A in FIG. 2;

FIG. 4 is a block diagram of a bracket in an embodiment of the present application;

FIG. 5 is a schematic view of an assembled configuration of a misting assembly in an embodiment of the application;

FIG. 6 is a front view of a side wall of a heat generating structure facing an electrode column and an air channel structure in an embodiment of the present application;

fig. 7 is a sectional view of B-B in fig. 6.

It should be noted that, the K direction identified in the drawing refers to the first direction.

Reference numerals: 1100. a bracket; 1101. an installation area; 1102. a limit structure; 1103. a guide surface; 1104. a top structure; 1105. a enclosing structure; 1106. an avoidance zone; 1107. a first wall surface; 1108. a second wall surface; 1200. a heating structure; 1201. a first bump structure; 1202. a second bump structure; 1203. a connection section; 1300. an electrode column; 1400. an oil guide member; 1501. an airway structure; 1502. a bottom sealing structure; 1600. a base; 2000. an oil cup.

Detailed Description

Embodiments of the present application are described in detail below in conjunction with fig. 1-7, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functionality throughout. The embodiments described below by referring to the drawings are exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it should be understood that, if the terms "center," "middle," "longitudinal," "transverse," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "axial," "radial," "circumferential," etc. indicate orientations or positional relationships are based on the orientations or positional relationships illustrated in the drawings, it is merely for convenience in describing the present application and simplifying the description, and it does not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application. Features defining "first", "second" are used to distinguish feature names from special meanings, and furthermore, features defining "first", "second" may explicitly or implicitly include one or more such features. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

The present application relates to an atomizer, and in combination with fig. 1, the atomizer includes an atomization assembly and an oil cup 2000, and the atomization assembly is installed in the oil cup 2000. Specifically, the top of the oil cup 2000 is provided with a suction nozzle opening, and the atomizing assembly is loaded into the oil cup 2000 from the bottom of the oil cup 2000.

Other construction and operation of atomizers are well known to those of ordinary skill in the art and will not be described in detail herein, the construction of the atomizing assembly will be described below.

The application relates to an atomizing subassembly, atomizing subassembly includes support 1100, heating structure 1200 and electrode post 1300, and support 1100 packs into oil cup 2000 and can seal the inner chamber of oil cup 2000 and form the storage chamber, and heating structure 1200 sets up in support 1100, and electrode post 1300 sets up to two, and the lateral wall of electrode post 1300 is contradicted in heating structure 1200, and electrode post 1300 and the conductive contact of heating structure 1200, and the lateral wall of electrode post 1300 compresses tightly heating structure 1200 to make heating structure 1200 be fixed in support 1100. Specifically, the outer peripheral side wall of the electrode column 1300 abuts against the heat generating structure 1200 and presses the heat generating structure 1200.

Referring to fig. 1, the atomization assembly further includes an air channel structure 1501, the air channel structure 1501 is provided with an air inlet channel, the air channel structure 1501 is disposed on a side surface of the support 1100, an atomization channel is formed between a side wall of the air channel structure 1501 and a side wall of the support 1100, one end of the atomization channel is communicated with a suction nozzle, the other end of the atomization channel is communicated with an air inlet channel of the atomizer, the heating structure 1200 is located between the air channel structure 1501 and the support 1100, and the air channel structure 1501 compresses the heating structure 1200. Specifically, the air channel structure 1501 presses against the sidewalls of the heat generating structure 1200.

The atomization assembly further comprises a bottom sealing structure 1502, the bottom sealing structure 1502 is arranged at the bottom of the oil cup 2000, the bottom sealing structure 1502 is arranged at the bottom of the support 1100, the bottom sealing structure 1502 is abutted to the bottom of the support 1100, the peripheral side wall of the bottom sealing structure 1502 is abutted to the inner wall of the oil cup 2000, the air channel structure 1501 is arranged on the upper side face of the bottom sealing structure 1502, the bottom sealing structure 1502 is connected with the air channel structure 1501, the bottom sealing structure 1502 is provided with an air inlet communicated with the atomization channel, and the electrode column 1300 penetrates through the bottom sealing structure 1502.

Referring to fig. 1 and 5, the atomizing assembly further includes a base 1600, the base 1600 is used for connecting with the bottom of the oil cup 2000, the base 1600 is connected with the bottom sealing structure 1502, the electrode column 1300 is disposed on the base 1600, and the electrode column 1300 penetrates through the base 1600.

It will be appreciated that the atomizing assembly further includes an oil guide member 1400, the oil guide member 1400 is configured as oil cotton, the oil guide member 1400 is disposed on a side of the stand 1100, and the oil guide member 1400 is located between the heat generating structure 1200 and the stand 1100. Referring to fig. 1, the heat generating structure 1200 is configured as a metal heat generating sheet, the metal heat generating sheet is flat, one side of the heat generating structure 1200 is abutted to the electrode column 1300, and the oil guiding component 1400 is disposed at the other side of the heat generating structure 1200. Further, in the case where the electrode column 1300 presses the heat generating structure 1200, the heat generating structure 1200 presses the oil guide member 1400.

Referring to fig. 2 and 4, the bracket 1100 has a mounting region 1101 with an opening in a side wall, and the mounting region 1101 is recessed in a first direction at a side of the bracket 1100, thereby forming a mounting groove as the mounting region 1101 at the side of the bracket 1100. It can be appreciated that the heating structure 1200 is disposed in the mounting region 1101, one side of the heating structure 1200 facing the opening is abutted to the electrode columns 1300, the oil guiding component 1400 is disposed in the mounting region 1101, the oil guiding component 1400 is disposed on one side of the heating structure 1200 facing away from the opening, the air channel structure 1501 is disposed in the mounting region 1101, the air channel structure 1501 is disposed on one side of the heating structure 1200 facing the opening, the electrode columns 1300 are partially disposed in the mounting region 1101, and the two electrode columns 1300 are respectively adjacent to two opposite side walls of the mounting region 1101.

Further, the side wall of the mounting region 1101 is clamped and pressed against the side wall of the electrode column 1300, so that the electrode column 1300 is fixed in the mounting region 1101, and the electrode column 1300 can press the heating structure 1200. In this case, the electrode column 1300 is fixed in a buckling manner, and the heating structure 1200 is pressed and fixed by the electrode column 1300, so that the electrode column 1300 and the heating structure 1200 are fixed on the bracket 1100 in a welding-free manner, and welding spots are avoided, so that the atomized medium can be effectively prevented from being in contact with the welding spots to cause the atomized medium to change color, the assembly operation of the atomization component can be simplified, the assembly efficiency is improved, and the cost is reduced.

Specifically, the support 1100 is provided with a limiting structure 1102 that is matched with the electrode column 1300 in the mounting region 1101, and the limiting structure 1102 is abutted against at least part of the side wall of the electrode column 1300 except for being in electrical contact with the heating structure 1200, so as to provide a pressing force for attaching the electrode column 1300 to the heating structure 1200, so that the side wall of the electrode column 1300 applies a pressure along the first direction to the heating structure 1200, and the heating structure 1200 is fixed in the mounting region 1101 under stress.

In the assembly process of the atomizing assembly, when the electrode column 1300 is installed in the installation region 1101 from the side of the support 1100 along the first direction, the peripheral side wall of the electrode column 1300 contacts the limiting structure 1102, and the peripheral side wall of the electrode column 1300 presses the limiting structure 1102, so that the electrode column 1300 is clamped in the installation region 1101, and the limiting structure 1102 can buckle the peripheral side wall of the electrode column 1300 to prevent the electrode column 1300 from being separated from the installation region 1101 along the opposite direction of the first direction.

In some examples, referring to fig. 2, the stand 1100 includes a top structure 1104 and a surrounding structure 1105, the surrounding structure 1105 being located at a bottom end of the top structure 1104, and the surrounding structure 1105 being integrally formed with the top structure 1104. Further, the limit structure is arranged on the enclosing structure, the enclosing structure 1105 encloses and forms an installation area 1101 with an opening on the side surface, the top structure 1104 is provided with a communication hole, and the atomization channel is communicated to the suction nozzle opening through the communication hole.

As an embodiment, the limiting structure 1102 is configured as an elastic clamping arm protruding on the inner wall of the mounting area 1101, the elastic clamping arm is used for buckling connection of the electrode column 1300, and when the electrode column 1300 is installed in the mounting area 1101, the elastic clamping arm can be elastically deformed so as to avoid the electrode column 1300 and buckling the electrode column 1300.

Specifically, the support 1100 is made of plastic, the support 1100 has a certain elastic deformation capability, the limiting structure 1102 is arranged in the support 1100, the limiting structure 1102 is made of silica gel or plastic, or the limiting structure 1102 is made of metal sheet made of metal. In this case, when the electrode column 1300 is clamped into the mounting region 1101 from the side of the support 1100, the side wall of the mounting region 1101 and the limiting structure 1102 can deform, so that the limiting structure 1102 avoids the clamped electrode column 1300, and after the electrode column 1300 is clamped into the mounting region 1101, the side wall of the mounting region 1101 and the limiting structure 1102 can recover, so that the limiting structure 1102 clamps the side wall of the buckling electrode column 1300.

In some examples, the stent 1100 is silicone and the stent 1100 is integrally injection molded from silicone.

As an embodiment, referring to fig. 4, the mounting area 1101 has a first wall 1107 facing the opening and a second wall 1108 connected to opposite sides of the first wall 1107, the first wall 1107 is located at the bottom of the mounting groove formed by recessing the mounting area 1101 along the first direction on the side of the bracket 1100, the first wall 1107 is the bottom of the mounting area 1101, and the first direction is perpendicular to the first wall 1107.

Further, the limiting structure 1102 is disposed on at least one of the first wall 1107 and the second wall 1108, and in the first direction, the limiting structure 1102 is spaced apart from the first wall 1107 and defines a limiting space, and the electrode column 1300 is at least partially disposed in the limiting space.

In some examples, the spacing structure 1102 is disposed on the first wall 1107, in which case the spacing structure 1102 is disposed along the first direction, and the spacing structure 1102 is formed to have a bent structure, in particular, the spacing structure 1102 is formed in an inverted "L" shape.

In other examples, the spacing structure 1102 is disposed on the second wall surface 1108, in which case the spacing structure 1102 is disposed along a direction perpendicular to the first direction, and the spacing structure 1102 presses the outer sidewall of the electrode pillar 1300, wherein the spacing structure 1102 can limit the movement of the electrode pillar 1300 along the direction perpendicular to the first wall surface 1107 and the second wall surface 1108, thereby limiting the electrode pillar 1300 in the mounting region 1101 so that the electrode pillar 1300 is in contact with the heat generating structure 1200.

It will be appreciated that in other embodiments, the first wall 1107 and the second wall 1108 each extend into the mounting region 1101 to form a spacing structure 1102, wherein the first wall 1107 and the second wall 110 cooperate to define movement of the electrode column 1300 in a radial direction, i.e., perpendicular to the first wall 1107 and/or the second wall 110, such that the electrode column 1300 is defined within the mounting region 1101 to contact the electrode column 1300 with the heat generating structure 1200.

As an embodiment, at least two limiting structures 1102 are disposed on the inner side wall of the same side in the mounting region 1101, the limiting structures 1102 are distributed at intervals along the axial direction of the electrode column 1300, and each limiting structure 1102 is respectively clamped and pressed at different positions of the outer peripheral side wall of the electrode column 1300, so that the electrode column 1300 is uniformly stressed, and the electrode column 1300 is ensured to uniformly press the heating structure 1200.

Further, one of the limiting structures 1102 is pressed against the sidewall of the top end of the electrode pillar 1300, and correspondingly, the other limiting structures 1102 are pressed against the sidewall of the middle or near the bottom of the electrode pillar 1300.

In some examples, referring to fig. 2, fig. 3, fig. 4, and fig. 5, two limiting structures 1102 are disposed on the second wall 1108 on the same side in the mounting region 1101, where one limiting structure 1102 fixes the top side wall of the electrode pillar 1300, and the other limiting structure 1102 fixes the middle side wall of the electrode pillar 1300 or the side wall near the bottom of the electrode pillar 1300.

In other examples, corresponding to one electrode column 1300, three limiting structures 1102 are disposed on the inner side wall of the same side of the mounting region 1101, and the three limiting structures 1102 respectively fix the top side wall, the middle side wall and the side wall near the bottom of the electrode column 1300.

With respect to the number of the stopper structures 1102, the following alternative designs are also possible.

In some examples, corresponding to one electrode column 1300, a limiting structure 1102 is disposed on the inner side wall on the same side in the mounting region 1101, and along the axial direction of the electrode column 1300, the limiting structure 1102 extends from the top end near the electrode column 1300 to the bottom end on the side wall of the mounting region 1101, and the extending length of the limiting structure 1102 is consistent with the length of the electrode column 1300 in the mounting region 1101 or the extending length of the limiting structure 1102 is close to the length of the electrode column 1300 in the mounting region 1101.

In some examples, a limiting structure 1102 is disposed on the inner side wall of the mounting region 1101 corresponding to one electrode pillar 1300, and the limiting structure 1102 is disposed near the top end of the electrode pillar 1300 to press the side wall of the top end of the electrode pillar 1300. In this case, when the base 1600 is connected to the bottom of the oil cup 2000, the bottom end of the electrode column 1300 is fixed to the base 1600, and the support 1100 fixes the top end of the electrode column 1300 through the limiting structure 1102, thereby ensuring the fixed installation of the two ends of the electrode column 1300 and improving the reliability of the assembly of the atomizing assembly structure.

For additional explanation of the limiting structure 1102, the abutment surface of the limiting structure 1102 for pressing the sidewall of the electrode pillar 1300 should be configured to be compatible with the sidewall of the electrode pillar 1300, that is, the abutment surface between the limiting structure 1102 and the electrode pillar 1300 is compatible. Specifically: in some examples, if the cross section of the electrode pillar 1300 is circular, the abutment surface of the limiting structure 1102 is configured as a cambered surface. In some examples, if the cross section of the electrode column 1300 is rectangular, the abutment surface of the stop structure 1102 is provided as a planar surface.

As an embodiment, a side of each of the limiting structures 1102 facing away from the heat generating structure 1200 is provided with an inclined guiding surface 1103, and the guiding surface 1103 extends obliquely from the surface of the limiting structure 1102 along a direction inclined to the first direction, and the guiding surface 1103 is configured as an arc surface or a plane. Specifically, when the electrode column 1300 is mounted in the mounting region 1101 in the first direction, the side wall of the electrode column 1300 abuts against the guide surface 1103, and the side wall of the electrode column 1300 is caught in the mounting region 1101 along the guide surface 1103.

It will be appreciated that as the electrode column 1300 snaps into the mounting region 1101, the peripheral side walls of the electrode column 1300 progressively compress the guide surface 1103 such that the spacing structure 1102 progressively deforms so that the electrode column 1300 snaps into the spacing interval.

As an embodiment, the left and right ends of the heating structure 1200 are respectively provided with a disconnected connection section 1203, so that the side surface of the support 1100 is provided with a concave avoidance area 1106, the connection section 1203 is located in the avoidance area 1106, and in combination with fig. 2, fig. 4 and fig. 5, the avoidance area 1106 is communicated to the installation area 1101, and the side wall where the limiting structure 1102 is located is divided into two sections by the avoidance area 1106.

In this case, at least one limiting structure 1102 is respectively disposed on the side wall of the mounting region 1101 divided into two sections on the same side, or at least one limiting structure 1102 is disposed on the side wall of the mounting region 1101 divided into two sections on the same side, which is close to the top end of the electrode column 1300.

Further, the inner side wall of the avoiding area 1106 can clamp the connection section 1203 of the heat generating structure 1200, and can fix the heat generating structure 1200.

As one embodiment, at least one of the heat generating structure 1200 and the electrode column 1300 is provided with a first bump structure 1201 at a position corresponding to the other. It can be appreciated that, by providing the first protruding structure 1201, the outer peripheral sidewall of the electrode pillar 1300 can be ensured to be in contact with the heat generating structure 1200, and the pressing effect of the electrode pillar 1300 on the heat generating structure 1200 can be enhanced, so that the electrode pillar 1300 and the heat generating structure 1200 can be fully pressed together.

Specifically, the heat generating structure 1200 is provided with a first protruding structure 1201 protruding toward the electrode pillar 1300, and a sidewall of the electrode pillar 1300 abuts against the first protruding structure 1201. Further, referring to fig. 6 and fig. 7, corresponding to the positions of the two electrode columns 1300, the heating structure 1200 is provided with first bump structures 1201 near the left and right sides, respectively.

In some examples, at least two first bump structures 1201 are provided at intervals along the axial direction of each electrode column 1300 corresponding to the position of the electrode column 1300. It will be appreciated that the first bump structures 1201 are provided near the top and bottom ends of the electrode column 1300, respectively, so that the electrode column 1300 uniformly presses the upper and lower portions of the heat generating structure 1200.

In some examples, the first bump structure 1201 is formed by stamping on the heat generating structure 1200, and under the stamping action, a boss is formed on the heat generating structure 1200 protruding toward the side of the electrode pillar 1300 as the first bump structure 1201.

With respect to the design of the first bump structure 1201, there are also alternatives: corresponding to the position of the electrode column 1300, the heating structure 1200 is provided with a first protrusion structure 1201 near the side edge, and the first protrusion structure 1201 is arranged to extend along the axial direction of the electrode column 1300, forming a rectangular boss.

It will be appreciated that in other embodiments, the first bump structures 1201 may be disposed on the electrode column 1300 at a location corresponding to contact with the heat generating structure 1200.

As an embodiment, a second protrusion structure 1202 is disposed between the heat generating structure 1200 and the air channel structure 1501, and the air channel structure 1501 presses the heat generating structure 1200 against the oil guiding member 1400 through the second protrusion structure 1202.

It can be appreciated that, compared to the heat generating structure 1200 contacting the air channel structure 1501 in a planar manner, there may be a problem that the air channel structure 1501 does not exert enough force on the heat generating structure 1200 to cause the heat generating structure 1200 to press the oil guiding component 1400, so that the second protrusion structure 1202 is disposed between the heat generating structure 1200 and the air channel structure 1501 to enhance the acting force of the air channel structure 1501 on the heat generating structure 1200, thereby enhancing the compression of the heat generating structure 1200 on the oil guiding component 1400 and ensuring sufficient press fit between the heat generating structure 1200 and the oil guiding component 1400.

Specifically, referring to fig. 6 and 7, the heat generating structure 1200 is provided with a second protrusion structure 1202 on a side facing the air passage structure 1501, and the second protrusion structure 1202 protrudes on a side of the heat generating structure 1200 facing the air passage structure 1501. Further, the heat generating structure 1200 is provided to the second bump structures 1202 protruding toward the air passage structure 1501 at the opposite ends in the axial direction of the electrode column 1300, respectively.

In some examples, the second bump structure 1202 is stamped and formed on the heat generating structure 1200, and under the stamping action, a boss is formed on the heat generating structure 1200 protruding toward the side of the air channel structure 1501 as the second bump structure 1202.

In some examples, a second raised structure 1202 is provided on the heat generating structure 1200 on a side facing the air channel structure 1501, at a location near the top and near the bottom, such that the air channel structure 1501 is capable of increasing pressure on the upper and lower portions of the heat generating structure 1200, respectively.

Further, a second bump structure 1202 is disposed on the side of the heat generating structure 1200 facing the air channel structure 1501, and the second bump structure 1202 is a rectangular boss disposed near the top and near the bottom. Alternatively, at least two second bump structures 1202 are disposed on the heat generating structure 1200 at intervals near the top and near the bottom.

It will be appreciated that in other embodiments, the second raised structure 1202 may also be disposed on the side of the airway structure 1501 facing the heat generating structure 1200.

As one embodiment, the air channel structure 1501 and the bottom sealing structure 1502 are formed separately, with a detachable connection between the air channel structure 1501 and the bottom sealing structure 1502. Alternatively, airway structure 1501 and bottom sealing structure 1502 are integrally formed.

Based on the above description of the atomizing assembly, the following is a supplementary explanation of the structure of the atomizer.

As an embodiment, the atomizer includes a power supply assembly, a housing of which is connected to the oil cup 2000, and positive and negative electrodes of which are respectively contacted with the two electrode columns 1300. The power supply assembly is provided with a switch to energize the electrode column 1300, and the heat generating structure 1200 starts to generate heat.

Further, the power supply assembly is provided with a detachable and replaceable battery, or the power supply assembly is provided with a chargeable and dischargeable storage battery.

In some examples, the connection between the housing of the power assembly and the oil cup 2000 is detachable to enable reuse of the power assembly. Specifically, the detachable connection manner between the housing of the power supply assembly and the oil cup 2000 includes, but is not limited to, clamping connection, magnetic connection, screwing connection, and the like.

In the description of the present specification, if a description appears with reference to the term "one embodiment," "some examples," "some embodiments," "an exemplary embodiment," "an example," "a particular example," or "some examples," etc., it is intended that the particular feature, structure, material, or characteristic described in connection with the embodiment or example be included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The embodiments of the present application have been described in detail above with reference to the drawings, but the present application is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present application.

In the description of the present application, the patent names, if appearing ", indicate a relationship of" and "instead of a relationship of" or ". For example, patent name "a A, B", describing what is claimed in this application is: a technical scheme with a subject name A and a technical scheme with a subject name B.

Claims (13)

1. An atomizing assembly, characterized in that: comprising

A bracket having a mounting region with an opening in a side wall;

the heating structure is arranged in the installation area;

the side wall of the electrode column is abutted against the heating structure;

the support is arranged in the mounting area, and is further provided with a limiting structure matched with the electrode column, wherein the limiting structure is abutted to at least part of side walls, except for electric contact with the heating structure, on the electrode column, so as to provide pressing force for bonding the electrode column with the heating structure.

2. The atomizing assembly according to claim 1, wherein: the limiting structure applies a pressing force to the side wall of the electrode column along a first direction perpendicular to the bottom surface of the mounting area.

3. The atomizing assembly according to claim 1, wherein: the inner side wall of the same side in the installation area is provided with at least two limit structures, and the limit structures are distributed at intervals along the axial direction of the electrode column.

4. A spray assembly as claimed in claim 3 wherein: one of the limiting structures is used for buckling the side wall of the top end of the electrode column.

5. The atomizing assembly according to claim 1, wherein: the mounting area is internally provided with a first wall surface facing the opening and a second wall surface connected to two opposite sides of the first wall surface, wherein the limiting structure is arranged on at least one of the first wall surface and the second wall surface, and is arranged at intervals with the first wall surface in a first direction perpendicular to the first wall surface and is defined with a limiting interval, and the electrode column is at least partially arranged in the limiting interval.

6. An atomizing assembly according to any one of claims 1 to 5, wherein: the limiting structure is arranged to be an elastic clamping arm protruding on the inner wall of the installation area, and the elastic clamping arm is used for being buckled and connected with the electrode column.

7. An atomizing assembly according to any one of claims 1 to 5, wherein: and one side of each limiting structure, which is away from the heating structure, is provided with an inclined guide surface.

8. The atomizing assembly according to claim 1, wherein: one side of the heating structure, which faces the opening, is abutted against the electrode column, and at least one of the heating structure and the electrode column is provided with a first protruding structure at a position corresponding to the other one.

9. The atomizing assembly of claim 8, wherein: the heating structure is provided with first protruding structures protruding towards the electrode columns, at least two first protruding structures are arranged at intervals on the axial direction corresponding to each electrode column, and/or the first protruding structures extend along the axial direction of the corresponding electrode columns.

10. The atomizing assembly according to claim 1 or 8 or 9, wherein: the atomization assembly further comprises an oil guide component and an air passage structure, wherein the oil guide component is arranged on one side, away from the opening, of the heating structure, the air passage structure is arranged on one side, facing the opening, of the heating structure, a second protruding structure is further arranged between the heating structure and the air passage structure, and the air passage structure enables the heating structure to compress the oil guide component through the second protruding structure.

11. The atomizing assembly according to claim 10, wherein: the heating structure is provided with second bulge structures protruding towards one side of the air passage structure at two opposite ends along the axial direction of the electrode column.

12. The atomizing assembly according to claim 1, wherein: the support includes the top structure and encloses and close the structure, enclose and close the structure and be located the bottom of top structure, limit structure set up in enclose and close the structure, enclose the side that closes the structure and form and have the opening the installation zone.

13. An atomizer, characterized in that: comprising

An atomising assembly as claimed in any one of claims 1 to 12;

and the atomizing assembly is arranged in the oil cup.