CN116725238A - Manufacturing method of atomization structure and atomization structure - Google Patents

Abstract

The application relates to the technical field of atomization, and discloses a manufacturing method of an atomization structure and the atomization structure. The manufacturing method of the atomization structure comprises the steps of providing a mounting tube, a heating assembly and an oil guide piece, wherein the mounting tube comprises a first end and a second end, a first groove is formed in the side wall of the mounting tube, an elastic piece is connected to the groove wall of the first groove close to the first end, one end of the elastic piece, which is far away from the first end, is a free end, the free end of the elastic piece is arranged in the mounting tube, and the inner side wall of the mounting tube protrudes to form a limiting convex hull; wrapping the oil guide along the outer side wall of the heating assembly; the heating component and the oil guide piece are inserted into the mounting pipe; and moving the heating assembly and the oil guide piece until the end part of the oil guide piece is propped against the limiting convex hull, and arranging the side wall of the oil guide piece at the first groove, wherein the side wall of the oil guide piece is propped against the side wall of the elastic piece, so that the elastic piece is elastically shaped. Through this setting to solve among the prior art oil guide probably for the gliding technical problem of installation pipe.

Description

Manufacturing method of atomization structure and atomization structure

Technical Field

The application relates to the technical field of atomization, in particular to a manufacturing method of an atomization structure and the atomization structure.

Background

At present, the atomizing structure is used for vaporizing the tobacco tar in a heating mode, and the gaseous tobacco tar is used for people.

In the related art, an atomization structure generally comprises a mounting pipe, an oil guide piece and a heating component, wherein the mounting pipe adopts a steel pipe under most conditions, and an oil inlet hole is formed in the side wall of the mounting pipe; in the manufacturing process of the atomization structure, firstly, the oil guide is wrapped around the heating assembly along the outer side of the heating assembly, and the diameter of the outer side wall of the oil guide is larger than the inner diameter of the mounting pipe; then the heating component and the oil guide piece are inserted into the installation tube, the oil guide piece is arranged at the oil inlet, and the inner side wall of the installation tube clamps the oil guide piece, so that the installation process of the atomization structure is completed.

In the above-mentioned in-process, the internal diameter of installation pipe adopts interference fit with the external diameter of oil guide, and then the inside wall of installation pipe can be followed the outer lateral wall of oil guide and press from both sides tight oil guide, and heating element has the tobacco tar to flow through in the oil guide in the course of the work, and then probably leads to the ductility of oil guide to reduce, and the outer lateral wall of oil guide is smoother simultaneously, finally leads to the oil guide probably to slide for the installation pipe.

Disclosure of Invention

The embodiment of the application aims to provide a manufacturing method of an atomization structure and the atomization structure, which are used for solving the technical problem that an oil guide piece can slide relative to a mounting pipe in the prior art.

The technical scheme adopted by the embodiment of the application for solving the technical problems is as follows:

one embodiment of the present application provides a method for manufacturing an atomization structure, including: providing an installation tube, a heating assembly and an oil guide piece, wherein the installation tube comprises a first end and a second end, a first groove is formed in the side wall of the installation tube, an elastic sheet is connected to the groove wall of the first groove, which is close to the first end, one end, away from the first end, of the elastic sheet is a free end, the free end of the elastic sheet is arranged in the installation tube, and the inner side wall of the installation tube protrudes to form a limiting convex hull;

wrapping the oil guide member around the heating element along the outer wall of the heating element;

inserting the heating assembly and the oil guide member into the mounting tube along the direction from the first end to the second end;

and moving the heating assembly and the oil guide piece until the end part of the oil guide piece is propped against the limiting convex hull, and the side wall of the oil guide piece is arranged at the first groove, wherein the side wall of the oil guide piece is propped against the side wall of the elastic piece, so that the elastic piece is in an elastic shape, and the side wall of the elastic piece and the inner wall of the mounting tube clamp the oil guide piece.

In some embodiments, the mounting tube is provided with a second groove, a clamping piece is connected to the groove wall of the second groove close to the second end, and a buckling part is arranged at one end of the clamping piece away from the groove wall of the second groove; the outer side wall of the oil guide piece is connected with an extension part;

the manufacturing method further comprises the steps of: extending the extension out of the mounting tube along the second slot;

wrapping the extension around the mounting tube at least one revolution along the mounting tube outer sidewall;

one end of the extending part is propped against one end of the clamping piece connected with the wall of the second groove;

the buckling part is arranged in the mounting pipe, so that the buckling part abuts against the other end of the extending part, and the side wall of the clamping piece presses the side wall of the extending part.

In some embodiments, the method of manufacturing an atomization structure further comprises: providing a sleeve member, an inner diameter of the sleeve member being adapted to an outer diameter of the mounting tube;

sleeving the sleeve part on the outer side wall of the mounting tube along the first end;

and moving the sleeve member along the direction from the first end to the second end, so that one end of the sleeve member abuts against the buckling part.

One embodiment of the present application provides an atomization structure, including:

the mounting tube comprises a first end and a second end, a first groove is formed in the side wall of the mounting tube, an elastic sheet is connected to the groove wall of the first groove, which is close to the first end, one end, away from the groove wall of the first groove, of the elastic sheet is a free end, the free end of the elastic sheet is arranged in the mounting tube, and the inner side wall of the mounting tube protrudes to form a limiting convex hull;

a heating assembly;

the oil guide piece is wrapped on the outer side wall of the heating assembly, the oil guide piece and the heating assembly are arranged in the mounting pipe, the elastic piece is elastically deformed, the elastic piece and the inner wall of the mounting pipe clamp the oil guide piece, and the end part of the oil guide piece is propped against the limiting convex hull.

In some embodiments, the mounting tube is provided with a second groove, a clamping piece is connected to the groove wall of the second groove close to the second end, and a buckling part is arranged at one end of the clamping piece away from the groove wall of the second groove; the outer side wall of the oil guide piece is connected with an extension part; the extending part extends out of the mounting pipe along the second groove, the extending part is wound at least one circle along the outer side wall of the mounting pipe, one end of the clamping piece connected with the groove wall of the second groove is propped against one end of the extending part, the buckling part is arranged in the mounting pipe, and the buckling part is propped against the other end of the extending part; the side wall of the clamping piece is propped against the side wall of the extension part.

In some embodiments, the atomizing structure further comprises a sleeve member having an inner diameter adapted to an outer diameter of the mounting tube; the sleeve member is sleeved on the outer side wall of the mounting tube along the first end, and one end of the sleeve member abuts against the buckling part.

In some embodiments, the second groove is disposed through the first end with a chamfer disposed between a groove wall of the second groove and the first end.

In some embodiments, the first groove and the second groove are respectively arranged at two sides of the axis of the mounting tube, and the distance from the connecting end of the clamping piece and the groove wall of the second groove to the second end is adapted to the distance from the free end of the elastic piece to the second end.

In some embodiments, the clamping member includes a connecting section and a parallel section, one end of the connecting section is connected to a groove wall of the second groove near the second end, the other end is connected to one end of the parallel section, the parallel section is parallel to the axis of the mounting tube, and one end of the parallel section far from the connecting section is connected to the fastening part; one end of the extending part is propped against the connecting section, the other end of the extending part is propped against the buckling part, and the parallel section is propped against the side wall of the extending part.

In some embodiments, the spacing convex hull comprises two sets, wherein one set of spacing convex hull is propped against one end of the oil guide, and the other set of spacing convex hull is propped against the other end of the oil guide.

Compared with the prior art, in the manufacturing method of the atomization structure, the side wall of the oil guide piece can resist and press the side wall of the elastic piece towards the axis of the installation tube, so that the elastic piece is elastically deformed, pressure is arranged between the side wall of the elastic piece and the side wall of the oil guide piece, the side wall of the elastic piece is tightly propped against the side wall of the oil guide piece, and the side wall of the elastic piece and the inner side wall of the installation tube clamp the oil guide piece. Meanwhile, the limiting convex hulls are abutted against the end parts of the oil guide pieces, and further the limiting convex hulls play a limiting role on the oil guide pieces along the axis direction of the mounting pipe, and finally the oil guide pieces are difficult to loosen relative to the mounting pipe after being clamped.

Drawings

One or more embodiments are illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements, and in which the figures of the drawings are not to be taken in a limiting sense, unless otherwise indicated.

FIG. 1 is a cross-sectional view of a misting structure in one embodiment of the application;

FIG. 2 is an isometric view of a mounting tube and oil guide in accordance with another embodiment of the application;

FIG. 3 is an isometric view of a mounting tube in yet another embodiment of the application;

FIG. 4 is a cross-sectional view of a mounting tube in other embodiments of the application;

fig. 5 is a flow chart of a method of manufacturing a haze structure in other embodiments of the application.

Reference numerals:

100. an atomizing structure; 10. installing a pipe; 102. a first groove; 104. a second groove; 106. an oil inlet hole; 11. an elastic sheet; 12. limiting convex hulls; 13. a clamping member; 132. a connection section; 134. parallel sections; 136. a holding part; 14. a first end; 15. a second end; 20. a heating assembly; 30. an oil guide; 32. an extension; 40. a sleeve member.

Detailed Description

In order that the application may be readily understood, a more particular description thereof will be rendered by reference to specific embodiments that are illustrated in the appended drawings. It will be understood that when an element is referred to as being "connected" to another element, it can be directly on the other element or one or more intervening elements may be present therebetween. The terms "upper," "lower," "left," "right," "upper," "lower," "top," and "bottom," and the like, as used herein, refer to an orientation or positional relationship based on that shown in the drawings, merely for convenience in describing the present application and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present application. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used in the description of the application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application.

The following describes a method for manufacturing the atomizing structure 100 and the atomizing structure 100 according to the embodiments of the present application in detail by referring to the drawings throughout the specification.

Referring to fig. 1 to 3, an atomization structure 100 according to an embodiment of the present application is disclosed, including: mounting tube 10, heating assembly 20 and oil guide 30; the installation tube 10 comprises a first end 14 and a second end 15, a first groove 102 is formed in the side wall of the installation tube 10, an elastic sheet 11 is connected to the groove wall of the first groove 102 close to the first end 14, one end, far away from the first end 14, of the elastic sheet 11 is a free end, the free end of the elastic sheet 11 is arranged in the installation tube 10, and the inner side wall of the installation tube 10 protrudes to form a limiting convex hull 12. The heating assembly 20 is used to heat the tobacco tar. The oil guide 30 wraps the heating assembly 20 along the outer side wall of the heating assembly 20, the oil guide 30 and the heating assembly 20 are arranged in the mounting tube 10, the elastic sheet 11 is elastically deformed, the elastic sheet 11 clamps the oil guide 30 with the inner wall of the mounting tube 10, and the end part of the oil guide 30 abuts against the limiting convex hull 12.

Specifically, in this embodiment, the installation tube 10 is a steel tube, and the sidewall of the installation tube 10 is provided with a plurality of oil inlet holes 106, the oil inlet holes 106 are waist-shaped, and the waist line of the oil inlet holes 106 is parallel to the axis of the installation tube 10. The elastic piece 11 and the mounting tube 10 are integrally formed, three rectangular sides are cut along the side wall of the mounting tube 10 to form a first groove 102 and the elastic piece 11, and one end of the elastic piece 11 close to the first end 14 is connected with the groove wall of the first groove 102; the flexible sheet 11 is then bent into the mounting tube 10 by an angle of less than 90 deg., whereby the free end of the flexible sheet 11 is placed in the mounting tube 10. The limiting convex hull 12 is formed by stamping along the outer side wall of the mounting tube 10, the limiting convex hull 12 is kidney-shaped, the limiting convex hull 12 includes a set of limiting convex hulls, and the limiting convex hull 12 is disposed between the first end 14 and the first groove 102.

In other embodiments, the mounting tube 10 may also be made of other rigid materials, such as copper or high temperature resistant plastic; the shape of the oil inlet hole 106 may be other, such as circular; the first groove 102 may be of other shapes, such as triangle, the elastic piece 11 may be made of different materials from the mounting tube 10, and one end of the elastic piece 11 may be welded or otherwise fixedly connected to the groove wall of the first groove 102.

The limiting convex hull 12 may also have other shapes, such as a circle, and the limiting convex hull 12 may further include two or three groups, where when the limiting convex hull 12 is two groups, one group of limiting convex hulls 12 is disposed between the first end 14 and the first groove 102, and another group of limiting convex hulls 12 is disposed between the second end 15 and the first groove 102; when the limit convex hulls 12 are three groups, the first group of limit convex hulls 12 are arranged between the first end 14 and the first groove 102, the second group of limit convex hulls 12 are arranged between the second end 15 and the first groove 102, and the third group of limit convex hulls 12 are arranged between the first group of limit convex hulls 12 and the second group of limit convex hulls 12; the limiting convex hulls 12 of the same group are uniformly distributed circumferentially with the axis of the mounting tube 10 as the center.

The heating assembly 20 comprises a heating wire and an electrode, the electrode is used for connecting a power supply, and in the embodiment, the heating wire is in a spring shape; in other embodiments, the heater wire may take other shapes, such as a mesh structure rolled into a tube. In the present embodiment, the oil guide 30 is made of cotton, and the oil guide 30 has a sheet-like structure; in other embodiments, the oil guide 30 may be made of other malleable materials.

Through the structure, the heating assembly 20 is firstly wrapped around the oil guide 30 along the outer side of the heating assembly 20, then the heating assembly 20 and the oil guide 30 are inserted into the mounting tube 10 along the first end 14, the heating assembly 20 and the oil guide 30 move along the mounting tube 10 along the first end 14 towards the second end 15, when the heating assembly 20 and the oil guide 30 move to the first groove 102, the side wall of the oil guide 30 can resist the side wall of the elastic sheet 11 towards the axis of the mounting tube 10, and then the elastic sheet 11 is elastically deformed, so that pressure is arranged between the side wall of the elastic sheet 11 and the side wall of the oil guide 30, the side wall of the elastic sheet 11 is abutted against the side wall of the oil guide 30, and the side wall of the elastic sheet 11 and the inner side wall of the mounting tube 10 clamp the oil guide 30.

Meanwhile, the limiting convex hull 12 is propped against the end part of the oil guide piece 30, the limiting convex hull 12 plays a limiting role on the oil guide piece 30 along the axial direction of the mounting pipe 10, the oil guide piece 30 is difficult to loosen relative to the mounting pipe 10 after being clamped finally, and meanwhile, the oil guide piece 30 is difficult to move along the axial direction of the mounting pipe 10 under the action of the limiting convex hull 12, so that the assembly relationship between the oil guide piece 30 and the mounting pipe 10 is more stable.

Referring to fig. 1, 3 and 4, in some embodiments, the mounting tube 10 is provided with a second groove 104, a groove wall of the second groove 104 near the second end 15 is connected with a clamping member 13, and a fastening portion 136 is disposed at one end of the clamping member 13 away from the groove wall of the second groove 104; the outer side wall of the oil guide 30 is connected with an extension part 32; the extension part 32 extends out of the mounting tube 10 along the second groove 104, the extension part 32 is wound at least one circle along the outer side wall of the mounting tube 10, one end of the clamping piece 13 connected with the groove wall of the second groove 104 abuts against one end of the extension part 32, the buckling part 136 is partially arranged in the mounting tube 10, and the buckling part 136 abuts against the other end of the extension part 32; the side wall of the clamp 13 abuts against the side wall of the extension 32.

Specifically, in the present embodiment, the second groove 104 is rectangular, the second groove 104 is opened along the first end 14, and a chamfer is provided between the groove wall of the second groove 104 and the first end 14; the distance from the second slot 104 to the second end 15 is equal to the distance from the first slot 102 to the second end 15, and the axis of the first slot 102, the axis of the second slot 104 and the axis of the mounting tube 10 are coplanar; the first end 14 cuts the mounting tube 10 along two line segments parallel to the axis of the mounting tube 10 to form a second groove 104 and a clamping piece 13, and the clamping piece 13 and the second groove 104 are integrally formed, so that the clamping piece 13 is connected to the groove wall of the second groove 104 near the second end 15. One end of the clamping piece 13, which is close to the first end 14, is bent towards the axial direction of the mounting tube 10 to form a buckling part 136; when the buckling part 136 is partially arranged in the installation tube 10, the sleeve member 40 is sleeved on the outer side wall of the installation tube 10, and the end part of the sleeve member 40 abuts against the buckling part 136, so that the buckling part 136 is limited.

In other embodiments, the second slot 104 may also have other shapes, such as triangular; the axis of the second slot 104, the axis of the second slot 104 and the axis of the mounting tube 10 may also be non-coplanar; the distance from the second slot 104 to the second end 15 may be different from the distance from the first slot 102 to the second end 15, the clamping member 13 may not be integrally formed with the mounting tube 10, and the clamping member 13 may be fixedly connected to the mounting tube 10 by welding or other means; the catch 136 may also be partially disposed within the mounting tube 10 by other means, such as a snap fit or a plug fit.

The extending part 32 is in a sheet structure, and the extending part 32 and the oil guide 30 are integrally formed; along the axial direction of the mounting tube 10, the height of the extension portion 32 is equal to the height of the oil guide 30, the extension portion 32 is in a sheet-like structure, and the length of the extension portion 32 perpendicular to the axial direction of the mounting tube 10 is greater than the outer diameter of the mounting tube 10, so that the extension portion 32 can be wound at least one round along the outer side wall of the mounting tube 10.

Through the above structure, the extension portion 32 extends out of the installation tube 10 along the second groove 104, and after at least one circle of winding along the installation tube 10, when the fastening portion 136 is partially disposed in the installation tube 10, the fastening portion 136 abuts against one end of the extension portion 32 close to the first end 14, and the outer side wall of the extension portion 32 abuts against the side edge of the clamping member 13 close to the axis of the installation tube 10, and meanwhile, one end of the extension portion 32 close to the second end 15 abuts against one end of the clamping member 13 connected with the wall of the second groove 104, so that under the action of the clamping member 13, the extension portion 32 is limited, and then the oil guide member 30 connected to the extension portion 32 is further limited, so that the atomization structure 100 in this embodiment has better stability. In addition, under the action of the extension portion 32, the oil guide 30 and the oil storage member arranged outside the installation tube 10 can have a larger contact area, so that the conduction efficiency of tobacco tar is improved.

In some embodiments, the atomizing structure 100 further includes a sleeve member 40, the inner diameter of the sleeve member 40 being adapted to the outer diameter of the mounting tube 10; the sleeve member 40 is sleeved on the outer side wall of the installation tube 10 along the first end 14, and one end of the sleeve member 40 abuts against the buckling portion 136.

Specifically, the sleeve member 40 in this embodiment is a glass fiber tube; in other embodiments, the sleeve member 40 may also be made of other materials, such as plastic.

Through the above-mentioned structure, because the size of atomizing structure 100 is certain, therefore the length after sleeve spare 40 and installation pipe 10 are connected and the overall dimension adaptation of atomizing structure 100, and then under the effect of sleeve spare 40, the length of installation pipe 10 reduces, because installation pipe 10 is made by steel, and sleeve spare 40 is made by the fine material of glass, consequently, when saving material cost, reduced atomizing structure 100's total quality for atomizing structure 100 is more convenient.

In addition, under the cooperation of the sleeve member 40 and the retaining portion 136, the sleeve member 40 is supported by the retaining portion 136, and is difficult to move along the axis of the mounting tube 10 toward the second end 15, so that the sleeve member 40 is difficult to press the extension portion 32; meanwhile, when the buckling part 136 is pressed by the sleeve member 40, the part of the buckling part 136 placed in the installation tube 10 is difficult to tilt, so that the buckling part 136 and the sleeve member 40 can be mutually limited, and the installation process of the atomization structure 100 in the embodiment is more convenient.

Meanwhile, since the thermal stability of the steel material is better, the installation tube 10 is made of the steel material, but the thermal conductivity of the steel material is better, so that the heat of the gaseous tobacco tar may be absorbed by the side wall of the installation tube 10 during the process of flowing out along the installation tube 10, the tobacco tar may be condensed on the side wall of the installation tube 10, thereby reducing the atomization efficiency, and the tobacco tar output along the first end 14 of the installation tube 10 may be partially in a liquid state. In the embodiment, the sleeve member 40 made of glass fiber material is adopted, so that the length of the mounting tube 10 is shortened, the heat conduction efficiency of the glass fiber material is lower, and the gaseous tobacco tar is not easy to condense in the process of flowing along the sleeve member 40; furthermore, the atomization structure 100 in this embodiment reduces the contact area between the gaseous tobacco tar and the sidewall of the installation tube 10, and reduces the possibility of condensation during the output process of the gaseous tobacco tar.

In some embodiments, the second slot 104 is disposed through the first end 14 with a chamfer disposed between the second slot 104 and the slot wall of the first end 14.

Specifically, the first end 14 is cut along two points of the first end 14, the cutting direction is parallel to the axis of the mounting tube 10, and the lengths of the two cuts are equal, so that the second groove 104 and the clamping piece 13 can be formed, and the condition that the second groove 104 penetrates through the first end 14 is satisfied.

With the above structure, the sleeve member 40 is more easily sleeved outside the mounting tube 10 along the first end 14 under the chamfering effect; meanwhile, the integrated molding of the installation tube 10 and the clamping piece 13 is realized, and the manufacturing process of the installation tube 10 is simplified. In addition, when the second groove 104 is formed along the first end 14, the extension portion 32 can directly cooperate with the second groove 104 when the oil guide 30 is inserted into the mounting tube 10 along the first end 14, and the extension portion 32 is more easily protruded along the second groove 104.

In some embodiments, the first slot 102 and the second slot 104 are respectively disposed on two sides of the axis of the mounting tube 10, and the distance from the connecting end of the clamping member 13 and the slot wall of the second slot 104 to the second end 15 is adapted to the distance from the free end of the elastic piece 11 to the second end 15.

Specifically, the axis of the first groove 102, the axis of the second groove 104 and the axis of the mounting tube 10 are coplanar, and thus the first groove 102 and the second groove 104 are provided on both sides of the axis of the mounting tube 10, respectively. The distance of the second groove 104 near the second end 15 is equal to the distance of the first groove 102 near the second end 15, and thus the distance from the connecting end of the clamping member 13 and the groove wall of the second groove 104 to the second end 15 is adapted to the distance from the free end of the elastic piece 11 to the second end 15.

With the above structure, since the first groove 102 and the second groove 104 are respectively disposed on two sides of the axis of the mounting tube 10, the elastic piece 11 can press the oil guide 30 along one side of the oil guide 30, the clamping piece 13 can press the extending portion 32 along the other side of the oil guide 30, and further press the oil guide 30, so that the elastic piece 11 and the clamping piece 13 have a clamping effect on the oil guide 30, and finally the oil guide 30 is more stable relative to the mounting tube 10.

In addition, when the distance from the connecting end of the clamping member 13 and the groove wall of the second groove 104 to the second end 15 is adapted to the distance from the free end of the elastic piece 11 to the second end 15, when the extending portion 32 abuts against the groove wall of the second groove 104, which is close to the second end 15, the oil guide member 30 can be placed at a proper position in the mounting tube 10, and the end portion of the oil guide member 30 can abut against the limiting convex hull 12.

In some embodiments, the clamping member 13 includes a connecting section 132 and a parallel section 134, one end of the connecting section 132 is connected to the groove wall of the second groove 104 near the second end 15, the other end is connected to one end of the parallel section 134, the parallel section 134 is parallel to the axis of the mounting tube 10, and one end of the parallel section 134 far from the connecting section 132 is connected to the fastening part 136; one end of the extension portion 32 abuts against the connecting section 132, the other end of the extension portion 32 abuts against the holding portion 136, and the parallel section 134 abuts against the side wall of the extension portion 32.

Specifically, the connecting section 132, the parallel section 134 and the fastening portion 136 are all in rectangular sheet structures, and the clamping member 13 is in a strip-shaped sheet structure as a whole; the clamping member 13 is bent 90 ° along the groove wall of the second groove 104 to form a connecting section 132, the connecting section 132 is bent reversely 90 ° to form a parallel section 134, and then one end of the parallel section 134 away from the connecting section 132 is bent at an acute angle toward the axis of the mounting tube 10 to form a holding portion 136. The axis of the connecting section 132 is perpendicular to the axis of the mounting tube 10, and the length of the connecting section 132 is smaller than the thickness of the extension 32, so that the connecting section 132 can clamp the extension 32 with the mounting tube 10; the length of the holding portion 136 is greater than twice the length of the connecting section 132, and therefore, the holding portion 136 can be placed in the installation tube 10 only by bending an angle smaller than 30 degrees.

With the above structure, since the oil guide 30 partially protrudes along the second groove 104 under the extrusion action of the elastic sheet 11, the connection section 132 can limit the end of the extension portion 32 and the end of the oil guide 30, and thus the possibility that the oil guide 30 slides along the axis of the mounting tube 10 is reduced. In addition, under the action of the connecting section 132, the gap between the parallel section 134 and the outer side wall of the mounting tube 10 is larger, so that the deformation amount of the extension portion 32 when clamped is reduced, and the oil guiding efficiency between the oil guiding member 30 and the extension portion 32 is improved.

Referring back to fig. 4, in some embodiments, the limiting convex hull 12 includes two sets, wherein one set of limiting convex hull 12 abuts against one end of the oil guiding member 30, and the other set of limiting convex hull 12 abuts against the other end of the oil guiding member 30.

Specifically, one set of limiting convex hulls 12 is disposed between the first end 14 and the first groove 102, the other set of limiting convex hulls 12 is disposed between the second end 15 and the first groove 102, and the distance between the two sets of limiting convex hulls 12 is adapted to the height of the oil guide 30. In this embodiment, each set of limit projections 12 includes one limit projection 12; in other embodiments, each set of limit projections 12 may also include other numbers of limit projections 12; and all the limiting convex hulls 12 in each group of limiting convex hulls 12 are uniformly distributed circumferentially by taking the axis of the mounting tube 10 as a central line.

Through the structure, when the oil guide 30 is placed at the first groove 102, one group of limiting convex hulls 12 are propped against one end of the oil guide 30, the other group of limiting convex hulls 12 are propped against the other end of the oil guide 30, and then the two groups of limiting convex hulls 12 limit the oil guide 30 at the same time, so that the oil guide 30 is more difficult to move along the axial direction of the mounting pipe 10, and the stability between the oil guide 30 and the mounting pipe 10 is improved.

Referring to fig. 5, another embodiment of the present application further provides a method for manufacturing an atomization structure 100, which includes:

501: the mounting tube 10, the heating assembly 20 and the oil guide 30 are provided, the mounting tube 10 comprises a first end 14 and a second end 15, a first groove 102 is formed in the side wall of the mounting tube 10, an elastic piece 11 is connected to the groove wall of the first groove 102 close to the first end 14, one end, away from the groove wall of the first groove 102, of the elastic piece 11 is a free end, the free end of the elastic piece 11 is arranged in the mounting tube 10, and the inner side wall of the mounting tube 10 protrudes to form a limiting convex hull 12.

Providing a part for manufacturing the atomizing structure 100; the mounting tube 10 is a steel tube, the heating component 20 is a spiral heating wire, and the oil guide 30 is a flaky oil guide cotton; the side wall of the installation tube 10 is provided with a plurality of oil inlet holes 106, and the oil inlet holes 106 and the first groove 102 are positioned at the same height along the axial direction of the installation tube 10.

502: the oil guide 30 is wrapped around the heating element 20 along the outer sidewall of the heating element 20.

The sheet-shaped oil guide 30 is rolled up in a cylindrical shape along the outer side wall of the heating assembly 20, and thus the oil guide 30 can wrap the heating assembly 20 along the outer side wall of the heating assembly 20.

503: the heating assembly 20 and the oil guide 30 are inserted into the mounting tube 10 in the direction from the first end 14 to the second end 15.

Since the mounting tube 10 is cylindrical, openings are provided at both the first end 14 and the second end 15 of the mounting tube 10, and the heating element 20 and the oil guide 30 are inserted into the mounting tube 10 along the mounting tube 10 at the opening of the first end 14.

504: the heating assembly 20 and the oil guide 30 are moved until the end of the oil guide 30 abuts against the limiting convex hull 12, the side wall of the oil guide 30 is placed at the first groove 102, the side wall of the oil guide 30 abuts against the side wall of the elastic sheet 11, and the elastic sheet 11 is made to be elastic, so that the side wall of the elastic sheet 11 and the inner wall of the mounting tube 10 clamp the oil guide 30.

The heating assembly 20 and the oil guide 30 are forced to move along the direction from the first end 14 to the second end 15, and in the process that the heating assembly 20 and the oil guide 30 move to the first groove 102, the side wall of the oil guide 30 gradually presses against the side wall of the elastic sheet 11, so that the elastic sheet 11 gradually deforms elastically; when the end of the oil guide 30 abuts against the corresponding limit protrusion 12, the heating assembly 20 and the oil guide 30 stop moving.

By the above method, due to the elastic deformation of the elastic piece 11, the elastic piece 11 and the side wall of the oil guide 30 have elastic force, so that the corresponding side wall of the installation pipe 10 and the oil guide 30 have pressure, and therefore the elastic piece 11 and the side wall of the installation pipe 10 can clamp the oil guide 30, and the oil guide 30 is difficult to move along the axis direction of the installation pipe 10. In addition, the end of the oil guide 30 is limited by the limiting convex hull 12, so that the oil guide 30 is more difficult to move along the axial direction of the mounting tube 10, and the possibility that the oil guide 30 may slide relative to the mounting tube 10 is further reduced.

In some embodiments, the mounting tube 10 is provided with a second groove 104, a clamping member 13 is connected to a groove wall of the second groove 104 near the second end 15, and a fastening portion 136 is provided at one end of the clamping member 13 away from the groove wall of the second groove 104; the outer side wall of the oil guide 30 is connected with an extension part 32; the manufacturing method further comprises the following steps: extending the extension 32 out of the mounting tube 10 along the second slot 104; wrapping the extension 32 around the mounting tube 10 along the outer sidewall of the mounting tube 10 at least one revolution; one end of the extension part 32 is propped against one end of the clamping piece 13 connected with the wall of the second groove 104; the retainer 136 is partially disposed within the mounting tube 10 such that the retainer 136 abuts the other end of the extension 32 and the side wall of the clamp 13 compresses the side wall of the extension 32.

By the above method, the extension portion 32 can extend out of the mounting tube 10 along the second groove 104, and when the extension portion 32 is wound around the mounting tube 10 along the outer side of the mounting tube 10, on one hand, one end of the extension portion 32 can abut against the bottom wall of the second groove 104, and meanwhile, the fastening portion 136 can abut against the other end of the extension portion 32, so that the extension portion 32 can be limited along the axial direction of the mounting tube 10, and further, the oil guide 30 connected to the extension portion 32 can be further limited along the axial direction of the mounting tube 10. In addition, under the action of the extension portion 32, the oil guide 30 can have a larger contact area with the oil storage member disposed at the outer side of the installation tube 10, thereby improving the oil guide efficiency of the oil guide 30.

In some embodiments, the method of manufacturing further comprises: providing a sleeve member 40, the inner diameter of the sleeve member 40 being adapted to the outer diameter of the mounting tube 10; sleeving the sleeve member 40 on the outer side wall of the mounting tube 10 along the first end 14; the sleeve member 40 is moved in the direction from the first end 14 to the second end 15 such that one end of the sleeve member 40 abuts against the catching portion 136.

Through the above method, on one hand, the sleeve member 40 can play a limiting role on the holding portion 136, and the mutual limitation of the sleeve member 40 and the holding portion 136 can be completed only by abutting the sleeve member 40 against the holding portion 136, so that the fixing step of the holding portion 136 is simplified. On the other hand, the sleeve member 40 may be made of glass fiber material or other materials with poor thermal conductivity, so that the heat in the gaseous tobacco tar is not easy to be taken away by the inner wall of the sleeve member 40 in the process that the tobacco tar flows through the sleeve member 40, so that the gaseous tobacco tar is not easy to be condensed on the inner wall of the sleeve member 40, and finally, the proportion of the gaseous tobacco tar in the tobacco tar output along the atomization structure 100 is improved, and the overall atomization efficiency of the atomization structure 100 is improved.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present application, and are not limiting; the technical features of the above embodiments or in the different embodiments may also be combined within the idea of the application, the steps may be implemented in any order, and there are many other variations of the different aspects of the application as described above, which are not provided in detail for the sake of brevity; while the application has been described in detail with reference to the foregoing embodiments, those skilled in the art will appreciate that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the corresponding technical solutions from the scope of the technical solutions of the embodiments of the present application.

Claims (10)

1. A method of manufacturing an atomizing structure, comprising:

providing an installation tube, a heating assembly and an oil guide piece, wherein the installation tube comprises a first end and a second end, a first groove is formed in the side wall of the installation tube, an elastic sheet is connected to the groove wall of the first groove, which is close to the first end, one end, away from the first end, of the elastic sheet is a free end, the free end of the elastic sheet is arranged in the installation tube, and the inner side wall of the installation tube protrudes to form a limiting convex hull;

wrapping the oil guide member around the heating element along the outer wall of the heating element;

inserting the heating assembly and the oil guide member into the mounting tube along the direction from the first end to the second end;

and moving the heating assembly and the oil guide piece until the end part of the oil guide piece is propped against the limiting convex hull, and the side wall of the oil guide piece is arranged at the first groove, wherein the side wall of the oil guide piece is propped against the side wall of the elastic piece, so that the elastic piece is in an elastic shape, and the side wall of the elastic piece and the inner wall of the mounting tube clamp the oil guide piece.

2. The method for manufacturing an atomization structure according to claim 1, wherein a second groove is formed in the mounting tube, a clamping piece is connected to a groove wall of the second groove, which is close to the second end, and a buckling part is arranged at one end of the clamping piece, which is far away from the groove wall of the second groove; the outer side wall of the oil guide piece is connected with an extension part;

the manufacturing method further comprises the steps of:

extending the extension out of the mounting tube along the second slot;

wrapping the extension around the mounting tube at least one revolution along the mounting tube outer sidewall;

one end of the extending part is propped against one end of the clamping piece connected with the wall of the second groove;

the buckling part is arranged in the mounting pipe, so that the buckling part abuts against the other end of the extending part, and the side wall of the clamping piece presses the side wall of the extending part.

3. The method of manufacturing an atomizing structure according to claim 2, further comprising: providing a sleeve member, an inner diameter of the sleeve member being adapted to an outer diameter of the mounting tube;

sleeving the sleeve part on the outer side wall of the mounting tube along the first end;

and moving the sleeve member along the direction from the first end to the second end, so that one end of the sleeve member abuts against the buckling part.

4. An atomizing structure, comprising:

the mounting tube comprises a first end and a second end, a first groove is formed in the side wall of the mounting tube, an elastic sheet is connected to the groove wall of the first groove, which is close to the first end, one end, away from the groove wall of the first groove, of the elastic sheet is a free end, the free end of the elastic sheet is arranged in the mounting tube, and the inner side wall of the mounting tube protrudes to form a limiting convex hull;

a heating assembly;

the oil guide piece is wrapped on the outer side wall of the heating assembly, the oil guide piece and the heating assembly are arranged in the mounting pipe, the elastic piece is elastically deformed, the elastic piece and the inner wall of the mounting pipe clamp the oil guide piece, and the end part of the oil guide piece is propped against the limiting convex hull.

5. The atomizing structure of claim 4, wherein the mounting tube is provided with a second groove, a clamping piece is connected to a groove wall of the second groove close to the second end, and a buckling part is arranged at one end of the clamping piece away from the groove wall of the second groove; the outer side wall of the oil guide piece is connected with an extension part; the extending part extends out of the mounting pipe along the second groove, the extending part is wound at least one circle along the outer side wall of the mounting pipe, one end of the clamping piece connected with the groove wall of the second groove is propped against one end of the extending part, the buckling part is arranged in the mounting pipe, and the buckling part is propped against the other end of the extending part; the side wall of the clamping piece is propped against the side wall of the extension part.

6. The atomizing structure of claim 5, further comprising a sleeve member having an inner diameter adapted to an outer diameter of said mounting tube; the sleeve member is sleeved on the outer side wall of the mounting tube along the first end, and one end of the sleeve member abuts against the buckling part.

7. The atomizing structure of claim 6, wherein the second slot is disposed through the first end, and a chamfer is disposed between a slot wall of the second slot and the first end.

8. The atomizing structure according to claim 5, wherein the first groove and the second groove are provided on both sides of the mounting tube axis, respectively, and a distance from a connecting end of the clamping member and the second groove wall to the second end is adapted to a distance from a free end of the elastic piece to the second end.

9. The atomizing structure of claim 5, wherein the holder includes a connecting section and a parallel section, one end of the connecting section is connected to a groove wall of the second groove near the second end, the other end is connected to one end of the parallel section, the parallel section is disposed parallel to an axis of the mounting tube, and one end of the parallel section away from the connecting section is connected to the holding portion; one end of the extending part is propped against the connecting section, the other end of the extending part is propped against the buckling part, and the parallel section is propped against the side wall of the extending part.

10. The atomizing structure of claim 4, wherein the limiting projection comprises two sets, one set of the limiting projection being against one end of the oil guide and the other set of the limiting projection being against the other end of the oil guide.