CN215303022U - Three-dimensional atomization assembly and atomizer thereof - Google Patents

Abstract

The utility model discloses a three-dimensional atomization assembly and an atomizer thereof, wherein the three-dimensional atomization assembly comprises a porous liquid guide body with an atomization surface and a liquid inlet surface and a three-dimensional heating body matched with the porous liquid guide body for use, the three-dimensional heating body is provided with a bending part and forms a heating body with a plurality of heating dimensions through the bending part; the three-dimensional heating body comprises a first electrode, a second electrode and at least two heating tracks connected in parallel between the first electrode and the second electrode, the heating tracks are bent and deformed to form a plurality of heating dimensions, the three-dimensional atomizer comprises a three-dimensional atomizing assembly, a base, an upper fixing base and a liquid storage bin. This kind of three-dimensional atomization component and atomizer thereof have that the atomizing area is big, small, smog volume advantage such as big for miniaturized atomization component and atomizer also can provide enough big smog volume, promote to use and experience, can satisfy the pursuit of user to small volume and big smog and experience.

Description

Three-dimensional atomization assembly and atomizer thereof

Technical Field

The utility model relates to the field of electronic cigarettes, in particular to a three-dimensional atomization assembly and an atomizer thereof.

Background

The electronic atomizer applied to the field of electronic atomization at present mainly comprises a cylindrical heating element and a sheet-shaped heating element, wherein the sheet-shaped heating element mostly adopts planar sheet heating. Along with the development of the electronic atomization industry, users prefer products which are small in size, large in atomization amount and long in endurance, so that the space reserved for heating and atomizing of the heating body is smaller and smaller, the sheet-type heating body is limited by the product space, the sufficient atomization amount is hardly exploded to supply for user experience, the experience of small size and large smoke pursued by the users cannot be met simultaneously, and the use experience is poor.

Therefore, the present invention aims to provide a new technical solution to solve the existing technical drawbacks.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model provides a three-dimensional atomization component and an atomizer thereof, which solve the technical defects that the existing product has small smoke quantity and is difficult to be compatible with miniaturization and large smoke.

The technical scheme adopted by the utility model for solving the technical problems is as follows:

the utility model provides a three-dimensional atomizing subassembly, is including having the porous liquid of leading of atomizing face and liquid inlet face and cooperation the porous three-dimensional heat-generating body that leads the liquid and use, three-dimensional heat-generating body has the bending part and forms the heat-generating body that has a plurality of heating dimensions through the bending part.

As an improvement of the above technical solution, the three-dimensional heating element includes a first electrode, a second electrode, and at least two heating traces connected in parallel between the first electrode and the second electrode, and the heating traces are bent and deformed to form a heating element having a plurality of heating dimensions.

As a further improvement of the above technical solution, the porous liquid guiding body is a hard porous liquid guiding body, the three-dimensional heating body is embedded in the porous liquid guiding atomization surface, the first electrode and the second electrode of the three-dimensional heating body have bending portions, the bending portions are embedded in the porous liquid guiding body, and the heating track of the three-dimensional heating body has a surface exposed outside the porous liquid guiding atomization surface.

As a further improvement of the above technical solution, the porous liquid guide body is a hard porous liquid guide body, the three-dimensional heating element is embedded in the porous liquid guide body, the end portions of the first electrode and the second electrode of the three-dimensional heating element are exposed outside the porous liquid guide body, and all surfaces of the heating track of the three-dimensional heating element are embedded inside the porous liquid guide body.

As a further improvement of the technical scheme, the porous liquid guide body is soft porous liquid guide body, and the three-dimensional heating body is attached to the outer surface of the atomization surface of the porous liquid guide body.

As a further improvement of the above technical solution, the atomization surface of the porous liquid guide body is three surfaces with rectangular cross sections, and includes a bottom surface and two vertical side surfaces, the heating tracks of the three-dimensional heating body are installed on the bottom surface and the two vertical side surfaces of the porous liquid guide body, and the three-dimensional surface formed by the heating tracks is substantially parallel to the atomization surface of the porous liquid guide body.

As a further improvement of the above technical solution, the atomization surface of the porous liquid guide body is three surfaces with trapezoidal cross sections, and includes a bottom surface and two slope surfaces, the heating tracks of the three-dimensional heating body are installed on the bottom surface and the two slope surfaces of the porous liquid guide body, and the three-dimensional surface formed by the heating tracks is substantially parallel to the atomization surface of the porous liquid guide body.

As a further improvement of the above technical solution, the atomization surface of the porous liquid guide is two surfaces with obtuse triangle cross sections, and includes a first inclined surface and a second inclined surface, the heating trajectory of the three-dimensional heating body is installed on the first inclined surface and the second inclined surface of the porous liquid guide, and the three-dimensional surface formed by the heating trajectory is substantially parallel to the atomization surface of the porous liquid guide.

As a further improvement of the above technical solution, the atomization surface of the porous liquid guide is an arc surface with an arc-shaped cross section, the heating trajectory of the three-dimensional heating body is installed on the inclined surface of the porous liquid guide, and the three-dimensional surface formed by the heating trajectory is substantially parallel to the atomization surface of the porous liquid guide.

As a further improvement of the above technical solution, the heating tracks on the three-dimensional heating body between the first electrode and the second electrode are in a rhombus shape or a rectangular shape or a wave shape or an S-shaped extending distribution, and two or more heating tracks on the three-dimensional heating body are provided, and two adjacent heating tracks are connected with each other.

As a further improvement of the above technical solution, the first electrode and the second electrode of the three-dimensional heating body have bent portions, and the first electrode and the second electrode can be welded to the electrode leads.

As a further improvement of the technical scheme, at least one liquid inlet groove is formed in the porous liquid guide body, and the porous liquid guide body is a porous ceramic body, a liquid guide cotton, a non-woven fabric or a fiber liquid guide body.

The utility model also provides a three-dimensional atomizer which comprises the three-dimensional atomization assembly.

As an improvement of the above technical scheme, still include the base, go up fixing base and stock solution storehouse, three-dimensional atomizing unit installs on the base, it installs on three-dimensional atomizing unit upper portion and is used for fixing three-dimensional atomizing unit on the base to go up the fixing base, the stock solution storehouse is used for storing the tobacco juice and fixes on the base, the liquid outlet in stock solution storehouse and the feed liquor face intercommunication of porous leaded liquid, the inlet port just has on the base the inlet port just the inlet port communicates with the atomizing face of porous leaded liquid, the stock solution storehouse has the outlet flue just the outlet flue with the inlet port intercommunication of the atomizing face of porous leaded liquid and base.

As a further improvement of the above technical scheme, the base is further provided with two electrode thimbles, the two electrode thimbles are respectively in electrical contact with two ends of the three-dimensional heating body, and each electrode thimble has an end face exposed at the bottom of the base.

As a further improvement of the technical scheme, the side part of the base is provided with a step position, the lower edge of the liquid storage bin is fixed at the step position, and a silica gel sealing ring is arranged between the inner wall of the liquid storage bin and the outer wall of the base.

As a further improvement of the technical scheme, a first sealing silica gel sleeve is arranged between the porous liquid guide body and the inner wall of the upper fixing seat, and a second sealing silica gel sleeve is arranged between the outer wall of the upper fixing seat and the inner wall of the liquid storage bin.

As a further improvement of the technical scheme, the liquid storage bin is provided with two liquid storage inner cavities, the upper fixing seat is provided with two liquid guide holes, and the two liquid storage inner cavities are communicated with the liquid inlet surface of the porous liquid guide through the two liquid guide holes in the upper fixing seat respectively.

As a further improvement of the above technical scheme, the base is internally provided with an atomization inner cavity, the porous atomization surface for guiding the liquid and the three-dimensional heating body are both positioned in the atomization inner cavity, the upper fixing seat is provided with a fixing seat smoke hole, the side part of the upper fixing seat is provided with a side part notch, the side part notch communicates the atomization inner cavity with the fixing seat smoke hole, and the smoke outlet of the liquid storage bin is communicated with the fixing seat smoke hole.

The utility model has the beneficial effects that: the three-dimensional atomizing assembly and the atomizer thereof adopt the cooperation of the three-dimensional heating body and the porous liquid guide body, and can provide a larger atomizing area in the same volume space in actual application, so that the miniaturized atomizing assembly and the atomizer can also provide enough smoke volume, the use experience is improved, and the pursuit experience of a user for small-volume and large smoke can be met.

In conclusion, the three-dimensional atomization assembly and the atomizer thereof solve the technical defects that the existing product is small in smoke amount and is difficult to be compatible with miniaturization and large smoke.

Drawings

The utility model is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic assembly of an embodiment 1 of a three-dimensional atomizing assembly of the present invention;

FIG. 2 is another schematic assembly view of embodiment 1 of the three-dimensional atomizing assembly of the present invention;

FIG. 3 is a structurally broken away view of embodiment 1 of the three-dimensional atomizing assembly of the present invention;

FIG. 4 is a schematic cross-sectional view of embodiment 1 of the three-dimensional atomizing assembly of the present invention;

FIG. 5 is a schematic view showing the structure of a three-dimensional heating body in example 1 of the three-dimensional atomizing assembly of the present invention;

FIG. 6 is a schematic assembly view of embodiment 2 of the three-dimensional atomizing assembly of the present invention;

FIG. 7 is a structurally broken away view of embodiment 2 of the three-dimensional atomizing assembly of the present invention;

FIG. 8 is a schematic cross-sectional view of embodiment 2 of a three-dimensional atomizing assembly of the present invention;

FIG. 9 is a schematic assembly view of embodiment 3 of the three-dimensional atomizing assembly of the present invention;

FIG. 10 is a structurally broken away view of the three-dimensional atomizing assembly of embodiment 3 of the present invention;

FIG. 11 is a schematic cross-sectional view of embodiment 3 of a three-dimensional atomizing assembly of the present invention;

FIG. 12 is a schematic assembly view of embodiment 4 of a three-dimensional atomizing assembly of the present invention;

FIG. 13 is a structurally broken away view of the three-dimensional atomizing assembly of embodiment 4 of the present invention;

FIG. 14 is a schematic cross-sectional view of embodiment 4 of a three-dimensional atomizing assembly of the present invention;

FIG. 15 is a schematic structural view of a first embodiment of the porous liquid-conductive body of the present invention in cooperation with a three-dimensional heating body;

FIG. 16 is a schematic structural view of a second embodiment of the porous liquid-conductive body of the present invention in cooperation with a three-dimensional heating body;

FIG. 17 is a schematic structural view of a third embodiment of the porous liquid-conductive body of the present invention in cooperation with a three-dimensional heating body;

FIG. 18 is a schematic structural view of example 1 of the three-dimensional heating body of the present invention;

FIG. 19 is a schematic structural view of example 2 of the three-dimensional heating body of the present invention;

FIG. 20 is a schematic structural view of example 3 of the three-dimensional heating body of the present invention;

FIG. 21 is a schematic structural view of embodiment 4 of the three-dimensional heating body of the present invention;

fig. 22 is a schematic view of a three-dimensional heating body according to the present invention having three heating traces;

FIG. 23 is a sectional view showing the structure of a three-dimensional atomizer according to the present invention;

FIG. 24 is a sectional view showing another structure of the three-dimensional atomizer according to the present invention;

FIG. 25 is an exploded view of the structure of FIG. 23;

FIG. 26 is an exploded view of the structure of FIG. 24;

fig. 27 is a structural exploded view of a three-dimensional atomizer according to the present invention.

Detailed Description

The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and those skilled in the art can obtain other embodiments without inventive effort based on the embodiments of the present invention, and all embodiments are within the protection scope of the present invention. In addition, all the connection/connection relations referred to in the patent do not mean that the components are directly connected, but mean that a better connection structure can be formed by adding or reducing connection auxiliary components according to specific implementation conditions. The technical features of the utility model can be combined interactively without conflicting with each other, see fig. 1-27

Example 1, with particular reference to fig. 1-5.

A three-dimensional atomization assembly comprises a porous liquid guiding body 11 with an atomization surface and a liquid inlet surface and a three-dimensional heating body 12 matched with the porous liquid guiding body 11 for use, wherein the three-dimensional heating body 12 is provided with a bending part and forms a heating body with a plurality of heating dimensions through the bending part.

Preferably, the three-dimensional heating element 12 comprises a first electrode 121, a second electrode 122 and at least two heating tracks 123 connected in parallel between the first electrode 121 and the second electrode 122, and the heating tracks 123 are bent and deformed and formed so that the three-dimensional heating element 12 has a plurality of heating dimensions; the first electrode 121 and the second electrode 122 of the three-dimensional heating body 12 have bent portions 124, and the first electrode 121 and the second electrode 122 can be welded to electrode leads 125; the porous liquid guiding body 11 is internally provided with at least one liquid inlet groove 111, and the porous liquid guiding body 11 is a porous ceramic body, a liquid guiding cotton, a non-woven fabric or a fiber liquid guiding body.

In this embodiment, the atomization surface of the porous liquid guiding body 11 is three surfaces with a rectangular cross section, and includes a bottom surface and two vertical side surfaces, the heating traces 123 of the three-dimensional heating body 12 are installed on the bottom surface and the two vertical side surfaces of the porous liquid guiding body 11, and the three-dimensional surface formed by the heating traces 123 is substantially parallel to the atomization surface of the porous liquid guiding body 11.

In this embodiment, the atomization surface of the porous liquid guide 11 is preferably a rectangular solution, which makes it relatively easier to control the angle of the heating trace 123, and has high product consistency.

Example 2, with particular reference to fig. 6-8.

The present embodiment is basically the same as embodiment 1 in structure, and is different in that:

the atomization surface of the porous liquid guiding body 11 is three surfaces with trapezoidal sections, and comprises a bottom surface and two slope surfaces, the heating tracks 123 of the three-dimensional heating body 12 are installed on the bottom surface and the two slope surfaces of the porous liquid guiding body 11, and the three-dimensional surface formed by the heating tracks 123 is approximately parallel to the atomization surface of the porous liquid guiding body 11.

The advantage of this embodiment lies in that the atomizing department of bending is the obtuse angle, and the department of bending is difficult to cause the high temperature because of long-pending heat.

Example 3, with particular reference to FIGS. 9-11.

The present embodiment is basically the same as embodiment 1 in structure, and is different in that:

the atomization surface of the porous liquid guiding body 11 is two surfaces with obtuse triangle sections, and comprises a first inclined surface and a second inclined surface, the heating track 123 of the three-dimensional heating body 12 is installed on the first inclined surface and the second inclined surface of the porous liquid guiding body 11, and the three-dimensional surface formed by the heating track 123 is approximately parallel to the atomization surface of the porous liquid guiding body 11.

The advantage of this embodiment is that the air current that gets into can be through the cutting apart of atomizing face for steam atomizing is blockked for a short time, and steam atomizing is more smooth and easy in airflow channel.

Example 4, with particular reference to FIGS. 12-14.

The present embodiment is basically the same as embodiment 1 in structure, and is different in that:

the section of the atomization surface of the porous liquid guiding body 11 is an arc surface, the heating track 123 of the three-dimensional heating body 12 is installed on the inclined surface of the porous liquid guiding body 11, and the three-dimensional surface formed by the heating track 123 is approximately parallel to the atomization surface of the porous liquid guiding body 11.

The steam atomizing device has the advantages that no bending angle exists, no heat accumulation is generated, the blocking of the arc surface to the atomized steam is small, and the atomized steam is smoother in the airflow channel.

In the above four embodiments, the assembly of the porous conductive liquid 11 with the three-dimensional heating body 12 has various embodiments.

Referring to fig. 15, in the first assembly embodiment of the porous conductive liquid 1 and the three-dimensional heating element 12, the porous conductive liquid 11 is a hard porous conductive liquid, the three-dimensional heating element 12 is embedded in the atomized surface of the porous conductive liquid 11, the first electrode 121 and the second electrode 122 of the three-dimensional heating element 12 have bent portions embedded in the porous conductive liquid 11, and the heating trace 123 of the three-dimensional heating element 12 has one surface exposed outside the atomized surface of the porous conductive liquid 11.

Specifically, when the porous liquid guiding body 11 is a hard porous body, the heating trace 123 is embedded in the outer surface of the porous liquid guiding body 11, one surface of the heating trace 12 is exposed in the air, and the rest surface is embedded in the porous liquid guiding body 11; the bending parts on the electrodes on the three-dimensional heating body 12 are all embedded in the porous liquid, so that the three-dimensional heating body is prevented from falling off from the porous liquid under stress; the hard porous liquid guiding body 11 is generally made of porous materials with liquid guiding capacity, such as porous ceramics, porous quartz glass, porous fibers and the like; the three-dimensional heating element 12 is formed by cutting, punching, etching and other processes of a metal and/or alloy material to form a heating circuit, and then the three-dimensional heating element 12 with the multi-surface characteristic is formed by bending.

Referring to fig. 16, in the second assembly embodiment of the porous conductive liquid 1 and the three-dimensional heating body 12, the porous conductive liquid 11 is a hard porous conductive liquid, the three-dimensional heating body 12 is embedded in the porous conductive liquid 11, the ends of the first electrode 121 and the second electrode 122 of the three-dimensional heating body 12 are exposed outside the porous conductive liquid 11, and all the surfaces of the heating trace 123 of the three-dimensional heating body 12 are embedded inside the porous conductive liquid 11, in this embodiment, the porous conductive liquid 11 is a hard porous body, the heating trace 123 is completely embedded in the porous conductive liquid 11, and the electrode leaks out of the outer surface of the porous conductive liquid 11 near the atomizing surface end of the porous conductive liquid 11.

In this embodiment, there is an advantage in that the contact between the heating trace 123 of the three-dimensional heating body 12 and the porous conductive liquid 1 is better, and after the three-dimensional heating body 12 is heated by electricity, the heat is conducted to the surface of the porous conductive liquid 11, so as to atomize the liquid in the porous conductive liquid 11 on the outer surface; furthermore, since the heating trace 123 is embedded in the porous liquid-conducting body 11, the heating trace 123 and the porous liquid-conducting body 11 are in good contact with each other and are not easily loosened.

Referring to fig. 17, in the third embodiment of assembling the porous liquid guide 1 and the three-dimensional heating body 12, the porous liquid guide 11 is a soft porous liquid guide, and the three-dimensional heating body 12 is attached to the outer surface of the atomization surface of the porous liquid guide 11, specifically, when the porous liquid guide 11 is a soft porous body, such as a liquid guide cotton, a non-woven fabric, or a fiber-based liquid guide material, the heating trace 123 is attached to the outer surface of the porous liquid guide 11.

Specifically, the porous liquid-conducting body 11 has the following preferred embodiments:

example 1 of porous liquid conducting 11:

the porous liquid guiding body 11 is made of porous ceramic, the porosity is 50-60%, the diameter of each micropore is 15-25 microns, the height of the ceramic is 3-5mm, and when the kinematic viscosity of atomized liquid is high, the distance from the liquid inlet on the upper surface to the atomization surface is long, so that more than one liquid inlet groove 111 can be formed in the porous liquid guiding body 11, the liquid can reach the atomization surface more quickly, and the liquid supply is sufficient.

Example 2 of porous liquid conducting 11:

the porous liquid guiding 11 is made of porous ceramic, the porosity is 50-60%, the diameter of each micropore is 15-25um, and the height of the ceramic is 3-5mm, when the kinematic viscosity of the atomized liquid is low, a large liquid inlet groove 111 is directly opened due to the large diameter of each micropore, so that the risk of liquid leakage from the porous ceramic exists, and therefore, a scheme of dividing one liquid inlet groove 111 into a plurality of small liquid inlet grooves 111 (liquid inlet holes) can be adopted, the liquid inlet speed is reduced, and the effect of balancing the liquid inlet amount and the atomization amount is achieved.

Example 3 of porous liquid conducting 11:

the porous liquid guiding body 11 is made of porous ceramic, the porosity is 50-60%, the diameter of each micropore is 8-18um, the height of the ceramic is 2-3mm, and when the kinematic viscosity of the atomized liquid is low, the diameter of each micropore is small, and the distance between a liquid inlet surface and an atomization surface is short, so that a liquid inlet groove hole 111 does not need to be formed in the porous liquid guiding body 11, and the effect of balance of liquid supply and atomization can be achieved.

Referring to fig. 18 to 21, in the above examples and embodiments, the heating traces 123 on the three-dimensional heating body 12 between the first electrode 121 and the second electrode 122 are rhombic or rectangular or wavy or S-shaped extending distribution; referring to fig. 5 and 22, the heating trace 123 on the three-dimensional heating body 12 has two or more, and two adjacent heating traces 12 are connected to each other.

Referring to fig. 23-27, based on the three-dimensional atomizing assembly, the utility model also provides a three-dimensional atomizer, which comprises the three-dimensional atomizing assembly 1.

Preferably, still include base 2, go up fixing base 3 and stock solution storehouse 4, three-dimensional atomization component 1 is installed on base 2, it installs on 1 upper portion of three-dimensional atomization component and is used for fixing three-dimensional atomization component 1 on base 2 to go up fixing base 3, stock solution storehouse 4 is used for storing the tobacco juice and fixes on base 2, the liquid outlet of stock solution storehouse 4 and porous inlet surface intercommunication of leading liquid 11, inlet port 21 just has on base 2 inlet port 21 and porous atomizing surface intercommunication of leading liquid 11, stock solution storehouse 4 has outlet flue 41 just outlet flue 41 with porous atomizing surface of leading liquid 11 and the inlet port 21 intercommunication of base 2.

Preferably, the base 1 is further provided with two electrode thimble 5, the two electrode thimble 5 are respectively in electrical contact with two ends of the three-dimensional heating body 12, and the electrode thimble 5 has an end surface exposed at the bottom of the base 2.

Preferably, base 2 lateral part has a step position 22, the lower edge of stock solution storehouse 4 is fixed step position 22 department is provided with silica gel sealing ring 63 between stock solution storehouse 4 inner wall and the base 2 outer wall.

Preferably, a first sealing silica gel sleeve 61 is arranged between the porous liquid guide 11 and the inner wall of the upper fixing seat 3, and a second sealing silica gel sleeve 62 is arranged between the outer wall of the upper fixing seat 3 and the inner wall of the liquid storage bin 4.

Preferably, the liquid storage bin 4 has two liquid storage inner cavities 40, the upper fixing base 3 has two liquid guide holes 31, and the two liquid storage inner cavities 40 are respectively communicated to the liquid inlet surface of the porous liquid guide body 11 through the two liquid guide holes 31 on the upper fixing base 3.

Preferably, base 2 is inside to have atomizing inner chamber 20, the atomizing face and the three-dimensional heating body 12 of porous liquid 11 of leading all are located in atomizing inner chamber 20, be provided with fixing base smoke hole 32 on the fixing base 3 of upper portion, 3 lateral parts of fixing base have lateral part breach 33, lateral part breach 33 will atomize inner chamber 20 and fixing base smoke hole 32 intercommunication, the outlet flue 41 of stock solution storehouse 4 with fixing base smoke hole 32 intercommunication.

In the atomizer, the porous atomization component 1 that leads liquid 11 and three-dimensional heat-generating body 12 constitution, wrap up sealed with first sealing silica gel cover 61, install in last fixing base 3, it can become integrative through the screens connection to go up fixing base 3 after the equipment, the silica gel circle is installed in the silica gel circle mounting groove of base 2, electrode thimble 5 is installed in the electrode mounting hole site of base 2, one end spills from the bottom face of base 2, the electrode contact of one end and three-dimensional heat-generating body 12, after base and fixing base have been installed, install on fixing base 3 with second sealing silica gel cover 62, the liquid that need be atomized is packed into in the stock solution storehouse 4, pack the atomization module 1 who installs into in the stock solution storehouse 4 again, the air flow channel at stock solution storehouse 4 center aligns with the mounting hole of last fixing base, the centre adopts sealing silica gel to seal. The criminal becomes an atomizing unit.

When the liquid storage device works, liquid in the liquid storage bin 4 is absorbed by the porous ceramic body 11, after the porous ceramic body 11 absorbs the liquid, as the liquid in the liquid storage bin 4 is reduced, the air pressure is lower than the atmospheric pressure, and the outside gas enters the liquid storage bin, as the liquid storage bin 4 is completely sealed, the only channel is the micropore in the porous ceramic body 11, and the micropore is full of the liquid, the outside atmospheric pressure gives the upward pressure to the liquid and balances the downward gravity of the liquid, so that the liquid cannot continuously permeate downwards to cause liquid leakage. When there is suction in the end of giving vent to anger of stock solution storehouse 4, atomizing unit begins work, and the outside air gets into by the base air inlet, and the atomizing steam of three-dimensional heat-generating body 12 atomizing is carried by the outside cold air, forms gas-liquid mixture, emits by stock solution storehouse 4 gas outlets.

While the preferred embodiments of the present invention have been illustrated and described, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims (19)

1. A three-dimensional atomizing assembly, characterized by: the heating device comprises a porous liquid guide body (11) with an atomizing surface and a liquid inlet surface and a three-dimensional heating body (12) matched with the porous liquid guide body (11) for use, wherein the three-dimensional heating body (12) is provided with a bending part and forms a heating body with a plurality of heating dimensions through the bending part.

2. The three-dimensional atomizing assembly of claim 1, wherein: the three-dimensional heating body (12) comprises a first electrode (121), a second electrode (122) and at least two heating tracks (123) connected between the first electrode (121) and the second electrode (122) in parallel, wherein the heating tracks (123) are bent and deformed to form a plurality of heating dimensions of the three-dimensional heating body (12).

3. The three-dimensional atomizing assembly of claim 2, wherein: the porous liquid guide (11) is hard porous liquid guide, the three-dimensional heating element (12) is embedded in the atomization surface of the porous liquid guide (11), the first electrode (121) and the second electrode (122) of the three-dimensional heating element (12) are provided with bent parts and the bent parts are embedded in the porous liquid guide (11), and the heating track (123) of the three-dimensional heating element (12) is provided with a surface exposed outside the atomization surface of the porous liquid guide (11).

4. The three-dimensional atomizing assembly of claim 3, wherein: the porous liquid guide body (11) is hard porous liquid guide body, the three-dimensional heating body (12) is embedded in the porous liquid guide body (11), the end parts of the first electrode (121) and the second electrode (122) of the three-dimensional heating body (12) are exposed outside the porous liquid guide body (11), and all the surfaces of the heating track (123) of the three-dimensional heating body (12) are embedded inside the porous liquid guide body (11).

5. The three-dimensional atomizing assembly of claim 2, wherein: the porous liquid guide body (11) is soft porous liquid guide body, and the three-dimensional heating body (12) is attached to the outer surface of the atomization surface of the porous liquid guide body (11).

6. The three-dimensional atomizing assembly of claim 2, wherein: the atomizing surface of the porous liquid guide body (11) is three surfaces with rectangular sections and comprises a bottom surface and two vertical side surfaces, the heating tracks (123) of the three-dimensional heating body (12) are arranged on the bottom surface and the two vertical side surfaces of the porous liquid guide body (11), and the three-dimensional surface formed by the heating tracks (123) is approximately parallel to the atomizing surface of the porous liquid guide body (11).

7. The three-dimensional atomizing assembly of claim 2, wherein: the atomizing surface of the porous liquid guide body (11) is three surfaces with trapezoidal sections, and comprises a bottom surface and two slope surfaces, the heating track (123) of the three-dimensional heating body (12) is installed on the bottom surface and the two slope surfaces of the porous liquid guide body (11), and the three-dimensional surface formed by the heating track (123) is approximately parallel to the atomizing surface of the porous liquid guide body (11).

8. The three-dimensional atomizing assembly of claim 2, wherein: the atomization surface of the porous liquid guide body (11) is two surfaces with obtuse triangular sections, and comprises a first inclined surface and a second inclined surface, the heating track (123) of the three-dimensional heating body (12) is installed on the first inclined surface and the second inclined surface of the porous liquid guide body (11), and the three-dimensional surface formed by the heating track (123) is approximately parallel to the atomization surface of the porous liquid guide body (11).

9. The three-dimensional atomizing assembly of claim 2, wherein: the atomization surface of the porous liquid guide body (11) is an arc surface with an arc-shaped section, the heating track (123) of the three-dimensional heating body (12) is arranged on the inclined surface of the porous liquid guide body (11), and the three-dimensional surface formed by the heating track (123) is approximately parallel to the atomization surface of the porous liquid guide body (11).

10. The three-dimensional atomizing assembly of claim 2, wherein: the heating tracks (123) on the three-dimensional heating body (12) between the first electrode (121) and the second electrode (122) are in rhombus shape or rectangular shape or wave shape or S-shaped extending distribution, two or more heating tracks (123) on the three-dimensional heating body (12) are provided, and two adjacent heating tracks (123) are connected with each other.

11. The three-dimensional atomizing assembly of claim 2, wherein: the first electrode (121) and the second electrode (122) of the three-dimensional heating body (12) are provided with bending parts (124), and the first electrode (121) and the second electrode (122) can be welded with electrode leads (125).

12. The three-dimensional atomizing assembly of claim 1, wherein: the porous liquid guide body (11) is internally provided with at least one liquid inlet groove (111), and the porous liquid guide body (11) is a porous ceramic body, a liquid guide cotton, a non-woven fabric or a fiber liquid guide body.

13. A three-dimensional atomiser comprising a three-dimensional atomising assembly (1) according to any of the claims 1 to 12.

14. The three-dimensional atomizer according to claim 13, wherein: still include base (2), go up fixing base (3) and stock solution storehouse (4), three-dimensional atomizing subassembly (1) is installed on base (2), it installs on three-dimensional atomizing subassembly (1) upper portion and is used for fixing three-dimensional atomizing subassembly (1) on base (2) to go up fixing base (3), stock solution storehouse (4) are used for storing the tobacco juice and fix on base (2), the liquid outlet of stock solution storehouse (4) and the inlet liquid face intercommunication of porous conducting liquid (11), inlet port (21) just have on base (2) inlet port (21) and the atomizing face intercommunication of porous conducting liquid (11), stock solution storehouse (4) have outlet flue hole (41) just outlet flue hole (41) with the atomizing face of porous conducting liquid (11) and inlet port (21) intercommunication of base (2).

15. The three-dimensional atomizer according to claim 14, wherein: the base (1) is further provided with two electrode thimbles (5), the two electrode thimbles (5) are respectively in electrical contact with two ends of the three-dimensional heating body (12), and the electrode thimbles (5) are provided with one end face exposed at the bottom of the base (2).

16. The three-dimensional atomizer according to claim 14, wherein: base (2) lateral part has one step (22), along fixing under stock solution storehouse (4) step (22) department is provided with silica gel sealing washer (63) between stock solution storehouse (4) inner wall and base (2) outer wall.

17. The three-dimensional atomizer according to claim 14, wherein: a first sealing silica gel sleeve (61) is arranged between the porous liquid guide body (11) and the inner wall of the upper fixing seat (3), and a second sealing silica gel sleeve (62) is arranged between the outer wall of the upper fixing seat (3) and the inner wall of the liquid storage bin (4).

18. The three-dimensional atomizer according to claim 14, wherein: stock solution storehouse (4) have two stock solution inner chambers (40), upper portion fixing base (3) have two drain holes (31), and two stock solution inner chambers (40) communicate the inlet surface of porous leading liquid (11) through two drain holes (31) on upper portion fixing base (3) respectively.

19. The three-dimensional atomizer according to claim 14, wherein: base (2) inside atomizing inner chamber (20) have, the atomizing face and the three-dimensional heating body (12) of liquid (11) are led to the porous all are located in atomizing inner chamber (20), be provided with fixing base cigarette hole (32) on upper portion fixing base (3), upper portion fixing base (3) lateral part has lateral part breach (33), lateral part breach (33) will atomize inner chamber (20) and fixing base cigarette hole (32) intercommunication, the outlet flue (41) of stock solution storehouse (4) with fixing base cigarette hole (32) intercommunication.

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