CN219396285U - Atomization assembly, device and equipment with main and auxiliary temperature difference air passages - Google Patents

Abstract

The application provides an atomization component, device and equipment with main and auxiliary temperature difference air passages. Foretell atomization component with main and auxiliary difference in temperature air flue includes the center tube, lead liquid and generate heat the piece, lead the liquid cover and put in the center tube, lead the liquid in seted up the air flue, it sets up in the air flue to generate heat the piece, medium passageway has been seted up to the center tube, the outer wall of leading the liquid still is used for contacting with the atomizing medium through medium passageway, the air flue of seting up in the liquid is atomizing air flue, it communicates with atomizing air flue to generate heat the piece, and it pastes to establish or at least partly inlay to lead the liquid on the inner wall of atomizing air flue to generate heat, the center tube inner wall is provided with the air flue that adjusts the temperature in the region of avoiding medium passageway, the outer wall of leading the liquid is provided with the structure in air flue department that adjusts the temperature and keeps away the sky. The atomization component with the main and auxiliary temperature difference air passages can effectively reduce the problem that condensate blocks the air passages and aerosol scalding nozzles.

Description

Atomization assembly, device and equipment with main and auxiliary temperature difference air passages

Technical Field

The utility model relates to the technical field of aerosol generating devices, in particular to an atomization assembly, an atomization assembly device and atomization equipment with main and auxiliary temperature difference air passages.

Background

Aerosol is suspension system of liquid or solid particles in the air, generally, go on through aerosol generating equipment, and aerosol generating equipment generally adopts traditional cylinder pottery atomizing core, it uses the center pin of cylinder pottery as the air flue, cylinder pottery outer wall passes through cotton and center tube cooperation, only have single air flue, because aerosol passes through the center tube, the temperature of center tube is lower than the first air flue of air flue wall, and then make the aerosol chilled at the center tube, the long-time accumulation easily lead to the condensate reflux of center tube wall to the air flue of cylinder pottery on, and then cause the air flue to block, and the air flue is unobstructed can lead to the respiratory tract to appear when the aerosol is sucked, or lead to sucking to condensate, and the initial temperature when producing is higher in air flue department, the problem that the aerosol that produces when through direct suction air flue department in a large number easily takes place the ironing nozzle, for the user brings bad experience, chinese patent CN 114158776A, set up first atomizing face and the first air flue of the aerosol that the first atomizing face produced, and the second atomizing face produced the second aerosol of transmission, and the second atomizing face set up the condensate reflux to the air flue on the air flue of cylinder pottery, and the air flue that the second atomizing face produced the second atomizing face and the air flue that the condensate produced the second atomizing face, the air flue is the two-time is long-time to be passed through, and the air flue that the problem that the air flue is still is blown up is still is blown down in the air flue is still, and the air flue is still, the air flue is reduced is still to the problem that the air flue is blown down is simultaneously when the air flue is simultaneously is greatly to the air flue is formed to the air flue is simultaneously.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art and provides an atomization assembly, an atomization device and equipment with a main and auxiliary temperature difference air passage, which can effectively reduce the problem that condensate blocks the air passage and aerosol ironing nozzles.

The aim of the utility model is realized by the following technical scheme:

the utility model provides an atomization component with main difference in temperature air flue of assisting, includes the center tube, leads liquid and generates heat the piece, it is in to lead the liquid cover in the center tube, it sets up the air flue to lead in the liquid, it sets up in the air flue to generate heat the piece, medium passageway has been seted up to the center tube, the outer wall of leading the liquid still be used for with through medium passageway's atomizing medium contact, the air flue of seting up in the liquid is atomizing air flue, it with atomizing air flue intercommunication to generate heat the piece, and it establishes or at least part inlay to generate heat the piece lead the liquid in on the inner wall of atomizing air flue, the center tube inner wall is in keeping away from medium passageway's region is provided with the air flue that adjusts the temperature, lead the outer wall of liquid in air flue department that adjusts the temperature is provided with the structure and keeps away the zone.

In one embodiment, the center tube and the liquid guide body are integrally formed.

In one embodiment, the liquid guide penetrates the medium channel, and the liquid guide is embedded on the central pipe wall.

In one embodiment, the temperature of the temperature-adjusting air passage is normal temperature, and the temperature of the atomizing air passage is 160-210 ℃.

In one embodiment, a distance between a side of the heating element, which is close to the outer wall of the central tube, and the outer wall of the liquid guide body is greater than or equal to 0.8cm.

In one embodiment, the atomization assembly with the main and auxiliary temperature difference air passages further comprises a liquid guide cotton body, the liquid guide cotton body is attached to the outer wall of the liquid guide body, the liquid guide cotton body is at least partially clamped between the liquid guide body and the central tube wall, the liquid guide cotton body is communicated with the medium passage, the air passage through holes are formed in the atomization air passages, and the air passage through holes are respectively communicated with the atomization air passages and the central tube.

In one embodiment, the liquid guiding cotton body is provided with a hollowed hole at the structure void area so that the liquid guiding cotton body is communicated with the temperature adjusting air passage.

In one embodiment, the atomization assembly with the main and auxiliary temperature difference air passages further comprises liquid-absorbing cotton, the liquid-absorbing cotton is sleeved in the central tube and is arranged at intervals with the liquid guide body, the liquid-absorbing cotton is provided with aerosol flow holes, the aerosol flow holes are communicated with the atomization air passages, and the liquid-absorbing cotton is arranged at the air-avoiding position of the temperature-adjusting air passages.

In one embodiment, the central tube is provided with a partition plate and a clamping lug avoiding the temperature-adjusting air passage, the partition plate and the clamping lug are connected with the central tube, the partition plate and the clamping lug are connected to form an embedded area, the embedded area is communicated with the temperature-adjusting air passage, and the liquid-absorbing cotton is clamped in the embedded area.

In one embodiment, the heating element comprises a first pin and a heating wire, one end of the first pin is connected with the end of the heating wire, the heating wire is communicated with the atomization air passage, the heating wire is wound on the atomization air passage, the heating wire is attached to or at least partially embedded in the inner wall of the atomization air passage, and the other end of the first pin protrudes out of the liquid guide body.

In one embodiment, the heating element comprises a second pin and a heating piece, one end of the second pin is connected with the heating piece, the heating piece is communicated with the atomization air passage, the heating piece is attached to or at least partially embedded in the inner wall of the atomization air passage, and the other section of the second pin protrudes out of the liquid guide body.

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

the heating piece comprises a first heating part, a second heating part and a conductor part, wherein the first heating part and the second heating part are connected in series through the conductor part, one of the first heating part and the second heating part is connected with the first heating part, the other heating part and the second heating part are connected with the second heating part, the first heating part and the second heating part are communicated with the atomization air passage and are respectively attached to or at least partially embedded in the liquid guide body on the inner wall of the atomization air passage, and the conductor part is at least partially embedded in the end part of the liquid guide body.

The utility model provides an atomizing device with main difference in temperature air flue of assisting, includes atomizing medium storehouse, atomizing seat, suction nozzle and arbitrary embodiment above-mentioned atomizing subassembly with main difference in temperature air flue of assisting, atomizing medium storehouse cup joint in the center tube outer wall, atomizing seat connect in the tip of center tube, just the center tube atomizing medium storehouse with atomizing seat connects and forms atomizing medium storage chamber, the part that generates heat outstanding in the center tube and with atomizing seat connects the electricity, the air inlet has been seted up on the atomizing seat, the air inlet respectively with the air flue that adjusts the temperature communicates, the suction nozzle cover is located atomizing medium storehouse is kept away from the one end of atomizing seat, just the suction nozzle with the center tube intercommunication.

An atomization device with a main and auxiliary temperature difference air passage comprises a battery rod and the atomization device with the main and auxiliary temperature difference air passage according to any embodiment, wherein the battery rod is electrically connected with the atomization seat.

Compared with the prior art, the utility model has at least the following advantages:

the atomization component with the main and auxiliary temperature difference air passages has the advantages that the air passages arranged in the liquid guide body are the atomization air passages, the heating piece is communicated with the atomization air passages, and is attached to or at least partially embedded on the inner wall of the liquid guide body on the atomization air passages, namely, the heating piece directly atomizes an atomization medium led out by the liquid guide body to form aerosol, so that the temperature of the heating piece is about 200 ℃ to realize atomization of the atomization medium, the temperature of the outer wall of the liquid guide body is lower, the inner wall of the central tube is provided with the temperature-regulating air passages in the area avoiding the medium passage, the outer wall of the liquid guide body is provided with the structural void area at the temperature-regulating air passages, namely, the temperature-regulating air passages are formed by the inner wall of the central tube and the outer wall of the liquid guide body, and the temperature of the temperature-regulating air passages is lower, the air flowing out of the atomization air passage is continuously sucked and discharged after being mixed with the air flowing out of the temperature adjusting air passage, and the air flowing out of the temperature adjusting air passage is at normal temperature, so that the temperature of the aerosol can be well reduced when the air is mixed with the aerosol flowing out of the atomization air passage, the suitability of the temperature of the aerosol is ensured, and the problem of mouth scalding during the sucking and discharging of the aerosol is well alleviated; in addition, because the temperature of the air flue that adjusts the temperature is lower than the temperature of the atomizing air flue, and then if there is remaining when not sucking the outflow aerosol in center tube department, the aerosol meets cold and preferential condensation forms the condensate in the air flue department that adjusts the temperature, and then make the condensate gather more in the air flue department that adjusts the temperature, and then alleviateed the problem that the condensate blocks the atomizing air flue better, improved user's experience effectively and felt, and further, because the air flue part lateral wall that adjusts the temperature is the liquid guide, and then make the condensate of atomizing medium further be guided out again in the air flue department that adjusts the temperature and utilized, improved the utilization ratio of atomizing medium betterly.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present utility model and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an atomization assembly with a primary and secondary temperature differential air passage according to an embodiment of the present utility model;

FIG. 2 is another schematic illustration of the atomizing assembly of FIG. 1 with primary and secondary temperature differential air passages;

FIG. 3 is a cross-sectional view of the atomizing assembly shown in FIG. 1 with a primary and secondary differential temperature air passage;

FIG. 4 is another cross-sectional view of the atomizing assembly of FIG. 1 with a primary and secondary differential temperature air passage;

FIG. 5 is an exploded view of the atomizing assembly of FIG. 1 with a primary and secondary differential temperature air passage;

FIG. 6 is an exploded view of an atomizing assembly having a primary and secondary differential temperature air passage according to another embodiment of the present utility model;

FIG. 7 is a cross-sectional view of the atomizing assembly shown in FIG. 6 with a primary and secondary differential temperature air passage;

FIG. 8 is a partial view of the atomizing assembly of FIG. 6 with primary and secondary differential temperature air passages;

FIG. 9 is a schematic diagram of an atomizing assembly with a primary and secondary differential temperature air passage according to yet another embodiment of the present utility model;

FIG. 10 is an exploded view of the atomizing assembly of FIG. 9 with primary and secondary temperature differential airways;

FIG. 11 is a schematic structural view of an atomizing assembly with a primary and secondary differential temperature air passage according to yet another embodiment of the present utility model;

fig. 12 is an exploded view of the atomizing assembly of fig. 11 with primary and secondary temperature differential airways.

FIG. 13 is a partial view of the atomizing assembly of FIG. 11 with primary and secondary differential temperature air passages;

fig. 14 is a cross-sectional view of the atomizing assembly of fig. 13 with primary and secondary temperature differential airways.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the utility model. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The application provides an atomization assembly with main and auxiliary temperature difference air passages. Foretell atomization component with main and auxiliary difference in temperature air flue includes the center tube, lead liquid and generate heat the piece, lead the liquid cover and put in the center tube, lead the liquid in seted up the air flue, it sets up in the air flue to generate heat the piece, medium passageway has been seted up to the center tube, the outer wall of leading the liquid still is used for contacting with the atomizing medium through medium passageway, the air flue of seting up in the liquid is atomizing air flue, it communicates with atomizing air flue to generate heat the piece, and it pastes to establish or at least partly inlay to lead the liquid on the inner wall of atomizing air flue to generate heat, the center tube inner wall is provided with the air flue that adjusts the temperature in the region of avoiding medium passageway, the outer wall of leading the liquid is provided with the structure in air flue department that adjusts the temperature and keeps away the sky.

The atomization component with the main temperature difference air passage and the auxiliary temperature difference air passage has the advantages that the air passage arranged in the liquid guide body is the atomization air passage, the heating piece is communicated with the atomization air passage, and is attached to or at least partially embedded on the inner wall of the atomization air passage, namely, the heating piece directly atomizes an atomization medium led out by the liquid guide body to form aerosol, so that the temperature of the heating piece is about 200 ℃, the atomization of the atomization medium can be realized, the temperature of the outer wall of the liquid guide body is lower, the inner wall of the central tube is provided with the temperature-regulating air passage in the area avoiding the medium passage, the outer wall of the liquid guide body is provided with the structural void area at the temperature-regulating air passage, namely, the temperature-regulating air passage is formed by the inner wall of the central tube and the outer wall of the liquid guide body, and the temperature of the temperature-regulating air passage is lower, the air flowing out of the atomization air passage is continuously sucked and discharged after being mixed with the air flowing out of the temperature adjusting air passage, and the air flowing out of the temperature adjusting air passage is at normal temperature, so that the temperature of the aerosol can be well reduced when the air is mixed with the aerosol flowing out of the atomization air passage, the suitability of the temperature of the aerosol is ensured, and the problem of mouth scalding during the sucking and discharging of the aerosol is well alleviated; in addition, because the temperature of the air flue that adjusts the temperature is lower than the temperature of the atomizing air flue, and then if there is remaining when not sucking the outflow aerosol in center tube department, the aerosol meets cold and preferential condensation forms the condensate in the air flue department that adjusts the temperature, and then make the condensate gather more in the air flue department that adjusts the temperature, and then alleviateed the problem that the condensate blocks the atomizing air flue better, improved user's experience effectively and felt, and further, because the air flue part lateral wall that adjusts the temperature is the liquid guide, and then make the condensate of atomizing medium further be guided out again in the air flue department that adjusts the temperature and utilized, improved the utilization ratio of atomizing medium betterly.

The normal temperature refers to the temperature of air in the environment using the atomizing assembly having the main and auxiliary temperature difference air passages, that is, the normal temperature is typically-10 to 40 ℃ as the temperature of air in the environment of the atomizing assembly having the main and auxiliary temperature difference air passages changes.

For better understanding of the atomization assembly with the main and auxiliary temperature difference air passages, the atomization assembly with the main and auxiliary temperature difference air passages is further explained below:

referring to fig. 1 to 5, an atomization assembly 10 with a main and auxiliary temperature difference air passage according to an embodiment includes a central tube 100, a liquid guide 200 and a heating element 300, wherein the liquid guide 200 is sleeved in the central tube 100, the liquid guide 200 is provided with an air passage, the heating element 300 is disposed in the air passage, the central tube 100 is provided with a medium passage 101, an outer wall of the liquid guide 200 is further used for contacting with an atomized medium passing through the medium passage 101, the air passage provided in the liquid guide 200 is an atomized air passage 201, the heating element 300 is communicated with the atomized air passage 201, the heating element 300 is attached to or at least partially embedded in the liquid guide 200 on an inner wall of the atomized air passage 201, a temperature adjusting air passage 202 is disposed on an area of the inner wall of the central tube 100, and a structural air-shielding area 203 is disposed on the outer wall of the liquid guide 200 at the temperature adjusting air passage 202.

In the above atomization assembly 10 with the main and auxiliary temperature difference air passages, the air passage formed in the liquid guide 200 is the atomization air passage 201, the heating element 300 is communicated with the atomization air passage 201, and the heating element 300 is attached to or at least partially embedded in the inner wall of the atomization air passage 201 of the liquid guide 200, that is, the heating element 300 directly atomizes the atomization medium led out of the liquid guide 200 to form aerosol, so that the temperature of the heating element 300 can be atomized at about 200 ℃, further, the temperature of the outer wall of the liquid guide 200 is lower, the inner wall of the central tube 100 is provided with the temperature adjusting air passage 202 in the area of the medium passage 101, the outer wall of the liquid guide 200 is provided with the structure air-avoiding area 203 at the temperature adjusting air passage 202, that is, the temperature adjusting air passage 202 is formed by the inner wall of the central tube 100 and the outer wall of the liquid guide 200, so that the temperature of the temperature adjusting air passage 202 is lower, and can be considered to be at normal temperature, and the same, and the aerosol formed at the position of the atomizing air passage 201 directly flows out of the other end of the air passage 201 through the aerosol directly driven by the air entering from the atomization air passage 201, so that the temperature adjusting element 300 flows out of the other end of the atomizing air passage 201, and the aerosol flows out of the end of the air passage is only when the aerosol flowing from one end to the end of the atomizing air passage 201 is mixed with the aerosol at the aerosol, and the temperature of the aerosol is well mixed with the aerosol flowing from the air passage 201, and the aerosol flowing at the temperature of the aerosol is further, and the temperature is well mixed with the aerosol flowing at the temperature of the air passage is well when the aerosol flowing at the temperature is well, and the temperature is well when the temperature is well is sucked, and the temperature is lower, and the temperature is further, and the temperature is mixed with the aerosol is at the temperature; in addition, because the temperature of the temperature adjusting air passage 202 is lower than that of the atomizing air passage 201, if residual aerosol which is not sucked out is positioned at the central tube 100, the aerosol is cooled at the temperature adjusting air passage 202 and is condensed preferentially to form condensate, so that the condensate is more gathered at the temperature adjusting air passage 202, the problem that the condensate blocks the atomizing air passage 201 is better solved, the experience of a user is effectively improved, and further, because part of the side wall of the temperature adjusting air passage 202 is the liquid guide 200, the condensate of an atomizing medium can be further led out again for use at the temperature adjusting air passage 202, and the utilization rate of the atomizing medium is better improved.

In one embodiment, the central tube and the liquid guide are of an integrally formed structure. It can be understood that the central tube and the liquid guide body are of an integrated structure, so that the connection stability and connection compactness of the central tube and the liquid guide body are improved well, the structural stability and the structural compactness of the atomization assembly with the main and auxiliary temperature difference air passages are guaranteed well, the processing procedures of the atomization assembly with the main and auxiliary temperature difference air passages are reduced, and the processing efficiency of the atomization assembly with the main and auxiliary temperature difference air passages is improved well.

Referring to fig. 1 and fig. 9 together, in one embodiment, the liquid guide 200 penetrates through the medium channel 101, and the liquid guide 200 is embedded in the wall of the central tube 100, so that the tightness and stability of the blocking of the medium channel 101 by the liquid guide 200 are better ensured, and the leakage problem of the atomized medium of the atomizing assembly 10 with the main and auxiliary temperature difference air channels is better alleviated.

In one embodiment, the temperature of the tempering air passage is normal temperature. Further, the temperature of the atomizing air passage is 160-210 ℃. It is understood that the temperature of the temperature-adjusting air passage is controlled to be normal temperature. Further, the temperature of the atomization air passage is 160-210 ℃, so that the regulation effect of air flowing out of the temperature regulating air passage on the temperature of aerosol flowing out of the atomization air passage is better ensured, and further, the problem of nozzle scalding during the suction and outflow of the aerosol is better ensured.

In one embodiment, the distance between the side of the heating element, which is close to the outer wall of the central tube, and the outer wall of the liquid guide body is greater than or equal to 0.8cm. It can be understood that the distance between one side of the heating element, which is close to the outer wall of the central tube, and the outer wall of the central tube is greater than or equal to 0.8cm, so that the temperature of the heating element has only small influence on the temperature of the outer side wall of the liquid guide body, namely, the heating element does not cause the temperature of the outer side wall of the liquid guide body to rise, or the rising degree is considered to be very low, the regulation effect of the air flowing out of the temperature-regulating air passage on the temperature of the aerosol flowing out of the atomizing air passage is further better ensured, and the problem of nozzle scalding during the suction and outflow of the aerosol is further better ensured.

Referring to fig. 6 to 8 together with fig. 12, in one embodiment, the atomization assembly 10 with the 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 body 200, and the liquid guiding cotton body 400 is at least partially sandwiched between the liquid guiding body 200 and the wall of the central tube 100, and the liquid guiding cotton body 400 is communicated with the medium channel 101, the liquid guiding cotton body 400 is provided with an air channel through hole 401 at the position of the atomization air channel 201, and the air channel through hole 401 is respectively communicated with the atomization air channel 201 and the central tube 100. It can be understood that the liquid guiding cotton body 400 is attached to the outer wall of the liquid guiding body 200, and the liquid guiding cotton body 400 is at least partially clamped between the liquid guiding body 200 and the wall of the central tube 100, and the liquid guiding cotton body 400 is communicated with the medium channel 101, the liquid guiding cotton body 400 is provided with an air channel through hole 401 at the position of the atomization air channel 201, the air channel through hole 401 is respectively communicated with the atomization air channel 201 and the central tube 100, the liquid guiding body 200 is better assisted to effectively seal the medium channel 101, and the leakage problem of the atomization medium of the atomization assembly 10 with the main and auxiliary temperature difference air channels is further effectively reduced.

Referring to fig. 6, 8, 9 and 12, in one embodiment, the liquid guiding cotton body 400 is provided with a hollow hole 402 at the structure shielding area 203, so that the liquid guiding 200 is communicated with the temperature adjusting air passage 202, and the liquid guiding cotton can be rapidly assembled on the surface of the liquid guiding 200, thereby improving the assembly efficiency of the atomization assembly 10 with the main and auxiliary temperature difference air passages.

Referring to fig. 3 to 5, fig. 6, fig. 7 and fig. 12, in one embodiment, the atomization assembly 10 with the main and auxiliary temperature difference air channels further includes a liquid-absorbing cotton 500, the liquid-absorbing cotton 500 is sleeved in the central tube 100, the liquid-absorbing cotton 500 and the liquid guide 200 are arranged at intervals, the liquid-absorbing cotton 500 is provided with an aerosol flow hole 501, the aerosol flow hole is communicated with the atomization air channel 201, and the liquid-absorbing cotton 500 is arranged at the temperature adjustment air channel 202 in a clearance manner. It can be understood that when the temperature adjusting air passage 202 with a lower temperature than the atomizing air passage 201 is matched with the atomizing air passage 201, the aerosol is caused to be cooled to form condensate at the temperature adjusting air passage 202 preferentially, the problem that the condensate blocks the atomizing air passage 201 is well solved, but in this case, the condensate is still formed by condensing the aerosol part at the position of the central tube 100 corresponding to the atomizing air passage 201 and flows back to the atomizing air passage 201, and further, the problem that the condensate blocks the atomizing air passage 201 is still present when the aerosol is used for a longer time is solved, therefore, in the application, the liquid absorbing cotton 500 is sleeved in the central tube 100, the liquid absorbing cotton 500 is arranged at intervals with the liquid guiding 200, and the liquid absorbing cotton 500 is provided with the aerosol flowing through hole 501, the aerosol flowing through hole is communicated with the atomizing air passage 201, namely, the aerosol flows out of the liquid absorbing cotton 500, and the air flowing out of the temperature adjusting air passage 202 is synchronously formed by condensing the condensate at the position of the atomizing air passage 201, and the aerosol is mixed at the position of the aerosol cotton, and the residual condensate is preferably not sucked on the wall of the liquid absorbing cotton 500 to form condensate, and the condensate is absorbed by the liquid absorbing cotton 500 better, and the condensate absorbing medium is formed in the liquid absorbing cotton is better.

Referring to fig. 3 to fig. 5 and fig. 7, in one embodiment, a partition plate 110 and a clamping protrusion 120 are disposed in the central tube 100 to avoid the temperature-adjusting air passage 202, the partition plate 110 and the clamping protrusion 120 are connected to the central tube 100, the partition plate 110 and the clamping protrusion 120 are connected to form a embedding region 102, the embedding region 102 is communicated with the temperature-adjusting air passage 202, and the liquid-absorbing cotton 500 is clamped at the embedding region 102. It can be understood that, if the shape stability of the cotton body with better lotion capability is poor, if the liquid-absorbing cotton 500 is processed to form the structures of the air-avoiding air-conditioning air channel 202 and the atomization air channel 201, that is, in the process of absorbing condensate by the liquid-absorbing cotton 500, the liquid-absorbing cotton 500 expands to influence the smoothness of the temperature-adjusting air channel 202 and the atomization air channel 201, and even the liquid-absorbing cotton 500 blocks the temperature-adjusting air channel 202 or the atomization air channel 201, in the application, the partition 110 and the clamping convex block 120 are connected to form the embedded area 102, the embedded area 102 is communicated with the temperature-adjusting air channel 202, and the liquid-absorbing cotton 500 is clamped at the embedded area 102, so that the structures of the air-avoiding air-conditioning air channel 202 and the atomization air channel 201 are formed on the central tube 100, not only effectively avoiding the problems that the liquid-absorbing cotton 500 is deformed to influence the smoothness or even the blockage of the temperature-adjusting air channel 202 and the atomization air channel 201, but also effectively improving the assembly stability and the positioning and the installation accuracy of the liquid-absorbing cotton 500, and further better ensuring the smoothness of the temperature-adjusting air channel 202, and better ensuring the effective absorption of the liquid-absorbing cotton 500 to condensate.

Referring to fig. 1 and fig. 3 to fig. 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 an end of the heating wire 320, the heating wire 320 is communicated with the atomizing air channel 201, the heating wire 320 is wound on the atomizing air channel 201, the heating wire 320 is attached to or at least partially embedded in the inner wall of the atomizing air channel 201 of the liquid guide 200, and the other end of the first pin 310 protrudes out of the liquid guide 200.

Referring to fig. 9 to 14, in one embodiment, the heat generating component 300 includes a second pin 330 and a heat generating piece 340, one end of the second pin 330 is connected to the heat generating piece 340, the heat generating piece 340 is communicated with the atomizing air channel 201, the heat generating piece 340 is attached to or at least partially embedded in the inner wall of the atomizing air channel 201 of the liquid guide 200, and the other end of the second pin 330 protrudes out of the liquid guide 200.

Referring to fig. 9 to 14, in one embodiment, the number of the second pins 330 is two. Further, the heat generating piece 340 includes a first heat generating portion 341, a second heat generating portion 342 and a conductor portion 343, the first heat generating portion 341 and the second heat generating portion 342 are connected in series through the conductor portion 343, one second lead 330 is connected with the first heat generating portion 341, the other second lead 330 is connected with the second heat generating portion 342, the first heat generating portion 341 and the second heat generating portion 342 are both communicated with the atomization air channel 201 and are both attached to or at least partially embedded in the inner wall of the atomization air channel 201, and the conductor portion 343 is at least partially embedded in the end portion of the liquid guide 200.

In one embodiment, the tempering air passage is a vortex type spiral air passage. It can be understood that the vortex type spiral air passage is a spiral air passage capable of generating vortex, although the mixing speed of air is higher, the flow speed of the whole air flow is very fast when a user sucks the aerosol formed by atomization, if the air flowing out of the temperature adjusting air passage cannot be quickly mixed with the aerosol flowing out of the atomization air passage, even if the air mixing is realized, the mixing speed of the air flowing out of the temperature adjusting air passage and the aerosol flowing out of the atomization air passage is still lower than the sucking speed, and therefore the temperature of the aerosol is difficult to be fully adjusted to a better somatosensory temperature, and when the temperature of a heating piece is higher and the temperature of the aerosol is promoted to be higher, still can have the problem that suction aerosol was scalded the mouth, therefore, in this application, make the air flue that adjusts temperature be the heliciform air flue, even make the air that gets into the air flue that adjusts temperature then can take place the vortex phenomenon, and then have great diffusion power when making the air flow out the air flue that adjusts temperature, the quick mixing takes place with the aerosol that the atomizing air flue flows out more easily, and then guaranteed the quick decline of the temperature of aerosol better, guaranteed the air that flows out the air flue that adjusts temperature and the speed that the aerosol that flows out the atomizing air flue overtaken the speed of sucking, and then the problem that the mouth was scalded and influence user's experience when having alleviateed the suction aerosol better.

In one embodiment, the heater is fully embedded in the liquid guide.

Referring to fig. 9, 13 and 14, in one embodiment, the atomizing air passage 201 includes an oil blocking section 2012 and an atomizing section 2011 that are connected end to end, the heating element 300 is disposed in the atomizing section 2011, and a sidewall of the atomizing section 2011 is located at an outer periphery of a sidewall of the oil blocking section 2012 at a connection position between the oil blocking section 2012 and the atomizing section 2011. It can be appreciated that, make the atomizing air flue 201 include the oil blocking section 2012 that the head and the tail are connected and the atomizing section 2011, and a structure is simple, further in the intercommunication department that blocks oil section 2012 and atomizing section 2011, the area that the lateral wall of atomizing section 2011 encloses contains the area that the lateral wall that blocks oil section 2012 encloses, and under the same length, the volume of atomizing section 2011 is greater than the volume that blocks oil section 2012, make the oil blocking section 2012 that the atomizing air flue 201 is close to the one end of atomizing section 2011 have the effect of blocking to the atomizing medium granule that atomizing section 2011 produced when frying oil better, and still be located on the liquid guide 200 in the atomizing medium granule that blocks oil blocking section 2012, and then can be guided into by liquid guide 200 and form aerosol by the atomizing of heating element 300 again, namely under the simple structure's of the atomizing subassembly 10 that has guaranteed the main and auxiliary temperature difference air flue, the problem that the experience that the frying oil brought is relatively poor for the user has been alleviateed.

The application also provides an atomization device with the main and auxiliary temperature difference air passages. The above-mentioned atomizing device with main difference in temperature air flue that assists includes atomizing medium storehouse, atomizing seat, suction nozzle and the atomizing subassembly that has main difference in temperature air flue that assists of any embodiment of the aforesaid, atomizing medium storehouse cup joints in the center tube outer wall, atomizing seat connects in the tip of center tube, and center tube, atomizing medium storehouse and atomizing seat are connected and are formed atomizing medium and store the chamber, the part that generates heat is outstanding in the center tube and is connected with atomizing seat electricity, the air inlet has been seted up on the atomizing seat, the air inlet communicates with atomizing air flue and air flue that adjusts temperature respectively, the suction nozzle cover is located atomizing medium storehouse and is kept away from the one end of atomizing seat, and suction nozzle and center tube intercommunication. Further, referring to fig. 1 to 5, the atomization assembly 10 with the main and auxiliary temperature difference air passages includes a central tube 100, a liquid guide 200 and a heating element 300, wherein the liquid guide 200 is sleeved in the central tube 100, the liquid guide 200 is provided with an air passage, the heating element 300 is arranged in the air passage, the central tube 100 is provided with a medium passage 101, the outer wall of the liquid guide 200 is also used for contacting with an atomized medium passing through the medium passage 101, the air passage provided in the liquid guide 200 is an atomized air passage 201, the heating element 300 is communicated with the atomized air passage 201, the heating element 300 is attached to or at least partially embedded in the liquid guide 200 on the inner wall of the atomized air passage 201, a temperature adjusting air passage 202 is arranged on the inner wall of the central tube 100 in a region avoiding the medium passage 101, and a structural air-avoiding area 203 is arranged on the outer wall of the liquid guide 200 at the temperature adjusting air passage 202.

The atomization device with the main and auxiliary temperature difference air passages adopts the atomization assembly with the main and auxiliary temperature difference air passages, so that the suitability of the temperature of aerosol is well ensured, the problem of mouth scalding during the suction and outflow of the aerosol is well solved, the problem of condensate blocking the atomization air passages is well solved, and the experience of a user is effectively improved.

The application also provides an atomization device with the main and auxiliary temperature difference air passages. The atomizing equipment with the main and auxiliary temperature difference air passages comprises a battery rod and an atomizing device with the main and auxiliary temperature difference air passages, wherein the battery rod is electrically connected with the atomizing seat. Further, the atomizing device with main and auxiliary temperature difference air passages comprises an atomizing medium bin, an atomizing seat, a suction nozzle and an atomizing assembly with the main and auxiliary temperature difference air passages in any one of the embodiments, wherein the atomizing medium bin is sleeved on the outer wall of the central tube, the atomizing seat is connected to the end part of the central tube, the atomizing medium bin and the atomizing seat are connected to form an atomizing medium storage cavity, the heating part protrudes out of the central tube and is electrically connected with the atomizing seat, an air inlet is formed in the atomizing seat and is respectively communicated with the atomizing air passages and the temperature adjustment air passages, the suction nozzle is sleeved at one end of the atomizing medium bin, which is far away from the atomizing seat, and the suction nozzle is communicated with the central tube.

The atomizing equipment with the main and auxiliary temperature difference air passages adopts the atomizing device with the main and auxiliary temperature difference air passages, so that the suitability of the temperature of aerosol is better ensured, the problem of mouth scalding during the suction and outflow of the aerosol is better solved, the problem of condensate blocking the atomizing air passages is better solved, and the experience of a user is effectively improved.

Compared with the prior art, the utility model has at least the following advantages:

the atomization component 10 with the main and auxiliary temperature difference air passages of the utility model is characterized in that the air passage arranged in the liquid guide 200 is an atomization air passage 201, the heating element 300 is communicated with the atomization air passage 201, and the heating element 300 is attached to or at least partially embedded on the inner wall of the atomization air passage 201 of the liquid guide 200, namely, the heating element 300 forms aerosol for directly atomizing an atomization medium led out of the liquid guide 200, so that the temperature of the heating element 300 is about 200 ℃ to realize atomization of the atomization medium, further, the temperature of the outer wall of the liquid guide 200 is lower, the inner wall of the central tube 100 is provided with a temperature adjusting air passage 202 in a region avoiding the medium passage 101, the outer wall of the liquid guide 200 is provided with a structural air-avoiding area 203 at the temperature adjusting air passage 202, namely, the temperature adjusting air passage 202 is formed by the inner wall of the central tube 100 and the outer wall of the liquid guide 200, therefore, the temperature of the temperature adjusting air passage 202 is lower, the temperature is equal to the normal temperature, the aerosol formed by the heating element 300 at the atomizing air passage 201 is directly driven by the air entering from the atomizing air passage 201 to flow out from the other end of the atomizing air passage 201, the temperature adjusting air passage 202 is that only the air flows from one end to the other end and then is mixed with the aerosol flowing out of the atomizing air passage 201, the aerosol flowing out of the atomizing air passage 201 is continuously sucked and flows out after being mixed with the air flowing out of the temperature adjusting air passage 202, and the temperature of the aerosol can be well reduced when the air flowing out of the temperature adjusting air passage 202 is equal to the normal temperature, so that the temperature suitability of the aerosol is ensured, and the problem of mouth scalding when the aerosol is sucked and flows out is well relieved; in addition, because the temperature of the temperature adjusting air passage 202 is lower than that of the atomizing air passage 201, if residual aerosol which is not sucked out is positioned at the central tube 100, the aerosol is cooled at the temperature adjusting air passage 202 and is condensed preferentially to form condensate, so that the condensate is more gathered at the temperature adjusting air passage 202, the problem that the condensate blocks the atomizing air passage 201 is better solved, the experience of a user is effectively improved, and further, because part of the side wall of the temperature adjusting air passage 202 is the liquid guide 200, the condensate of an atomizing medium can be further led out again for use at the temperature adjusting air passage 202, and the utilization rate of the atomizing medium is better improved.

The above examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (11)

1. The utility model provides an atomizing subassembly with main difference in temperature air flue of assisting, includes the center tube, leads liquid and generates heat the piece, it is in to lead the liquid cover in the center tube, it sets up the air flue to lead in the liquid, it sets up in the air flue to generate heat the piece, medium passageway has been seted up to the center tube, the outer wall of leading the liquid still be used for with passing through medium passageway's atomizing medium contact, its characterized in that, the air flue of seting up in the liquid is atomizing air flue, it with atomizing air flue intercommunication to generate heat the piece, and it pastes to generate heat the piece establish or at least partly inlay in lead the liquid in on the inner wall of atomizing air flue, the center tube inner wall is in keeping away the regional temperature air flue that is provided with of medium passageway, lead the outer wall of liquid in temperature air flue department is provided with the structure and keeps away the air flue.

2. The atomizing assembly with a primary and secondary differential temperature air passage of claim 1, wherein the center tube is of unitary construction with the liquid conduit; and/or the number of the groups of groups,

the liquid guide penetrates through the medium channel, and is embedded on the central pipe wall; and/or the number of the groups of groups,

the temperature of the temperature-regulating air passage is normal temperature, and the temperature of the atomizing air passage is 160-210 ℃; and/or the number of the groups of groups,

the distance between one side of the heating element, which is close to the outer wall of the central tube, and the outer wall of the liquid guide body is more than or equal to 0.8cm.

3. The atomizing assembly with the main and auxiliary temperature difference air passages according to claim 1, wherein the atomizing assembly with the main and auxiliary temperature difference air passages further comprises a liquid guiding cotton body, the liquid guiding cotton body is attached to the outer wall of the liquid guiding body, the liquid guiding cotton body is at least partially clamped between the liquid guiding body and the central pipe wall, the liquid guiding cotton body is communicated with the medium passage, an air passage through hole is formed in the atomizing air passage, and the air passage through hole is respectively communicated with the atomizing air passage and the central pipe.

4. The atomizing assembly with the main and auxiliary temperature difference air passages according to claim 3, wherein the liquid guiding cotton body is provided with hollowed-out holes at the structure clearance area so that the liquid guiding cotton body is communicated with the temperature adjusting air passages.

5. The atomizing assembly with the main and auxiliary temperature difference air passages according to claim 1, further comprising liquid-absorbing cotton, wherein the liquid-absorbing cotton is sleeved in the central tube and is arranged at intervals with the liquid guide body, the liquid-absorbing cotton is provided with aerosol flow holes, the aerosol flow holes are communicated with the atomizing air passages, and the liquid-absorbing cotton is arranged at the temperature-adjusting air passages in a clearance-avoiding mode.

6. The atomizing assembly with the main and auxiliary temperature difference air passages according to claim 5, wherein a partition plate and a clamping lug are arranged in the central tube avoiding the temperature adjustment air passages, the partition plate and the clamping lug are connected with the central tube, a embedding area is formed by connecting the partition plate and the clamping lug, the embedding area is communicated with the temperature adjustment air passages, and the liquid absorbing cotton is clamped at the embedding area.

7. The atomizing assembly with the main and auxiliary temperature difference air passages according to claim 1, wherein the heating element comprises a first pin and a heating wire, one end of the first pin is connected with the end part of the heating wire, the heating wire is communicated with the atomizing air passages, the heating wire is wound on the atomizing air passages, the heating wire is attached to or at least partially embedded in the inner wall of the atomizing air passages, and the other end of the first pin protrudes out of the liquid guide.

8. The atomizing assembly with the main and auxiliary temperature difference air passages according to claim 1, wherein the heating piece comprises a second pin and a heating piece, one end of the second pin is connected with the heating piece, the heating piece is communicated with the atomizing air passages, the heating piece is attached to or at least partially embedded in the liquid guide body on the inner wall of the atomizing air passages, and the other section of the second pin protrudes out of the liquid guide body.

9. The atomizing assembly with a primary and secondary differential temperature air passage of claim 8, wherein the number of second pins is two;

the heating piece comprises a first heating part, a second heating part and a conductor part, wherein the first heating part and the second heating part are connected in series through the conductor part, one of the first heating part and the second heating part is connected with the first heating part, the other heating part and the second heating part are connected with the second heating part, the first heating part and the second heating part are communicated with the atomization air passage and are respectively attached to or at least partially embedded in the liquid guide body on the inner wall of the atomization air passage, and the conductor part is at least partially embedded in the end part of the liquid guide body.

10. An atomizing device with main and auxiliary temperature difference air passages is characterized by comprising an atomizing medium bin, an atomizing seat, a suction nozzle and the atomizing assembly with the main and auxiliary temperature difference air passages according to any one of claims 1 to 9, wherein the atomizing medium bin is sleeved on the outer wall of the central tube, the atomizing seat is connected with the end part of the central tube, the atomizing medium bin and the atomizing seat are connected to form an atomizing medium storage cavity, the heating part protrudes out of the central tube and is electrically connected with the atomizing seat, an air inlet is formed in the atomizing seat, the air inlet is respectively communicated with the atomizing air passages and the temperature adjusting air passages, and the suction nozzle is sleeved on one end of the atomizing medium bin, which is far away from the atomizing seat, and is communicated with the central tube.

11. An atomizing device with a main and auxiliary temperature difference air passage, which is characterized by comprising a battery rod and the atomizing device with the main and auxiliary temperature difference air passage as claimed in claim 10, wherein the battery rod is electrically connected with the atomizing base.