Atomizing assembly, device, apparatus with primary and secondary temperature difference air channels and atomizing method

By using a main and auxiliary temperature difference air duct design, the atomizing air duct in the liquid guide and the temperature regulating air duct in the central tube are used to mix aerosol and air, which solves the problems of air duct blockage and hot mouthpiece, achieves suitable aerosol temperature and effective treatment of condensate, and improves the user experience.

CN115778015BActive Publication Date: 2026-06-19SHENZHEN MEIRAY VAP TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SHENZHEN MEIRAY VAP TECH CO LTD
Filing Date
2022-12-16
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In existing aerosol generators, the air passages are easily blocked by condensate, and the mouth is easily burned when aerosol is drawn in. The existing dual-air passage design has not effectively solved the problems of condensate backflow caused by the temperature difference of the central tube and unsuitable aerosol temperature.

Method used

The design adopts a main and auxiliary temperature difference air channel, including a central tube, a liquid guide and a heating element. The liquid guide has an atomizing air channel, and the heating element is connected to the atomizing air channel. The inner wall of the central tube has a temperature regulating air channel, and the outer wall of the liquid guide has a structural air-proof zone. The temperature is regulated by mixing aerosol and air through the temperature regulating air channel and the atomizing air channel.

Benefits of technology

It effectively reduces the problem of condensate clogging the air passage, ensures a suitable aerosol temperature, improves the user experience and the utilization rate of the atomizing medium, and reduces the phenomenon of scalding the mouth.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application provides an atomizing component, device, equipment, and atomizing method with a main and auxiliary temperature difference air passage. The aforementioned atomizing component with a main and auxiliary temperature difference air passage includes a central tube, a liquid guide, and a heating element. The liquid guide is housed within the central tube, and an air passage is formed within the liquid guide. The heating element is disposed within the air passage. The central tube has a medium channel, and the outer wall of the liquid guide is also used to contact the atomizing medium passing through the medium channel. The air passage within the liquid guide is an atomizing air passage. The heating element communicates with the atomizing air passage and is attached to or at least partially embedded in the inner wall of the liquid guide within the atomizing air passage. A temperature-regulating air passage is provided on the inner wall of the central tube in a region avoiding the medium channel, and a structural clearance area is provided on the outer wall of the liquid guide at the temperature-regulating air passage. The aforementioned atomizing component with a main and auxiliary temperature difference air passage can effectively reduce condensate blockage of the air passage and alleviate the problem of aerosol burns.
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Description

Technical Field

[0001] This invention relates to the field of aerosol generating devices, and in particular to an atomizing component, device, equipment, and atomizing method having a main and auxiliary temperature difference air passage. Background Technology

[0002] Aerosols are suspensions of liquid or solid particles in the air, typically generated by aerosol generators. These generators generally use traditional cylindrical ceramic atomizing cores, with the central axis of the cylindrical ceramic serving as the air passage. The outer wall of the cylindrical ceramic connects to the central tube via cotton, creating only a single air passage. Because the aerosol passes through the central tube, which is cooler than the air passage walls, the aerosol accumulates in the central tube. Over time, this condensate can flow back into the air passage of the cylindrical ceramic, causing blockage. This blockage results in a hissing sound during aerosol suction or the aspiration of condensate. Furthermore, since the aerosol is generated directly at the air passage, its initial temperature is relatively high. Directly drawing in large quantities of aerosol generated at the air passage can easily cause burns to the mouth, leading to a poor user experience. (Chinese Patent CN 114158776) A. A first atomizing surface and a first air channel for transmitting the aerosol generated by the first atomizing surface are provided, as well as a second atomizing surface and a second air channel for transmitting the aerosol generated by the second atomizing surface are provided. That is, two air channels are provided for the generation and suction of aerosol. Although the overall space of the air channels is expanded, which can reduce the problem of condensate clogging the holes, the two air channels have the same function. The temperature of the central tube is still lower than the temperature of the air channel wall, which causes the aerosol to be cooled in the central tube. After a long period of accumulation, the condensate will still flow back to the two air channels of the cylindrical ceramic, which will cause air channel blockage. It will also cause the problem of burning the mouth when directly sucking a large amount of aerosol generated at the two air channels. Summary of the Invention

[0003] The purpose of this invention is to overcome the shortcomings of the prior art and provide an atomizing component, device, equipment, and atomizing method with a main and auxiliary temperature difference air passage that can effectively reduce the blockage of the air passage by condensate and reduce the problem of aerosol burning the mouth.

[0004] The objective of this invention is achieved through the following technical solution:

[0005] An atomizing component with a main and auxiliary temperature difference air passage includes a central tube, a liquid guide, and a heating element. The liquid guide is fitted inside the central tube and has an air passage. The heating element is disposed inside the air passage. The central tube has a medium channel. The outer wall of the liquid guide is also used to contact the atomizing medium passing through the medium channel. The air passage inside the liquid guide is an atomizing air passage. The heating element is connected to the atomizing air passage and is attached to or at least partially embedded in the inner wall of the liquid guide on the atomizing air passage. The inner wall of the central tube has a temperature regulating air passage in a region avoiding the medium channel. The outer wall of the liquid guide has a structural clearance area at the temperature regulating air passage.

[0006] In one embodiment, the central tube and the liquid guide are integrally formed.

[0007] In one embodiment, the liquid guide extends through the medium channel and is embedded in the central tube wall.

[0008] In one embodiment, the atomizing component with main and auxiliary temperature difference air channels further includes a liquid-guiding cotton body, which is attached to the outer wall of the liquid guiding fluid and is at least partially sandwiched between the liquid guiding fluid and the central tube wall. The liquid-guiding cotton body is also connected to the medium channel. The liquid-guiding cotton body has an air channel through hole at the atomizing air channel, and the air channel through hole is connected to the atomizing air channel and the central tube respectively.

[0009] In one embodiment, the liquid-guiding cotton body has a perforated hole in the structural void area to allow the liquid-guiding fluid to communicate with the temperature-regulating air passage.

[0010] In one embodiment, the atomizing component with main and auxiliary temperature difference air channels further includes absorbent cotton, which is sleeved inside the central tube and spaced apart from the liquid guide. The absorbent cotton is provided with an aerosol flow hole, which is connected to the atomizing air channel. The absorbent cotton is positioned in a sheltered location at the temperature regulating air channel.

[0011] In one embodiment, a partition and a snap-fit ​​protrusion are provided inside the central tube, avoiding the temperature-regulating air passage. Both the partition and the snap-fit ​​protrusion are connected to the central tube, and the partition and the snap-fit ​​protrusion are connected to form an embedding area. The embedding area is connected to the temperature-regulating air passage, and the absorbent cotton is snapped into the embedding area.

[0012] In one embodiment, the heating element includes a first pin and a heating wire, one end of the first pin is connected to the end of the heating wire, the heating wire is in communication with the atomizing air channel, and the heating wire is wound around the atomizing air channel, and the heating wire is attached to or at least partially embedded in the inner wall of the liquid guide in the atomizing air channel, and the other end of the first pin protrudes from the liquid guide.

[0013] In one embodiment, the heating element includes a second pin and a heating element, one end of the second pin is connected to the heating element, the heating element is in communication with the atomizing air channel, and the heating element is attached to or at least partially embedded in the inner wall of the liquid guide in the atomizing air channel, and the other end of the second pin protrudes from the liquid guide.

[0014] In one embodiment, the number of the second pins is two;

[0015] The heating element includes a first heating part, a second heating part, and a conductor part. The first heating part and the second heating part are connected in series through the conductor part. One of the second pins is connected to the first heating part, and the other second pin is connected to the second heating part. Both the first heating part and the second heating part are connected to the atomizing air channel and are attached to or at least partially embedded in the inner wall of the liquid guiding air channel. The conductor part is at least partially embedded in the end of the liquid guiding air channel.

[0016] Atomizing device with a main and auxiliary temperature difference air passage includes an atomizing medium chamber, an atomizing seat, a nozzle, and an atomizing component with a main and auxiliary temperature difference air passage as described in any of the above embodiments. The atomizing medium chamber is sleeved on the outer wall of the central tube, the atomizing seat is connected to the end of the central tube, and the central tube, the atomizing medium chamber, and the atomizing seat are connected to form an atomizing medium storage cavity. The heating element protrudes from the central tube and is electrically connected to the atomizing seat. An air inlet is provided on the atomizing seat, and the air inlet is connected to the atomizing air passage and the temperature adjustment air passage, respectively. The nozzle is sleeved on the end of the atomizing medium chamber away from the atomizing seat, and the nozzle is connected to the central tube.

[0017] Atomizing device with a main and auxiliary temperature difference air passage includes a battery rod and an atomizing device with a main and auxiliary temperature difference air passage as described in any of the above embodiments, wherein the battery rod is electrically connected to the atomizing base.

[0018] An atomization method, employing an atomization component with a main and auxiliary temperature difference air passage as described in any of the above embodiments, atomizes to form an aerosol, comprising the following steps:

[0019] Obtain an atomizing medium so that the atomizing medium is conducted to the conductive liquid along the medium channel;

[0020] The heating element is used to heat and atomize the atomizing medium, so that the atomizing medium is atomized at the heating element to form an aerosol;

[0021] The atomizing airway is used to export the aerosol, so that the aerosol is exported from the atomizing airway.

[0022] The temperature-regulating air duct is used to regulate the temperature of the aerosol. The temperature-regulating air duct is used to export air. The temperature of the temperature-regulating air duct is lower than the temperature of the atomizing air duct. The air exported by the temperature-regulating air duct and the aerosol exported by the atomizing air duct are exported and mixed synchronously and then drawn out from the central tube.

[0023] In one embodiment, the temperature of the temperature-regulating air duct is room temperature;

[0024] The temperature of the atomizing air duct is 160℃~210℃.

[0025] In one embodiment, the distance between the side of the heating element near the outer wall of the central tube and the outer wall of the liquid guide is greater than or equal to 0.8 cm.

[0026] In one embodiment, after the step of temperature-regulating the aerosol using the temperature-regulating airway, the atomization method further includes the following step:

[0027] The aerosol is treated with absorbent cotton to absorb condensate. The absorbent cotton is disposed in a way that avoids the airflow between the atomizing airway and the temperature regulating airway, and is spaced apart from the liquid guide. The absorbent cotton is located at the outlet end of the atomizing airway. The absorbent cotton is used to absorb the condensate formed when the aerosol is cooled.

[0028] Compared with the prior art, the present invention has at least the following advantages:

[0029] The atomizing component of the present invention, having a main and auxiliary temperature difference airway, has an airway within the guiding liquid that serves as an atomizing airway. The heating element is connected to the atomizing airway and is attached to or at least partially embedded in the inner wall of the guiding liquid within the atomizing airway. This means the heating element directly atomizes the atomizing medium from the guiding liquid to form an aerosol, allowing the atomizing medium to be atomized at approximately 200°C. This results in a lower temperature at the outer wall of the guiding liquid. A temperature-regulating airway is located on the inner wall of the central tube in a region avoiding the medium channel. A structural clearance area is provided on the outer wall of the guiding liquid at the temperature-regulating airway. The temperature-regulating airway is formed through the inner wall of the central tube and the outer wall of the guiding liquid, thus the temperature at the temperature-regulating airway is low, essentially equivalent to room temperature. Furthermore, the aerosol formed by the heating element at the atomizing airway is directly driven by the air entering through the atomizing airway and flows out from the other end of the atomizing airway. In this case, the temperature-regulating airway only has air flowing from one end to the other and then interacting with the atomizing airway. The aerosols from the atomizing channel mix with the air from the temperature-regulating channel before being drawn out again. Since the air from the temperature-regulating channel is at room temperature, the temperature of the aerosol decreases effectively when it mixes with the aerosol from the atomizing channel, ensuring a suitable temperature and reducing the risk of burning the mouth during aerosol extraction. Furthermore, because the temperature of the temperature-regulating channel is lower than that of the atomizing channel, any remaining unabsorbed aerosol in the central tube will condense preferentially at the temperature-regulating channel, forming condensate. This results in a greater accumulation of condensate in the temperature-regulating channel, reducing the risk of condensate clogging the atomizing channel and improving the user experience. Additionally, because part of the sidewall of the temperature-regulating channel is a liquid guide, the condensate from the atomizing medium can be further extracted and reused, further improving the utilization rate of the atomizing medium. Attached Figure Description

[0030] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of the present invention and should not be regarded as a limitation on the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.

[0031] Figure 1 This is a schematic diagram of the structure of an atomizing component with a main and auxiliary temperature difference air passage according to an embodiment of the present invention.

[0032] Figure 2 for Figure 1 Another schematic diagram of an atomizing component with a main and auxiliary temperature difference air passage is shown.

[0033] Figure 3 for Figure 1The diagram shows a cross-sectional view of an atomizing assembly with a main and auxiliary temperature difference air passage.

[0034] Figure 4 for Figure 1 Another cross-sectional view of the atomizing assembly with main and auxiliary temperature difference air channels is shown.

[0035] Figure 5 for Figure 1 An exploded view of an atomizing assembly with a main and auxiliary temperature difference air passage is shown.

[0036] Figure 6 An exploded view of an atomizing component with a main and auxiliary temperature difference air passage according to another embodiment of the present invention.

[0037] Figure 7 for Figure 6 The diagram shows a cross-sectional view of an atomizing assembly with a main and auxiliary temperature difference air passage.

[0038] Figure 8 for Figure 6 A partial view of an atomizing assembly with a main and auxiliary temperature difference air passage is shown.

[0039] Figure 9 This is a schematic diagram of the structure of an atomizing component with a main and auxiliary temperature difference air passage according to another embodiment of the present invention.

[0040] Figure 10 for Figure 9 An exploded view of an atomizing assembly with a main and auxiliary temperature difference air passage is shown.

[0041] Figure 11 This is a schematic diagram of the structure of an atomizing component with a main and auxiliary temperature difference air passage according to another embodiment of the present invention.

[0042] Figure 12 for Figure 11 The exploded view of the atomizing component with main and auxiliary temperature difference air channels is shown.

[0043] Figure 13 for Figure 11 A partial view of an atomizing assembly with a main and auxiliary temperature difference air passage is shown.

[0044] Figure 14 for Figure 13 The diagram shows a cross-sectional view of an atomizing assembly with a main and auxiliary temperature difference air passage.

[0045] Figure 15 This is a flowchart of an atomization method according to an embodiment of the present invention. Detailed Implementation

[0046] To facilitate understanding of the present invention, a more complete description will be given below with reference to the accompanying drawings. Preferred embodiments of the invention are shown in the drawings. However, the invention can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a thorough and complete understanding of the disclosure of the invention.

[0047] It should be noted that when an element is referred to as being "fixed to" another element, it can be directly attached to the other element or there may be an intervening element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or there may be an intervening element. The terms "vertical," "horizontal," "left," "right," and similar expressions used herein are for illustrative purposes only and do not represent the only possible implementation.

[0048] Unless otherwise defined, 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 invention pertains. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.

[0049] This application provides an atomizing component with a main and auxiliary temperature difference air passage. The aforementioned atomizing component with a main and auxiliary temperature difference air passage includes a central tube, a liquid guide, and a heating element. The liquid guide is placed inside the central tube, and an air passage is formed inside the liquid guide. The heating element is disposed inside the air passage. The central tube has a medium passage. The outer wall of the liquid guide is also used to contact the atomizing medium passing through the medium passage. The air passage formed inside the liquid guide is an atomizing air passage. The heating element is connected to the atomizing air passage, and the heating element is attached to or at least partially embedded in the inner wall of the liquid guide in the atomizing air passage. A temperature regulating air passage is provided on the inner wall of the central tube in a region that avoids the medium passage. A structural clearance area is provided on the outer wall of the liquid guide at the temperature regulating air passage.

[0050] The aforementioned atomizing component with main and auxiliary temperature difference air channels has an atomizing air channel within its liquid guide. The heating element is connected to the atomizing air channel and is attached to or at least partially embedded in the inner wall of the liquid guide in the atomizing air channel. This means the heating element directly atomizes the atomizing medium from the liquid guide to form an aerosol, allowing the atomizing medium to be atomized at around 200°C. This results in a lower temperature at the outer wall of the liquid guide. A temperature-regulating air channel is located on the inner wall of the central tube in an area avoiding the medium channel. A structural clearance area is provided at the temperature-regulating air channel on the outer wall of the liquid guide. The temperature-regulating air channel is formed through the inner wall of the central tube and the outer wall of the liquid guide. Therefore, the temperature at the temperature-regulating air channel is low, essentially equivalent to room temperature. Furthermore, the aerosol formed by the heating element at the atomizing air channel is directly driven by the air entering through the atomizing air channel and flows out from the other end of the atomizing air channel. In this case, the temperature-regulating air channel only has air flowing from one end to the other and then flowing out through the atomizing air channel. The aerosol mixing process involves mixing the aerosol flowing from the atomizing channel with the air flowing from the temperature-regulating channel before continuing to be drawn out. Since the air flowing from the temperature-regulating channel is at room temperature, the temperature of the aerosol decreases effectively when it mixes with the aerosol flowing from the atomizing channel, ensuring a suitable temperature and mitigating the problem of scalding the mouth during aerosol extraction. Furthermore, because the temperature of the temperature-regulating channel is lower than that of the atomizing channel, any remaining unextracted aerosol in the central tube will preferentially condense upon encountering the cold air in the temperature-regulating channel, forming condensate. This results in a greater accumulation of condensate in the temperature-regulating channel, effectively reducing the problem of condensate clogging the atomizing channel and improving the user experience. Moreover, since part of the sidewall of the temperature-regulating channel is a liquid guide, the condensate of the atomizing medium can be further extracted and reused in the temperature-regulating channel, further improving the utilization rate of the atomizing medium.

[0051] It should be noted that ambient temperature refers to the air temperature in the environment where an atomizing component with a main and auxiliary temperature difference airflow channel is used. In other words, ambient temperature varies with the air temperature in the environment where the atomizing component with a main and auxiliary temperature difference airflow channel is used, and is generally between -10℃ and 40℃.

[0052] To better understand the atomizing component with main and auxiliary temperature difference air channels of this application, the following further explanation is provided:

[0053] Please refer to the following: Figures 1 to 5An atomizing assembly 10 with a main and auxiliary temperature difference air passage in one embodiment includes a central tube 100, a liquid guide 200, and a heating element 300. The liquid guide 200 is fitted inside the central tube 100, and an air passage is formed inside the liquid guide 200. The heating element 300 is disposed inside the air passage. The central tube 100 has a medium channel 101. The outer wall of the liquid guide 200 is also used to contact the atomizing medium passing through the medium channel 101. The air passage formed inside the liquid guide 200 is an atomizing air passage 201. The heating element 300 is connected to the atomizing air passage 201, and the heating element 300 is attached to or at least partially embedded in the inner wall of the liquid guide 200 on the atomizing air passage 201. A temperature regulating air passage 202 is provided on the inner wall of the central tube 100 in a region that avoids the medium channel 101. A structural clearance area 203 is provided on the outer wall of the liquid guide 200 at the temperature regulating air passage 202.

[0054] The aforementioned atomizing component 10 with main and auxiliary temperature difference air channels has an atomizing air channel 201 opened within the liquid guide 200. The heating element 300 is connected to the atomizing air channel 201, and the heating element 300 is attached to or at least partially embedded in the inner wall of the liquid guide 200 on the atomizing air channel 201. That is, the heating element 300 directly atomizes the atomizing medium discharged from the liquid guide 200 to form an aerosol, so that the temperature of the heating element 300 can achieve atomization of the atomizing medium at around 200°C. This results in a lower temperature at the outer wall of the liquid guide 200, while the inner wall of the central tube 100 remains cool. A temperature-regulating air duct 202 is provided in the area of ​​the open medium channel 101. A structural void area 203 is provided on the outer wall of the liquid guide 200 at the temperature-regulating air duct 202. That is, the temperature-regulating air duct 202 is formed by the inner wall of the central tube 100 and the outer wall of the liquid guide 200. Therefore, the temperature at the temperature-regulating air duct 202 is relatively low and can be considered equivalent to room temperature. Furthermore, the aerosol formed by the heating element 300 at the atomizing air duct 201 is directly driven by the air entering from the atomizing air duct 201 and flows out from the other end of the atomizing air duct 201. At this time, the temperature-regulating air duct 202 is only empty. After the air flows from one end to the other, it mixes with the aerosol flowing out of the atomizing airway 201. The aerosol flowing out of the atomizing airway 201, after mixing with the air flowing out of the temperature-regulating airway 202, continues to be drawn out. Since the air flowing out of the temperature-regulating airway 202 is at room temperature, its temperature is effectively lowered when mixed with the aerosol flowing out of the atomizing airway 201, ensuring a suitable temperature for the aerosol and thus mitigating the problem of scalding the mouth during aerosol drawing. Furthermore, because the temperature of the temperature-regulating airway 202 is lower than that of the atomizing airway 201... The temperature is relatively low, so if there is any residual aerosol that has not been aspirated and flows out into the central tube 100, the aerosol will be cooled and preferentially condensed in the temperature-adjusting airway 202 to form condensate. This causes more condensate to accumulate in the temperature-adjusting airway 202, which effectively reduces the problem of condensate clogging the atomizing airway 201 and improves the user experience. Furthermore, since part of the sidewall of the temperature-adjusting airway 202 is a liquid guide 200, the condensate of the atomizing medium can be further discharged and reused in the temperature-adjusting airway 202, which further improves the utilization rate of the atomizing medium.

[0055] In one embodiment, the central tube and the liquid guide are integrally molded. It is understood that making the central tube and the liquid guide an integrally molded structure improves the connection stability and compactness between the two, thereby better ensuring the structural stability and compactness of the atomizing component with main and auxiliary temperature difference air channels. Furthermore, it reduces the processing steps of the atomizing component with main and auxiliary temperature difference air channels, thus improving the processing efficiency.

[0056] Please refer to the following: Figure 1 and Figure 9In one embodiment, the liquid guide 200 penetrates the medium channel 101 and is embedded in the wall of the central tube 100, which better ensures the tightness and stability of the liquid guide 200 in sealing the medium channel 101, thereby better mitigating the leakage problem of the atomizing medium of the atomizing component 10 with the main and auxiliary temperature difference air channels.

[0057] Please refer to the following: Figures 6 to 8 ,as well as Figure 12 In one embodiment, the atomizing component 10 with main and auxiliary temperature difference air channels further includes a liquid-guiding cotton body 400. The liquid-guiding cotton body 400 is attached to the outer wall of the liquid guiding 200, and the liquid-guiding cotton body 400 is at least partially sandwiched between the liquid guiding 200 and the wall of the central tube 100. The liquid-guiding cotton body 400 is connected to the medium channel 101. The liquid-guiding cotton body 400 has an air channel through hole 401 at the atomizing air channel 201, and the air channel through hole 401 is connected to the atomizing air channel 201 and the central tube 101 respectively. It is understood that the liquid-guiding cotton body 400 is attached to the outer wall of the liquid-guiding 200, and the liquid-guiding cotton body 400 is at least partially sandwiched between the liquid-guiding 200 and the wall of the central tube 100, and the liquid-guiding cotton body 400 is connected to the medium channel 101. The liquid-guiding cotton body 400 has an air passage hole 401 at the atomizing air channel 201, and the air passage hole 401 is connected to the atomizing air channel 201 and the central tube 100 respectively. This effectively assists the liquid-guiding 200 in effectively sealing the medium channel 101, thereby effectively reducing the leakage problem of the atomizing medium of the atomizing component 10 with main and auxiliary temperature difference air channels.

[0058] Please refer to the following: Figure 6 , Figure 8 , Figure 9 and Figure 12 In one embodiment, the liquid-guiding cotton body 400 has a hollow hole 402 in the structural void area 203 so that the liquid-guiding 200 can be connected to the temperature-regulating air channel 202, so that the liquid-guiding cotton can be quickly assembled on the surface of the liquid-guiding 200, thereby improving the assembly efficiency of the atomizing component 10 with the main and auxiliary temperature difference air channels.

[0059] Please refer to the following: Figures 3 to 5 , Figure 6 , Figure 7 and Figure 12In one embodiment, the atomizing component 10 with main and auxiliary temperature difference air channels further includes a liquid-absorbing cotton 500, which is sleeved inside the central tube 100 and spaced apart from the liquid guide 200. The liquid-absorbing cotton 500 has an aerosol flow hole 501, which is connected to the atomizing air channel 201. The liquid-absorbing cotton 500 is provided in a sheltered position at the temperature regulating air channel 202. It is understandable that using a temperature-regulating airway 202, which has a lower temperature than the atomizing airway 201, in conjunction with the atomizing airway 201 causes the aerosol to preferentially cool and form condensate at the temperature-regulating airway 202, thus effectively mitigating the problem of condensate clogging the atomizing airway 201. However, even under these conditions, some aerosol still condenses at the location of the central tube 100 corresponding to the atomizing airway 201, forming condensate that flows back to the atomizing airway 201. Consequently, with prolonged use, the problem of condensate clogging the atomizing airway 201 still exists. Therefore, in this application, the absorbent cotton 500 is placed inside the central tube 100, and the absorbent cotton 500 and the liquid guide 200 are spaced apart, with the absorbent cotton 500 having an aerosol flow hole 5. 01. The aerosol flow passage is connected to the atomizing air channel 201. The absorbent cotton 500 is set in the temperature-regulating air channel 202 in a sheltered position. This further allows the aerosol to pass through the absorbent cotton 500 immediately after flowing out of the atomizing air channel 201. At the same time, the air flowing out of the temperature-regulating air channel 202 also passes through the absorbent cotton 500. This allows the air and aerosol to mix at the atomizing cotton, thereby regulating the aerosol temperature. The remaining unabsorbed aerosol will preferentially condense on the hole wall or sheltered position formed on the absorbent cotton 500, forming condensate. Since the absorbent cotton 500 has the function of absorbing the atomizing medium, more of the condensate is absorbed into the absorbent cotton 500, thus better mitigating the problem of condensate clogging the atomizing air channel 201.

[0060] Please refer to the following: Figures 3 to 5 and Figure 7In one embodiment, a partition 110 and a snap-fit ​​protrusion 120 are provided inside the central tube 100, avoiding the temperature regulating air passage 202. Both the partition 110 and the snap-fit ​​protrusion 120 are connected to the central tube 100, and the partition 110 and the snap-fit ​​protrusion 120 are connected to form an embedding area 102. The embedding area 102 is connected to the temperature regulating air passage 202, and the absorbent cotton 500 is snapped into the embedding area 102. It is understandable that cotton bodies with good washing liquid absorption capacity have poor shape stability. If the absorbent cotton 500 is processed to form a structure that avoids the temperature-regulating air passage 202 and the atomizing air passage 201, that is, during the process of absorbing condensate, the absorbent cotton 500 will expand, affecting the smoothness of the temperature-regulating air passage 202 and the atomizing air passage 201, and may even cause the absorbent cotton 500 to block the temperature-regulating air passage 202 or the atomizing air passage 201. Therefore, in this application, the partition 110 and the snap-fit ​​protrusion 120 are connected to form an embedding area 102, which embeds... Zone 102 is connected to the temperature regulating air duct 202. The absorbent cotton 500 is snapped into the embedded zone 102, thus forming a structure on the central tube 100 that avoids the temperature regulating air duct 202 and the atomizing air duct 201. This not only effectively avoids the problem of deformation of the absorbent cotton 500 affecting the smoothness or even blocking of the temperature regulating air duct 202 and the atomizing air duct 201, but also effectively improves the assembly stability and positioning accuracy of the absorbent cotton 500. This better ensures the smoothness of the atomizing channel and the temperature regulating air duct 202, and also better ensures the effective absorption of condensate by the absorbent cotton 500.

[0061] Please refer to the following: Figure 1 , Figures 3 to 7 In one embodiment, the heating element 300 includes a first pin 310 and a heating wire 320. One end of the first pin 310 is connected to the end of the heating wire 320. The heating wire 320 communicates with the atomizing air channel 201 and is wound around the atomizing air channel 201. The heating wire 320 is attached to or at least partially embedded in the liquid guide 200 on the inner wall of the atomizing air channel 201. The other end of the first pin 310 protrudes from the liquid guide 200.

[0062] Please refer to the following: Figures 9 to 14 In one embodiment, the heating element 300 includes a second pin 330 and a heating element 340. One end of the second pin 330 is connected to the heating element 340, the heating element 340 is connected to the atomizing air channel 201, and the heating element 340 is attached to or at least partially embedded in the inner wall of the liquid guide 200 on the atomizing air channel 201. The other end of the second pin 330 protrudes from the liquid guide 200.

[0063] Please refer to the following: Figures 9 to 14In one embodiment, there are two second pins 330. Further, the heating element 340 includes a first heating part 341, a second heating part 342, and a conductor part 343. The first heating part 341 and the second heating part 342 are connected in series via the conductor part 343. One second pin 330 is connected to the first heating part 341, and the other second pin 330 is connected to the second heating part 342. Both the first heating part 341 and the second heating part 342 are connected to the atomizing airway 201 and are both attached to or at least partially embedded in the inner wall of the liquid guide 200 on the atomizing airway 201. The conductor part 343 is at least partially embedded in the end of the liquid guide 200.

[0064] In one embodiment, the temperature-regulating airway is a vortex-type spiral airway. It can be understood that a vortex-type spiral airway is a spiral-shaped airway capable of generating vortices. Although the gas mixing speed is relatively fast, the overall airflow speed is also very high when the user inhales the atomized aerosol. If the air flowing out of the temperature-regulating airway cannot quickly mix with the aerosol flowing out of the atomizing airway, even under conditions where gas mixing is achieved, the mixing speed between the air flowing out of the temperature-regulating airway and the aerosol flowing out of the atomizing airway will still be slower than the inhalation speed. Consequently, it will be difficult to sufficiently adjust the aerosol temperature to a better perceived temperature, leading to a higher temperature of the heating element and thus promoting gas... Even when the temperature of the aerosol is high, the problem of burning the mouth when drawing in the aerosol still exists. Therefore, in this application, the temperature-regulating airway is made into a spiral shape, so that the air entering the temperature-regulating airway will have a vortex phenomenon. This results in the air flowing out of the temperature-regulating airway having greater diffusion power, making it easier to mix quickly with the aerosol flowing out of the atomizing airway. This better ensures that the temperature of the aerosol drops rapidly and that the mixing speed of the air flowing out of the temperature-regulating airway and the aerosol flowing out of the atomizing airway keeps up with the drawing speed. This effectively reduces the problem of burning the mouth when drawing in the aerosol and affecting the user's experience.

[0065] In one embodiment, the heating element is completely embedded in the conductive fluid.

[0066] Please refer to the following: Figure 9 , Figure 13 and Figure 14In one embodiment, the atomizing airway 201 includes an oil-blocking section 2012 and an atomizing section 2011 connected end-to-end. The heating element 300 is disposed in the atomizing section 2011. The sidewall of the atomizing section 2011 is located on the outer periphery of the sidewall of the oil-blocking section 2012 at the connection point between the oil-blocking section 2012 and the atomizing section 2011. It can be understood that having the atomizing airway 201 including the oil-blocking section 2012 and the atomizing section 2011 connected end-to-end results in a simple structure. Furthermore, at the connection point between the oil-blocking section 2012 and the atomizing section 2011, the area enclosed by the sidewall of the atomizing section 2011 includes the area enclosed by the sidewall of the oil-blocking section 2012. Given the same length, the volume of the atomizing section 2011 is larger than the volume of the oil-blocking section 2012, which better ensures that the oil-blocking section 2012 of the atomizing airway 201 is close to the oil-blocking section 2012. One end of the near-atomization section 2011 blocks the large particles of atomized medium generated at the atomization section 2011 during frying. The large particles of atomized medium blocked by the oil blocking section 2012 are still located on the guide liquid 200, and can be introduced by the guide liquid 200 and re-atomized by the heating element 300 to form an aerosol. That is, while ensuring the simple structure of the atomization component 10 with the main and auxiliary temperature difference air channels, the problem of poor user experience caused by frying oil is effectively reduced.

[0067] This application also provides an atomizing device with a main and auxiliary temperature difference airway. The aforementioned atomizing device with a main and auxiliary temperature difference airway includes an atomizing medium chamber, an atomizing seat, a nozzle, and an atomizing assembly with a main and auxiliary temperature difference airway according to any of the above embodiments. The atomizing medium chamber is sleeved on the outer wall of a central tube, the atomizing seat is connected to the end of the central tube, and the central tube, the atomizing medium chamber, and the atomizing seat are connected to form an atomizing medium storage cavity. The heating element protrudes from the central tube and is electrically connected to the atomizing seat. An air inlet is provided on the atomizing airway and the temperature adjustment airway, respectively. The nozzle is sleeved on the end of the atomizing medium chamber away from the atomizing seat, and the nozzle is connected to the central tube. Further, please refer to... Figures 1 to 5 The atomizing component 10 with a main and auxiliary temperature difference air passage includes a central tube 100, a liquid guide 200, and a heating element 300. The liquid guide 200 is fitted inside the central tube 100 and has an air passage. The heating element 300 is disposed inside the air passage. The central tube 100 has a medium channel 101. The outer wall of the liquid guide 200 is also used to contact the atomizing medium passing through the medium channel 101. The air passage inside the liquid guide 200 is an atomizing air passage 201. The heating element 300 is connected to the atomizing air passage 201 and is attached to or at least partially embedded in the inner wall of the liquid guide 200 on the atomizing air passage 201. The inner wall of the central tube 100 has a temperature regulating air passage 202 in a region that avoids the medium channel 101. The outer wall of the liquid guide 200 has a structural clearance area 203 at the temperature regulating air passage 202.

[0068] The aforementioned atomizing device with main and auxiliary temperature difference air channels adopts an atomizing component with main and auxiliary temperature difference air channels, which better ensures the appropriate temperature of the aerosol, thereby reducing the problem of scalding the mouth when the aerosol is drawn out, and also reducing the problem of condensate clogging the atomizing air channels, effectively improving the user experience.

[0069] This application also provides an atomizing device with a main and auxiliary temperature difference airway. The aforementioned atomizing device with a main and auxiliary temperature difference airway includes a battery rod and an atomizing device with a main and auxiliary temperature difference airway, the battery rod being electrically connected to the atomizing base. Further, the atomizing device with a main and auxiliary temperature difference airway includes an atomizing medium chamber, an atomizing base, a nozzle, and an atomizing assembly with a main and auxiliary temperature difference airway according to any of the above embodiments. The atomizing medium chamber is sleeved on the outer wall of the central tube, the atomizing base is connected to the end of the central tube, and the central tube, the atomizing medium chamber, and the atomizing base are connected to form an atomizing medium storage cavity. The heating element protrudes from the central tube and is electrically connected to the atomizing base. An air inlet is provided on the atomizing airway and the temperature-regulating airway, respectively. The nozzle is sleeved on the end of the atomizing medium chamber away from the atomizing base and is connected to the central tube.

[0070] The aforementioned atomizing device with main and auxiliary temperature difference air channels employs an atomizing device with main and auxiliary temperature difference air channels, which better ensures the appropriate temperature of the aerosol, thereby reducing the problem of scalding the mouth when the aerosol is drawn out, and also reducing the problem of condensate clogging the atomizing air channels, effectively improving the user experience.

[0071] This application also provides an atomization method, which uses an atomization component with a main and auxiliary temperature difference air passages according to any of the above embodiments to atomize and form an aerosol. The atomization method includes the following steps: obtaining an atomization medium and conducting it along a medium passage to a liquid conductor; heating and atomizing the atomization medium using a heating element to form an aerosol at the heating element; exporting the aerosol using an atomization air passage; and adjusting the temperature of the aerosol using a temperature-adjusting air passage, wherein the temperature-adjusting air passage is used to export air, the temperature of the temperature-adjusting air passage is lower than the temperature of the atomization air passage, and the air exported from the temperature-adjusting air passage and the aerosol exported from the atomization air passage are exported and mixed simultaneously and drawn out from the central tube.

[0072] The aforementioned atomization method allows the atomizing medium to be conducted along the medium channel to the guiding liquid, further enabling the heating element to heat and atomize the atomizing medium, thus forming an aerosol at the heating element. This allows the heating element to directly contact the atomizing medium and directly atomize the atomizing medium from the guiding liquid. Consequently, the heating element can achieve atomization of the atomizing medium at approximately 200°C. The atomization channel is formed near the inner wall of the heating element by the guiding liquid. The temperature of the heating element and the aerosol causes the temperature of the atomization channel to rise. However, since the aerosol flows directly out from the atomization channel and not through the temperature-regulating channel, the temperature of the aerosol has no effect on the temperature of the temperature-regulating channel. Furthermore, the temperature of the heating element is only around 200°C. The temperature is around ℃, and the temperature-regulating air channel is formed by the outer wall of the liquid guide and the inner wall of the central tube. This makes the influence of the heating element on the temperature of the temperature-regulating air channel relatively small. That is, the temperature of the temperature-regulating air channel can be considered to be equivalent to the room temperature. At this time, the temperature of the air flowing out of the temperature-regulating air channel is lower than that of the aerosol. This allows the air flowing out of the temperature-regulating air channel to mix with the aerosol flowing out of the atomizing air channel and continue to be drawn out. At this time, the air has a temperature regulating effect on the aerosol. That is, when the air flowing out of the temperature-regulating air channel mixes with the aerosol flowing out of the atomizing air channel, the temperature of the aerosol can be reduced effectively, ensuring the appropriate temperature of the aerosol. This effectively reduces the problem of scalding the mouth when drawing out the aerosol and effectively realizes the atomization of the atomizing medium to form an aerosol.

[0073] To better understand the atomization method of this application, the following further explanation is provided:

[0074] Please refer to the following: Figure 15 One embodiment of the atomization method includes the following steps:

[0075] S100. Obtain the atomizing medium and conduct it along the medium channel to the liquid conductor. It can be understood that conducting the atomizing medium to the liquid conductor ensures better contact between the heating element and the atomizing medium, thereby better ensuring the atomization effect of the heating element on the atomizing medium, that is, better ensuring the aerosol generation effect.

[0076] S200: A heating element is used to heat and atomize the atomizing medium, so that the atomizing medium is atomized at the heating element to form an aerosol. It can be understood that by having the heating element atomize the liquid-conducting atomizing medium, the heating element heats up, causing the atomizing medium to be heated and atomized, thus effectively achieving the atomization of the atomizing medium to form an aerosol.

[0077] S300: An atomizing channel is used to discharge the aerosol, allowing it to exit through the atomizing channel. This is because the heating element directly atomizes the atomizing medium from the guiding liquid, achieving atomization at around 200°C. The atomizing channel is formed by the guiding liquid near the inner wall of the heating element. The temperature of the heating element and the aerosol causes the temperature of the atomizing channel to rise. However, since the aerosol flows directly out of the atomizing channel and not through the temperature-regulating channel, its temperature has no effect on the temperature of the temperature-regulating channel. Furthermore, the temperature of the heating element is only around 200°C, and the temperature-regulating channel is formed by the outer wall of the guiding liquid and the inner wall of the central tube, further minimizing the influence of the heating element on the temperature of the temperature-regulating channel. In other words, the temperature of the temperature-regulating channel can be considered equivalent to room temperature. At this point, the air flowing out of the temperature-regulating airway is at a lower temperature than the aerosol. This allows the air flowing out of the temperature-regulating airway to mix with the aerosol flowing out of the atomizing airway before being drawn out again. The air at this point has a temperature-regulating effect on the aerosol. That is, when the air flowing out of the temperature-regulating airway mixes with the aerosol flowing out of the atomizing airway, the temperature of the aerosol can be lowered effectively, ensuring the appropriate temperature of the aerosol. This effectively reduces the problem of burning the mouth when drawing out the aerosol. In other words, using the atomizing airway to discharge the aerosol effectively avoids the aerosol's influence on the temperature of the temperature-regulating airway, which is beneficial for subsequent aerosol temperature regulation.

[0078] S400 employs a temperature-regulating air duct for aerosol temperature control. This duct is used to extract air, and its temperature is lower than that of the atomizing air duct. The air extracted from the temperature-regulating air duct and the aerosol extracted from the atomizing air duct are simultaneously extracted, mixed, and drawn out from the central tube. This design effectively lowers the aerosol temperature, ensuring a suitable temperature and thus mitigating the issue of scalding the mouth during aerosol extraction.

[0079] The aforementioned atomization method allows the atomizing medium to be conducted along the medium channel to the guiding liquid, further enabling the heating element to heat and atomize the atomizing medium, thus forming an aerosol at the heating element. This allows the heating element to directly contact the atomizing medium and directly atomize the atomizing medium from the guiding liquid. Consequently, the heating element can achieve atomization of the atomizing medium at approximately 200°C. The atomization channel is formed near the inner wall of the heating element by the guiding liquid. The temperature of the heating element and the aerosol causes the temperature of the atomization channel to rise. However, since the aerosol flows directly out from the atomization channel and not through the temperature-regulating channel, the temperature of the aerosol has no effect on the temperature of the temperature-regulating channel. Furthermore, the temperature of the heating element is only around 200°C. The temperature is around ℃, and the temperature-regulating air channel is formed by the outer wall of the liquid guide and the inner wall of the central tube. This makes the influence of the heating element on the temperature of the temperature-regulating air channel relatively small. That is, the temperature of the temperature-regulating air channel can be considered to be equivalent to the room temperature. At this time, the temperature of the air flowing out of the temperature-regulating air channel is lower than that of the aerosol. This allows the air flowing out of the temperature-regulating air channel to mix with the aerosol flowing out of the atomizing air channel and continue to be drawn out. At this time, the air has a temperature regulating effect on the aerosol. That is, when the air flowing out of the temperature-regulating air channel mixes with the aerosol flowing out of the atomizing air channel, the temperature of the aerosol can be reduced effectively, ensuring the appropriate temperature of the aerosol. This effectively reduces the problem of scalding the mouth when drawing out the aerosol and effectively realizes the atomization of the atomizing medium to form an aerosol.

[0080] In one embodiment, the temperature of the temperature-regulating air duct is at room temperature. Further, the temperature of the atomizing air duct is 160°C to 210°C. It can be understood that controlling the temperature of the temperature-regulating air duct to room temperature, and further, the temperature of the atomizing air duct being 160°C to 210°C, better ensures the temperature regulation effect of the air flowing out of the temperature-regulating air duct on the aerosol flowing out of the atomizing air duct, thereby better mitigating the problem of scalding the mouth when the aerosol is drawn out.

[0081] In one embodiment, the distance between the side of the heating element near the outer wall of the central tube and the outer wall of the liquid guide is greater than or equal to 0.8 cm. It is understood that ensuring this distance between the side of the heating element near the outer wall of the central tube and the outer wall of the central tube better guarantees that the temperature of the heating element has only a small impact on the temperature of the outer wall of the liquid guide, meaning that the heating element does not cause an increase in the temperature of the outer wall of the liquid guide, or the increase is considered very small. This better ensures the temperature regulation effect of the air flowing out of the temperature-regulating airway on the temperature of the aerosol flowing out of the atomizing airway, and thus better mitigates the problem of burning the mouth when the aerosol is drawn out.

[0082] In one embodiment, after the step of temperature-regulating the aerosol using a temperature-regulating air duct, the atomization method further includes the following step: using absorbent cotton to absorb condensate from the aerosol, wherein the absorbent cotton is disposed in a way that avoids gaps between the atomizing air duct and the temperature-regulating air duct, and the absorbent cotton is spaced apart from the liquid guide, and the absorbent cotton is located at the outlet end of the atomizing air duct, and the absorbent cotton is used to absorb the condensate formed after the aerosol cools down. It is understandable that even when a temperature-regulating airway with a lower temperature than the atomizing airway is used in conjunction with the atomizing airway, causing the aerosol to preferentially condense at the temperature-regulating airway, some aerosol still condenses at the location of the central tube corresponding to the atomizing airway, flowing back into the atomizing airway. This leads to condensation clogging the atomizing airway over extended use. Therefore, in this application, absorbent cotton is used to absorb the condensate from the aerosol. This ensures that the aerosol passes through the absorbent cotton immediately after flowing out of the atomizing airway, and the air flowing out of the temperature-regulating airway also passes through the absorbent cotton simultaneously. This allows the air and aerosol to mix at the atomizing cotton, thus regulating the aerosol temperature. Any remaining unabsorbed aerosol preferentially condenses at the pores or open areas formed on the absorbent cotton. Because the absorbent cotton absorbs the atomizing medium, a larger amount of condensate is absorbed into the absorbent cotton, thus better mitigating the problem of condensation clogging the atomizing airway.

[0083] Compared with the prior art, the present invention has at least the following advantages:

[0084] The atomizing component 10 of the present invention, having a main and auxiliary temperature difference air passage, has an air passage 201 formed within its liquid guide 200. A heating element 300 communicates with the atomizing air passage 201, and the heating element 300 is attached to or at least partially embedded in the inner wall of the liquid guide 200 within the atomizing air passage 201. That is, the heating element 300 directly atomizes the atomizing medium discharged from the liquid guide 200 to form an aerosol. This allows the atomizing medium to be atomized at a temperature of approximately 200°C, resulting in a lower temperature at the outer wall of the liquid guide 200 and a lower temperature at the inner wall of the central tube 100. A temperature-regulating air duct 202 is provided in the area away from the medium channel 101. A structural clearance area 203 is provided on the outer wall of the liquid guide 200 at the temperature-regulating air duct 202. That is, the temperature-regulating air duct 202 is formed through the inner wall of the central tube 100 and the outer wall of the liquid guide 200. Therefore, the temperature at the temperature-regulating air duct 202 is relatively low and can be considered equivalent to room temperature. Furthermore, the aerosol formed by the heating element 300 at the atomizing air duct 201 is directly driven by the air entering from the atomizing air duct 201 and flows out from the other end of the atomizing air duct 201. At this time, the temperature-regulating air duct 202 is only Air flows from one end to the other and mixes with the aerosol flowing out of the atomizing airway 201. The aerosol flowing out of the atomizing airway 201, after mixing with the air flowing out of the temperature-regulating airway 202, continues to be drawn out. Since the air flowing out of the temperature-regulating airway 202 is at room temperature, its temperature is effectively lowered when mixed with the aerosol flowing out of the atomizing airway 201, ensuring a suitable temperature for the aerosol and thus mitigating the problem of scalding the mouth during aerosol extraction. Furthermore, because the temperature of the temperature-regulating airway 202 is lower than that of the atomizing airway 201... The lower temperature means that if any residual aerosol remains at the central tube 100, it will condense preferentially at the temperature-regulating airway 202, forming condensate. This results in a greater accumulation of condensate at the temperature-regulating airway 202, effectively mitigating the problem of condensate clogging the atomizing airway 201 and improving the user experience. Furthermore, since part of the sidewall of the temperature-regulating airway 202 is a liquid guide 200, the condensate of the atomizing medium can be further discharged and reused at the temperature-regulating airway 202, further improving the utilization rate of the atomizing medium.

[0085] The embodiments described above are merely illustrative of several implementations of the present invention, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the invention patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of the present invention, and these all fall within the protection scope of the present invention. Therefore, the protection scope of this invention patent should be determined by the appended claims.

Claims

1. An atomizing assembly with a main and auxiliary temperature difference air passage, comprising a central tube, a liquid guide, and a heating element, wherein the liquid guide is fitted inside the central tube, an air passage is formed within the liquid guide, the heating element is disposed within the air passage, the central tube has a medium channel, and the outer wall of the liquid guide is also used to contact the atomizing medium passing through the medium channel, characterized in that, The air passage opened in the liquid guide is an atomizing air passage. The heating element is connected to the atomizing air passage, and the heating element is attached to or at least partially embedded in the inner wall of the liquid guide in the atomizing air passage. The inner wall of the central tube is provided with a temperature regulating air passage in the area that avoids the medium channel. The outer wall of the liquid guide is provided with a structural void area at the temperature regulating air passage. The heating element includes a second pin and a heating element. One end of the second pin is connected to the heating element, the heating element is in communication with the atomizing air channel, and the heating element is attached to or at least partially embedded in the inner wall of the liquid guiding channel. The other end of the second pin protrudes from the liquid guiding channel. The number of the second pins is two; The heating element includes a first heating part, a second heating part, and a conductor part. The first heating part and the second heating part are connected in series through the conductor part. One of its second pins is connected to the first heating part, and the other second pin is connected to the second heating part. Both the first heating part and the second heating part are connected to the atomizing air channel and are attached to or at least partially embedded in the inner wall of the liquid guiding air channel. The conductor part is at least partially embedded in the end of the liquid guiding air channel. The atomizing component with main and auxiliary temperature difference air channels also includes absorbent cotton, which is sleeved inside the central tube and spaced apart from the liquid guide. The absorbent cotton is provided with an aerosol flow hole, which is connected to the atomizing air channel. The absorbent cotton is provided in a way that avoids airflow at the temperature regulating air channel. Inside the central tube, avoiding the temperature-regulating air passage, there is a partition and a snap-fit ​​protrusion. Both the partition and the snap-fit ​​protrusion are connected to the central tube, and the partition and the snap-fit ​​protrusion are connected to form an embedding area. The embedding area is connected to the temperature-regulating air passage, and the absorbent cotton is snapped into the embedding area.

2. The atomizing component with main and auxiliary temperature difference air channels according to claim 1, characterized in that, The central tube and the liquid guide are integrally formed; and / or... The guiding liquid penetrates the medium channel and is embedded in the central tube wall.

3. The atomizing component with main and auxiliary temperature difference air channels according to claim 1, characterized in that, The atomizing component with main and auxiliary temperature difference air channels also includes a liquid-guiding cotton body, which is attached to the outer wall of the liquid guiding fluid and is at least partially sandwiched between the liquid guiding fluid and the central tube wall. The liquid-guiding cotton body is also connected to the medium channel. The liquid-guiding cotton body has an air channel through hole at the atomizing air channel, and the air channel through hole is connected to the atomizing air channel and the central tube respectively.

4. The atomizing component with main and auxiliary temperature difference air channels according to claim 3, characterized in that, The liquid-guiding cotton body has perforated holes in the structural void area to allow the liquid to communicate with the temperature-regulating air passage.

5. The atomizing component with main and auxiliary temperature difference air channels according to claim 1, characterized in that, The heating element includes a first pin and a heating wire. One end of the first pin is connected to the end of the heating wire. The heating wire is in communication with the atomizing air channel and is wound around the atomizing air channel. The heating wire is also attached to or at least partially embedded in the inner wall of the liquid guide in the atomizing air channel. The other end of the first pin protrudes from the liquid guide.

6. An atomizing device with main and auxiliary temperature difference air channels, characterized in that, The atomizing assembly includes an atomizing medium chamber, an atomizing seat, a nozzle, and an atomizing component with a main and auxiliary temperature difference air passage as described in any one of claims 1 to 5. The atomizing medium chamber is sleeved on the outer wall of the central tube, the atomizing seat is connected to the end of the central tube, and the central tube, the atomizing medium chamber, and the atomizing seat are connected to form an atomizing medium storage cavity. The heating element protrudes from the central tube and is electrically connected to the atomizing seat. An air inlet is provided on the atomizing seat, and the air inlet is connected to the atomizing air passage and the temperature regulating air passage, respectively. The nozzle is sleeved on the end of the atomizing medium chamber away from the atomizing seat, and the nozzle is connected to the central tube.

7. An atomizing device with main and auxiliary temperature difference air channels, characterized in that, The device includes a battery rod and an atomizing device with a main and auxiliary temperature difference air passage as described in claim 6, wherein the battery rod is electrically connected to the atomizing base.

8. An atomization method, comprising atomizing an aerosol using an atomization component having a main and auxiliary temperature difference air passage as described in any one of claims 1 to 5, characterized in that, Includes the following steps: Obtain an atomizing medium so that the atomizing medium is conducted to the conductive liquid along the medium channel; The heating element is used to heat and atomize the atomizing medium, so that the atomizing medium is atomized at the heating element to form an aerosol; The atomizing airway is used to export the aerosol, so that the aerosol is exported from the atomizing airway. The temperature-regulating air duct is used to regulate the temperature of the aerosol. The temperature-regulating air duct is used to export air. The temperature of the temperature-regulating air duct is lower than the temperature of the atomizing air duct. The air exported by the temperature-regulating air duct and the aerosol exported by the atomizing air duct are exported and mixed synchronously and then drawn out from the central tube.

9. The atomization method according to claim 8, characterized in that, The temperature of the temperature-regulating air duct is room temperature; The temperature of the atomizing air passage is 160℃~210℃; and / or, The distance between the side of the heating element closest to the outer wall of the central tube and the outer wall of the liquid-conducting element is greater than or equal to 0.8 cm.

10. The atomization method according to claim 8, characterized in that, After the step of temperature-regulating the aerosol using the temperature-regulating air duct, the atomization method further includes the following step: using absorbent cotton to absorb condensate from the aerosol, wherein the absorbent cotton is disposed in a way that avoids gaps between the atomizing air duct and the temperature-regulating air duct, and the absorbent cotton is spaced apart from the liquid guide, and the absorbent cotton is located at the outlet end of the atomizing air duct, and the absorbent cotton is used to absorb the condensate formed after the aerosol cools down.