CN215455393U

CN215455393U - Atomization assembly capable of condensing and recycling and atomization device thereof

Info

Publication number: CN215455393U
Application number: CN202121459492.2U
Authority: CN
Inventors: 陈平
Original assignee: Shenzhen Huachengda Precision Industry Co Ltd
Current assignee: Shenzhen Huachengda Precision Industry Co Ltd
Priority date: 2021-06-29
Filing date: 2021-06-29
Publication date: 2022-01-11
Anticipated expiration: 2031-06-29
Also published as: WO2023273509A1

Abstract

The invention discloses a condensable recycling atomization assembly and an atomization device thereof, wherein the atomization assembly comprises a liquid guide part and a heating part matched on the liquid guide part, a backflow condensation part which can be arranged in an air flow channel and used for recycling condensate and guiding the condensate to the liquid guide part is arranged on the side surface of the liquid guide part, an air guide channel communicated with the air flow channel is arranged between the backflow condensation part and the liquid guide part, and/or an air guide channel communicated with the air flow channel is arranged on the backflow condensation part; the atomization device comprises a shell, and an atomization mechanism and an air regulation control mechanism which are arranged in the shell, wherein the atomization mechanism comprises an atomization assembly, an air guide pipe and an oil storage assembly which are communicated with the atomization assembly. According to the invention, the backflow condensing part is arranged, so that the condensate formed in the airflow channel can be absorbed by the backflow condensing part and atomized again for use, the waste of smoke liquid is avoided, the condensate is prevented from flowing to the electronic part to cause the damage of the atomizing device, the condensate is also prevented from being sucked into the suction port of a user, and the smoking experience of the user is improved.

Description

Atomization assembly capable of condensing and recycling and atomization device thereof

Technical Field

The invention relates to the technical field of atomization, in particular to an atomization assembly capable of condensing and recycling and an atomization device thereof.

Background

Electronic cigarette atomizer on the existing market forms smog with the tobacco juice through heating atomizing and supplies the user to use, however, forms high temperature atomizing steam among the heating atomizing process, high temperature atomizing steam contacts with the air flue inner wall when flowing in the cigarette bullet airflow channel, because the atomizing steam of high temperature meets the liquid that the inner wall of normal atmospheric temperature will produce the condensation, can have following problem when converging when the inside condensate liquid of cigarette bullet is more and more together: the collected condensate cannot flow back to the atomization assembly, so that the condensate cannot be atomized and utilized again, and the waste of the tobacco liquid is caused; the collected condensate can flow to the electronic parts along the atomizing device, so that the risk of damage to the whole atomizing device exists; or part of the smoke liquid or condensate is entrained in the smoke and sucked by the user, which seriously influences the use of the user.

Disclosure of Invention

The invention aims to solve the technical problem of providing an atomizing assembly and an atomizing device which can recover condensate in a gas channel and atomize and utilize the condensate again aiming at the defects of the prior art.

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

the utility model provides an atomizing component that condensable was retrieved, includes drain, the cooperation heating member on the drain, the drain side is equipped with the backward flow condensation piece that can arrange in airflow channel and retrieve the condensate and lead the drain in, be equipped with the air guide channel with airflow channel UNICOM between backward flow condensation piece and the drain, and/or be equipped with the air guide channel with airflow channel UNICOM on the backward flow condensation piece.

Further, in the condensation recovery atomization assembly, it is preferable that the reflux condensation member extends outward from at least one of a bottom portion, a middle portion, or a top portion of a side surface of the liquid guide member.

Furthermore, in the atomization assembly capable of condensing and recycling, the reflux condensing part and the liquid guide part are preferably of an integrally formed integral structure; or the reflux condensing part is fixedly connected with the liquid guide part; or the side wall of the liquid guide piece is provided with an embedding port, and the liquid guide piece is embedded and connected in the embedding port to be fixed.

Further, in the atomization assembly capable of condensing and recovering, the reflux condensation member is preferably provided with a reflux hole penetrating through the airflow channel.

Further, in the atomization assembly capable of condensing and recycling, preferably, the reflux hole is formed in the middle of the reflux condensation member, or the reflux hole is formed in the reflux condensation member at intervals, or the reflux condensation member is in a porous through structure.

Further, in the atomization assembly capable of condensing and recovering, preferably, the recovery condensing part is provided with a slope structure capable of guiding the condensate to the liquid guide part.

Further, in the atomization assembly capable of condensing and recycling, at least one surface of the reflux condensation member is preferably in a rugged rough structure.

Further, in the atomization assembly capable of condensing and recycling, the reflux condensing part is preferably provided with a groove for guiding the condensate to the liquid guide part.

The utility model provides an atomizing device that condensable was retrieved, includes the casing, sets up atomizing mechanism, the control mechanism that adjusts the gas in the casing, atomizing mechanism include atomizing component, with atomizing component UNICOM's air duct, oil storage component.

Further, in the atomization device capable of condensing and recycling, preferably, an airflow channel through which gas flows is reserved between the atomization assembly and the housing, and the liquid guide member of the atomization assembly extends the reflux condensation member into the airflow channel.

Furthermore, in the atomization device capable of condensing and recycling, preferably, a reflux condensation piece of the atomization assembly abuts against the shell, no gap exists between the reflux condensation piece and the shell, and an air guide channel communicated with the airflow channel is formed in the reflux condensation piece.

Further, in the atomization device capable of condensing and recycling, preferably, the reflux condensing part of the atomization assembly abuts against the shell, and an air guide channel communicated with the air flow channel is reserved between the reflux condensing part and the shell.

Further, in the atomization device capable of condensing and recycling, preferably, the reflux condensing part of the atomization assembly is not in contact with the shell, and an air guide channel communicated with the air flow channel is reserved between the reflux condensing part of the atomization assembly and the shell.

The invention has the following beneficial effects: according to the atomizing assembly and the atomizing device thereof, the backflow condensing part which can be arranged in the airflow channel and can recycle and guide the condensate to the liquid guide part is arranged, so that the condensate formed in the airflow channel can be absorbed by the backflow condensing part and atomized again for use, the waste of smoke liquid is avoided, the condensate is prevented from flowing to the electronic part to cause the damage of the atomizing device, the condensate is prevented from being sucked by a user, and the smoking experience of the user is improved.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a bottom view of embodiment 1-1 of the present invention;

FIG. 2 is a schematic structural view of example 1-1 of the present invention;

FIG. 3 is a bottom view of examples 1-2 of the present invention;

FIG. 4 is a schematic structural view of examples 1 to 2 of the present invention;

FIG. 5 is a bottom view of examples 1 to 3 of the present invention;

FIG. 6 is a schematic structural view of examples 1 to 3 of the present invention;

FIG. 7 is a bottom view of examples 1-4 of the present invention;

FIG. 8 is a schematic structural view of examples 1 to 4 of the present invention;

FIG. 9 is a bottom view of examples 1 to 5 of the present invention;

FIG. 10 is a schematic structural view of examples 1 to 5 of the present invention;

FIG. 11 is a bottom view of examples 1-6 of the present invention;

FIG. 12 is a schematic structural view of examples 1 to 6 of the present invention;

FIG. 13 is a bottom view of examples 1-7 of the present invention;

FIG. 14 is a schematic structural view of examples 1 to 7 of the present invention;

FIG. 15 is a bottom view of examples 1-8 of the present invention;

FIG. 16 is a schematic structural view of examples 1 to 8 of the present invention;

FIG. 17 is a bottom view of examples 1-9 of the present invention;

FIG. 18 is a schematic structural view of examples 1 to 9 of the present invention;

FIG. 19 is a schematic structural view of example 2-1 of the present invention;

FIG. 20 is a schematic structural view of example 2-2 of the present invention;

FIG. 21 is a sectional view of embodiment 2-2 of the present invention.

Detailed Description

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

An element is said to be "secured to" or "disposed on" another element, either directly or indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element.

The terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positions based on the orientations or positions shown in the drawings, and are for convenience of description only and not to be construed as limiting the technical solution. The terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "plurality" is two or more unless specifically limited otherwise.

Embodiment 1, as shown in fig. 1 to 14, a condensable recycling atomizing assembly includes a liquid guiding member 31, and a heating member 32 fitted to the liquid guiding member 31, and a backflow condensing member 33 disposed at a side of the liquid guiding member 31 and adapted to be disposed in an air flow path and to recycle and guide condensed liquid to the liquid guiding member 31, wherein, in order to ensure that the air flow path is unblocked, an air guide path communicating with the air flow path is disposed between the backflow condensing member 33 and the liquid guiding member 31, or an air guide path communicating with the air flow path is disposed on the backflow condensing member 33, although the air guide paths in both cases may exist at the same time. The during operation, heating member 32 provides the tobacco juice atomizing formation mist steam in making drain 31, high temperature mist steam contacts with the air flue inner wall when flowing in cigarette bullet air current passageway, because the mist steam of high temperature meets the liquid that the inner wall of normal atmospheric temperature will produce the condensation, the backward flow condensing part 33 that air flue passageway department was placed in to the condensate this moment absorbs and leads drain 31, again in drain 31 by heating member 32 heating atomizing, wherein, the heating member can be for the piece that generates heat, contact with drain 31 bottom. The reflux condensation member 33 is disposed in the airflow channel, the reflux condensation member 33 can absorb condensate or other liquid, wherein the reflux condensation member 33 is directly connected to the liquid guide member 31 to guide the condensate to the liquid guide member 31 for recycling the smoke liquid, and of course, the reflux condensation member 33 can also be connected to the liquid guide member 31 through other components having a liquid guide function to recycle the smoke liquid. The liquid guiding member 31 is a porous liquid guiding structure, in other words, the liquid guiding member 31 is made of a porous material, the plurality of pores of the liquid guiding member 31 perform a liquid guiding function, and the porous liquid guiding member is preferably a porous ceramic body. Wherein the reflux condenser 33 is made of a liquid guiding material, and can absorb the condensate or other liquid and guide the condensate to the liquid guiding member 31.

The side surface of the liquid guide member 31 can be divided into three parts: the reflux condenser 33 can extend outwards from the bottom of the side surface of the liquid guide 31, can extend outwards from the middle of the top surface of the liquid guide 31, certainly, can extend outwards from the bottom and the middle of the liquid guide at the same time, or can extend outwards from the top and the middle of the liquid guide at the same time, or extend outwards from the bottom and the top of the liquid guide at the same time, certainly, can extend outwards from the bottom, the middle and the top of the liquid guide at the same time, and the reflux condenser 33 and the liquid guide 31 can be of an integrally formed integral structure; or the reflux condenser 33 and the liquid guide member 31 are fixedly connected together in a separate structure.

The liquid guide part 31 is a porous structure made of porous liquid guide materials, the reflux condensation part 33 is made of liquid guide materials, and the liquid guide part 31 and the reflux condensation part 33 can be made of the same or different materials as long as the liquid guide part can absorb condensate and has the liquid guide function; the reflux condensation piece 33 and the liquid guide piece 31 can be of an integrally formed integral structure, so that multiple modeling is not needed in production, and an assembly step is omitted; or the reflux condensation piece 33 and the liquid guide piece 31 are fixedly connected together in a separate structure; or the side wall of the liquid guide piece 31 is provided with an embedding port, and the liquid guide piece 31 is embedded and fixed in the embedding port; the size and shape of the liquid guiding member 31 and the reflux condenser 33 are not limited.

The backflow condensing element 33 is provided with a backflow hole 331 penetrating through the airflow channel, and the backflow hole 331 can be used for increasing the contact area with the airflow channel on one hand and can be used as an air guide channel formed in the backflow condensing element 33 on the other hand, so that smoke can form an air circulation loop through the backflow hole 331, and condensate recycling with better condensate flowability is increased. The reflux holes 331 are formed in the middle of the reflux condensation member 33, or the reflux holes 331 are formed in the reflux condensation member 33 at intervals, or the reflux condensation member 33 is of a porous through structure and can be transverse holes, longitudinal holes or staggered holes, and the shape, the pore size and the number of the holes are not limited.

The reflux condenser 33 may be provided with a slope structure for guiding the condensate to the liquid guide 31; specifically, the upper surface of the reflux condensation member 33 is designed to be an inclined surface structure, which is beneficial to the condensate formed at the top of the reflux condensation member 33 to flow down along the inclined surface, and the lower position of the inclined surface is just the liquid guiding member 31, so that the condensate is accelerated to flow back to the liquid guiding member 31 and is heated and atomized by the heating member 32. At least one surface of the reflux condensation member 33 is of an uneven rough surface structure, and the contact surface area of the condensate and the reflux condensation member 33 can be increased by increasing the roughness of the surface, so that the condensate mixed in the smoke can be adsorbed to a greater extent. The reflux condensation member 33 is provided with a groove for guiding the liquid guide member 31, the groove can be designed as an annular groove, the groove is designed for guiding the liquid guide member 31 along the side wall of the reflux condensation member 33, and one or more grooves can be designed, and the number is not limited; the preferred grooves are arranged at the lower part of the reflux condenser 33, because the condensed liquid is heavier after being gathered and flows downwards along the side wall, and the grooves arranged at the lower part can better collect and guide the condensed liquid to the liquid guide member 31; preferably, the upper surface of the reflux condenser 33 is a slope, and a groove for guiding the liquid guiding member 31 is formed on the slope, and the condensate flows back to the liquid guiding member 31 along the groove on the slope and is heated and atomized again by the heating member 32.

To further illustrate the present invention, the following detailed description will be given by way of example only:

embodiment 1-1, as shown in fig. 1-2, a condensable recycling atomization assembly, including a liquid guiding member 31, a heating member 32 fitted on the liquid guiding member 31, a backflow condensing member 33 disposed on a side of the liquid guiding member 31 and capable of being disposed in an air flow channel and recycling condensed liquid and guiding the condensed liquid to the liquid guiding member 31, the backflow condensing member 33 being in a square shape and having two parts respectively connected to bottoms of two sides of the liquid guiding member 31, the liquid guiding member 31 and the backflow condensing member 33 being integrated, the backflow condensing member 33 being a part of a body of the liquid guiding member 31, modeling is more convenient during production, recycling the insufficiently atomized condensed liquid again, and improving utilization rate of smoke liquid.

Examples 1-2, as shown in FIGS. 3-4, a condensable recovery atomizing assembly of this example was modified on the basis of example 1-1. The specific improvement is that the reflux condensing part 33 is provided with a reflux hole 331 penetrating through the airflow channel, the reflux hole 331 is arranged in the middle of the reflux condensing part 33 and provided with one, so that smoke can pass through the reflux hole 331 to form an air circulation loop, and the condensate can be better recycled due to the flowing of the condensate.

Examples 1-3, as shown in FIGS. 5-6, a condensable recovery atomizing assembly of this example was modified based on examples 1-2. The specific improvement is that the reflux condensation piece 33 is an irregular block, the upper surface of the reflux condensation piece 33 is of an inclined surface structure, the side surface of the reflux condensation piece is also of an inclined surface structure, the lower position of the inclined surface of the upper surface is connected with the side surface of the liquid guide piece 31, the upper surface of the reflux condensation piece 33 is designed to be of an inclined surface structure, the condensate formed at the top of the reflux condensation piece 33 can flow downwards along the inclined surface, the lower position of the inclined surface is just the liquid guide piece 31, and the accelerated condensate flows back to the liquid guide piece 31 and is heated and atomized by the heating piece 32.

Examples 1-4, as shown in FIGS. 7-8, a condensable recovery atomizing assembly of this example was modified based on example 1-1. The specific improvement is that the reflux condensation piece 33 and the liquid guide piece 31 are of independent structures and are fixedly connected together in a connection mode of insertion, scarf joint and the like, so that the reflux condensation piece 33 and the liquid guide piece 31 are respectively molded independently, and the materials can be selected to be the same or different. Specifically, two reflux condenser pieces 33 are respectively inserted into both side surfaces of the liquid guiding member 31, and the liquid guiding member 31 is brought into contact with the single reflux condenser piece 33 during assembly, thereby recycling the condensate. The combination of the back-embedded reflux condensing part 33 and the liquid guiding part 31 can lead the assembly of the atomization components to be more compact, and simultaneously, more material choices are provided.

Examples 1-5, a condensable recovery atomizing assembly of this example is an improvement over examples 1-4 as shown in fig. 9-10. The specific improvement is that the reflux condensing part 33 is provided with a plurality of reflux holes 331 which penetrate through the airflow channel, and the reflux holes 331 are arranged on the reflux condensing part 33 at intervals, so that smoke can form an air circulation loop through the reflux holes 331, and the condensate can be better recycled due to the flowing of the condensate.

Examples 1-6, as shown in FIGS. 11-12, a condensable recovery atomizing assembly of this example is an improvement over examples 1-4. The specific improvement is that the reflux condensation piece 33 is an irregular block, the upper surface of the reflux condensation piece 33 is of an inclined surface structure, the side surface of the reflux condensation piece is also of an inclined surface structure, the lower position of the inclined surface of the upper surface is connected with the side surface of the liquid guide piece 31, the upper surface of the reflux condensation piece 33 is designed to be of an inclined surface structure, the condensate formed at the top of the reflux condensation piece 33 can flow downwards along the inclined surface, the lower position of the inclined surface is just the liquid guide piece 31, and the accelerated condensate flows back to the liquid guide piece 31 and is heated and atomized by the heating piece 32.

Examples 1-7, a condensable recovery atomizing assembly of this example was modified based on examples 1-4 as shown in fig. 13-14. The specific improvement is that the backflow condensing part 33 is a porous through structure, can be a porous net structure, and can be a porous structure similar to a honeycomb, and the criss-cross design of the backflow holes 331 enables smoke to form an air circulation loop through the backflow holes 331 which are communicated with each other in all directions, so that the fluidity of the smoke is increased, the fluidity of the condensate is improved, and the smoke can directly flow back to the liquid guide part 31 through the transverse holes to better recycle the condensate.

Examples 1-8, as shown in FIGS. 15-16, a condensable recovery atomizing assembly of this example was modified based on example 1-1. The specific improvement is that the middle part of the reflux condensation piece 33 is removed, namely the original two reflux condensation pieces 33 are changed into four reflux condensation pieces 33, the middle part of the reflux condensation piece 33 is removed to form an air guide channel, and the condensation reflux piece 33 is arranged on the side surface of the air guide channel, so that consumable materials are reduced, the cost is saved, the air passage can be enabled to pass through more smoothly, and the condensate flowing along the side wall can be recycled better.

Examples 1-9, a condensable recovery atomizing assembly of this example is an improvement over examples 1-8 as shown in fig. 17-18. The specific improvement is that the four reflux condensation pieces 33 and the liquid guide piece 31 are of independent structures and are fixedly connected together in a connection mode of insertion, scarf joint and the like, so that the reflux condensation pieces 33 and the liquid guide piece 31 are respectively molded independently, and the materials can be selected to be the same or different.

Embodiment 2, as shown in fig. 19 to 21, an atomization device capable of condensing and recycling includes a housing 10, an atomization mechanism and an air regulation control mechanism disposed in the housing, an atomization assembly 3 of the atomization mechanism, an air duct 301 communicated with the atomization assembly, and an oil storage assembly 302. The atomization mechanism is used for heating and atomizing the tobacco juice to form smoke, and the air regulation control mechanism is used for regulating the air input of the atomization device; when the atomization device is used, the air regulation control mechanism controls air to enter an inner cavity of the atomization device from the shell 10, liquid in the oil storage component 302 enters the atomization component 3, the liquid is guided to the position of the heating component 32 at the bottom through the liquid guide component 31, the heating component 32 starts to heat after the atomization device is electrified, the liquid on the heating component 32 is gasified into atomized steam at high temperature, the atomized steam flows through the air flow channel, incompletely atomized smoke liquid and condensate formed by cold contact are recovered by the backflow condensation component 33 to be heated and atomized again, the completely atomized steam enters the air guide pipe 301, and finally the user inhales the smoke.

When the atomization device is normally used, the whole airflow channel needs to be ensured to be smooth, otherwise, the normal use of the atomization device is influenced, and even equipment is damaged; therefore, a gas flow channel for gas circulation can be reserved between the atomizing assembly 3 and the housing 10, and the liquid guide member 31 of the atomizing assembly 3 extends the reflux condensation member 33 into the gas flow channel; or the reflux condenser 33 of the atomization component 3 is abutted against the shell 10 without a gap between the two, and the reflux condenser 33 is provided with an air guide channel communicated with the airflow channel; or the reflux condenser 33 of the atomizing assembly 3 is partially abutted against the housing 10, and an air guide channel communicated with the air flow channel is reserved between the reflux condenser and the housing. Or the reflux condenser 33 of the atomizing assembly 3 is not contacted with the shell 10, and an air guide channel communicated with the air flow channel is reserved between the reflux condenser and the shell 10.

embodiment 2-1, as shown in fig. 19, an atomizing device capable of condensing and recycling includes a housing 10, an atomizing mechanism and an air regulation control mechanism (not shown) disposed in the housing 10, wherein the atomizing mechanism includes an atomizing assembly 3, an air duct 301 communicated with the atomizing assembly, and an oil storage assembly 302. The atomizing assembly 3 is as in example 1-1, and is not described herein; and a silica gel cover 4 is arranged below the oil storage assembly 302 to play a role in sealing and prevent liquid leakage. The atomization component 3 is fixed in the shell 10 by a top support 5 and a bottom support 6, and a silica gel sleeve 7 can be sleeved on the liquid guide piece 31 to play a role of liquid leakage, and the bottom support is provided with an electrode column 8 for providing electric energy for the heating piece 32; this liquid recycle atomizing device is when using, and the air is got into by bottom support 6, reaches heating member 32 bottom through the gas department, and the liquid in the oil storage subassembly 302 is through leading liquid 31 and reaching the heating member 32 position of bottom, and electrode column 8 circular telegram back heating member 32 begins to heat, and liquid gasification on the high temperature will heating member becomes atomizing steam, and atomizing air current is through atomizing subassembly 3, top support 5, silica gel lid 4 in the casing 10, and the air duct 301 that finally passes through on the oil storage subassembly 302 flows out.

Embodiment 2-2, as shown in fig. 20-21, an atomization device capable of condensing and recycling includes a housing 10, an atomization mechanism and an air regulation control mechanism disposed in the housing 10, where the atomization mechanism includes an atomization assembly 3, an air duct 301 communicated with the atomization assembly, and an oil storage assembly 302. The atomizing assembly is as in examples 1-4 and will not be described herein.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications, combinations and variations may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims

1. The utility model provides an atomizing subassembly that condensable was retrieved, includes drain, the cooperation adds the heat-insulating material on the drain, its characterized in that, the drain side is equipped with the backward flow condensing part that can arrange in the air current passageway and retrieve and lead the drain with the condensate, be equipped with the air guide passageway with air current passageway UNICOM between backward flow condensing part and the drain, and/or be equipped with the air guide passageway with air current passageway UNICOM on the backward flow condensing part.

2. A condensables recovery atomizing assembly as claimed in claim 1 wherein said return flow condensing member (33) extends outwardly from at least one of a bottom, middle or top portion of the side of the liquid-conducting member (31).

3. A condensables recovery atomizing assembly as claimed in claim 1, wherein said reflux condenser (33) is of one-piece construction with the liquid-conducting member (31); or the reflux condensing part (33) is fixedly connected with the liquid guide part (31); or the side wall of the liquid guide piece (31) is provided with an embedding port, and the liquid guide piece (31) is embedded and connected in the embedding port to be fixed.

4. A condensables recovery atomizing assembly as claimed in claim 1 wherein said return condensing member (33) is provided with a return hole (331) extending through the gas flow passage.

5. The atomization assembly capable of condensing and recycling as claimed in claim 4, wherein the backflow hole (331) is formed in the middle of the backflow condensation member (33), or the backflow hole (331) is formed in the backflow condensation member (33) at intervals, or the backflow condensation member (33) has a porous through structure.

6. A condensables recovery atomizing assembly as claimed in claim 1, wherein said return condensing member (33) is provided with a ramp structure for directing condensate to said liquid-guiding member (31).

7. A condensation recovery atomizing assembly as set forth in claim 1, wherein at least one surface of said reflux condenser (33) has a rugged rough structure.

8. A condensables recovery atomizing assembly as claimed in claim 1, wherein said return condensing member (33) is provided with channels for directing condensate to said liquid-conducting member (31).

9. An atomization device capable of condensing and recycling, which comprises a shell (10), an atomization mechanism and a gas regulation control mechanism, wherein the atomization mechanism and the gas regulation control mechanism are arranged in the shell (10), and the atomization mechanism comprises an atomization assembly (3) as claimed in any one of claims 1 to 5, a gas guide pipe (301) communicated with the atomization assembly (3), and an oil storage assembly (302).

10. A condensables recovery atomiser device as claimed in claim 9, wherein a gas flow path is provided between the atomiser assembly and the housing (10), and the liquid-conducting part (31) of the atomiser assembly (3) extends into the gas flow path to return the condensing part (33).

11. A condensables recovery atomizer device as claimed in claim 9, wherein said recirculation condenser (33) of said atomizer assembly (3) abuts said housing (10) without clearance therebetween, and said recirculation condenser (33) is provided with an air guide channel communicating with said air flow channel.

12. A condensables recovery atomiser device as claimed in claim 9, characterised in that the return condensate (33) of the atomiser assembly (3) is partly in abutment with the housing (10) leaving an air-conducting channel therebetween communicating with the air-flow channel.

13. A condensables recovery atomiser device as claimed in claim 9, characterised in that the return condenser (33) of the atomiser assembly (3) is not in contact with the housing (10) and an air guide channel communicating with the air flow channel is provided therebetween.