CN106418729B - Atomizer external member - Google Patents

Abstract

The invention provides an atomizer kit, which comprises an atomizer body, wherein a containing cavity, an oil storage cavity, an atomizing cavity and a heating component are arranged in the atomizer body, the atomizer body and a suction nozzle component are matched to form an atomizer, the containing cavity is used for containing tobacco and is used as a first smoke channel, the heating component is used for atomizing tobacco tar in the oil storage cavity to form smoke, and the smoke atomized in the atomizing cavity is used for heating the tobacco in the containing cavity to generate mixed smoke, so that the mixed smoke flows to the suction nozzle component through the first smoke channel when smoking. The tobacco is not required to be baked by the electric heating device, so that the aromatic flavor of the tobacco in the accommodating cavity can be uniformly heated and fully evaporated, the smoke amount is large, and the problem that more harmful substances are still generated due to easy carbonization when the tobacco is baked by the electric heating device in the prior art is avoided.

Description

Atomizer external member

Technical Field

The invention relates to the field of electronic cigarettes, in particular to an atomizer kit.

Background

Traditional smoking is by igniting tobacco with an open flame, which burns to produce smoke for the smoker to smoke. Smoke generated by burning tobacco typically contains thousands of harmful substances, and thus, conventional tobacco causes serious respiratory diseases to smokers and tends to cause second-hand smoke hazard.

In order to solve the technical problem that more harmful substances are generated by traditional tobacco combustion, technicians develop an atomized electronic cigarette and an electronic flue-cured tobacco, however, the atomized electronic cigarette forms smog through atomized tobacco liquid so as to be smoked by smokers, and the atomized electronic cigarette overcomes the defects of the traditional cigarette and can meet the dependence of consumers on tobacco to a certain extent, but the tobacco liquid of the electronic cigarette is prepared by essence and spice, is not a real cigarette product, has light smoke taste and lacks the fragrance of tobacco, and cannot be widely accepted by the consumers. The existing low-temperature electronic flue-cured tobacco adopts a low-temperature (about 100 ℃) non-combustion mode to heat tobacco shreds, and the heating temperature is low, so that the harmful substances generated by heating are less, but the smoke quantity is obviously insufficient. When the tobacco is heated at a high temperature, the tobacco is easily blackened and carbonized, and the heat distribution is uneven, so that the problem that part of the tobacco is carbonized and the other part of the tobacco is insufficient in temperature is easily generated, and more harmful substances are also generated. How to suck out the aromatic flavor of tobacco and reduce harmful substances to a great extent has become a problem to be solved urgently in the tobacco industry.

Disclosure of Invention

The invention provides an atomizer kit capable of greatly reducing harmful substances of tobacco sucked by a user.

The invention provides an atomizer kit, which is used for being connected and matched with a suction nozzle assembly to form an atomizer, and comprises an atomizer main body, wherein a connecting column or a connecting groove used for being detachably connected with the suction nozzle assembly is arranged at the first end of the atomizer main body, an electrode assembly used for being electrically connected with an external power supply is arranged at the second end of the atomizer main body, a containing cavity, an oil storage cavity, an atomizing cavity and a heating assembly used for atomizing tobacco tar to form smoke are arranged in the atomizer main body, when the suction nozzle assembly is connected with the atomizer main body, the containing cavity is communicated with the atomizing cavity and the suction nozzle assembly, the containing cavity is used for containing tobacco and is used as a first smoke channel, the heating assembly is arranged in the atomizing cavity and used for atomizing the tobacco tar in the oil storage cavity to form smoke, and the smoke formed in the atomizing cavity is used for heating the tobacco in the containing cavity to generate mixed smoke, so that when the mixed smoke flows to the suction nozzle assembly through the first smoke channel.

Optionally, a second smoke channel is further provided in the atomizer body, the second smoke channel is in communication with the suction nozzle assembly and the atomizing cavity, and the second smoke channel is used for shunting part of smoke in the atomizing cavity and guiding the part of smoke into the suction nozzle assembly.

Optionally, the cavity wall department that holds the chamber is sunken to be formed with along hold the ventilation groove that the longitudinal extension in chamber set up, the one end of ventilation groove with the atomizing chamber is linked together, when atomizer main part is connected with the suction nozzle subassembly, the other end of ventilation groove with the suction nozzle subassembly is linked together.

Optionally, one end of the first cavity mouth of holding the chamber back to holding the chamber is provided with and is used for stopping tobacco is kept away from first cavity mouth direction motion limiting plate, hold the first cavity mouth of chamber for hold the chamber and be close to the cavity mouth of atomizing chamber, limiting plate face the one side of suction nozzle subassembly be provided with hold the coaxial third smog passageway that sets up of chamber, the one end of third smog passageway with hold the chamber and be linked together, the other end of third smog passageway with suction nozzle subassembly is linked together.

Optionally, a partition board for blocking the tobacco in the accommodating cavity from moving towards the atomizing cavity is arranged between the atomizing cavity and the accommodating cavity, and at least one perforation is arranged on the partition board and is communicated with the accommodating cavity and the atomizing cavity.

Optionally, the partition plate is disposed in the accommodating cavity and detachably connected with a groove wall of the accommodating cavity, so that the partition plate can be taken out from the accommodating cavity after the suction nozzle assembly is detached.

Optionally, the baffle is the disc, the baffle orientation hold the cell wall in chamber and be provided with the annular groove, just the opening direction of annular groove with hold the cell wall in chamber and set up relatively, the annular groove is inside to be provided with the elastic component, just the elastic component supports to hold and sets up the annular groove with hold between the cell wall in chamber.

Optionally, a second cavity opening is provided in the direction of the accommodating cavity facing the suction nozzle assembly, the second cavity opening of the accommodating cavity is a cavity opening of the accommodating cavity away from the atomizing cavity, when the suction nozzle assembly is separated from the atomizer body, the tobacco can be inserted into the accommodating cavity from the second cavity opening or taken out from the accommodating cavity from the second cavity opening, and a limiting mechanism for blocking the tobacco to move in a direction away from the accommodating cavity is provided in the direction of the second cavity opening.

Optionally, the limiting mechanism is a limiting step arranged around the cavity wall of the accommodating cavity.

Optionally, the accommodating cavity is further provided with a filter screen covering the second cavity opening of the accommodating cavity, and the filter screen is used for blocking tobacco in the accommodating cavity from entering the suction nozzle assembly.

Optionally, the atomizer main body comprises an oil storage component and an atomization core component inserted in the oil storage component, and the oil storage cavity is formed in the oil storage component; the atomizing core component comprises an atomizing sleeve, a tobacco tar adsorption sleeve, an electric heating wire, an upper insulating ring and an upper electrode, wherein an oil inlet communicated with the oil storage cavity is formed in the pipe wall of the atomizing sleeve, the tobacco tar adsorption sleeve is sleeved in the atomizing sleeve and covers the oil inlet, the electric heating wire is used as the heating component, the electric heating wire is wound into a spiral shape and is at least partially sleeved in the tobacco tar adsorption sleeve so as to atomize tobacco tar in the tobacco tar adsorption sleeve, the atomizing cavity is formed in the tobacco tar adsorption sleeve, the insulating ring is sleeved in one end of the atomizing sleeve, the upper electrode is sleeved in the insulating ring, one end of the electric heating wire is electrically connected with the upper electrode, and the other end of the electric heating wire is electrically connected with the atomizing sleeve so as to be electrically connected with an external power supply through the upper electrode and the atomizing sleeve.

Optionally, the oil storage component comprises an oil storage component main body and an anti-disassembly component detachably inserted into one end of the oil storage component main body, and the anti-disassembly component comprises an air regulating seat, an elastic piece and a movable cover;

one end of the air regulating seat is inserted into the oil storage component main body and is connected with the oil storage component main body through threads, the other end of the air regulating seat extends out of the oil storage component main body, the elastic piece is fixed on the air regulating seat and elastically supports against the movable cover so as to provide the movable cover with elastic force in the direction away from the oil storage component main body, the movable cover is arranged at one end of the air regulating seat, which is opposite to the oil storage component main body, the movable cover is provided with a meshing groove, the air regulating seat is provided with meshing teeth matched with the meshing groove, and the meshing groove is a preset distance away from the meshing teeth; when the disassembly prevention assembly is required to be disassembled from the oil storage component main body, a force towards the direction of the air regulating seat is required to be applied to the movable cover until the engagement groove is engaged with the engagement teeth, so that the disassembly prevention assembly is disassembled from the oil storage component main body by rotating the movable cover.

Optionally, the atomization core component is movably inserted in the oil storage component, and one end of the atomization core component is in threaded connection with the disassembly prevention component, so that the atomization core component can be taken out from the oil storage component main body together with the disassembly prevention component when the disassembly prevention component is taken out from the oil storage component main body.

The atomizer kit has the beneficial effects that the atomizer body is internally provided with the containing cavity, the oil storage cavity, the atomizing cavity and the heating component, the atomizer body and the suction nozzle component are matched to form the atomizer, the containing cavity is communicated with the atomizing cavity and the suction nozzle component, the containing cavity is used for containing tobacco and is used as a first smoke channel, the heating component is arranged in the atomizing cavity and is used for atomizing tobacco oil in the oil storage cavity to form smoke, and the smoke atomized in the atomizing cavity is used for heating the tobacco in the containing cavity to generate mixed smoke, so that the mixed smoke flows to the suction nozzle component through the first smoke channel when smoking. The tobacco in the atomizer is heated only by the high-temperature smoke generated by the atomizing cavity, and no additional electric heating device is needed for baking the tobacco, so that the tobacco in the containing cavity can be uniformly heated and the aromatic flavor of the tobacco in the containing cavity can be fully steamed, the smoke amount is large, and the problem that more harmful substances are still generated due to easy carbonization when the tobacco is baked by the electric heating device in the prior art is avoided.

Drawings

FIG. 1 is a schematic view of the overall structure of an atomizer kit according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of an atomizer kit according to an embodiment of the present invention;

FIG. 3 is a schematic view of the overall structure of an embodiment of the atomizer according to the present invention;

FIG. 4 is a schematic cross-sectional view of another embodiment of a nebulizer body according to the invention;

FIG. 5 is a schematic view of an explosion connection structure of an embodiment of the atomizer according to the present invention;

FIG. 6 is a schematic cross-sectional view of another embodiment of a nebulizer according to the invention;

FIG. 7 is a schematic cross-sectional view of an atomizer according to an embodiment of the present invention;

FIG. 8 is a schematic cross-sectional view of another embodiment of a nebulizer according to the invention;

FIG. 9 is a schematic view of an explosion connection structure of an embodiment of the atomizer according to the present invention;

FIG. 10 is a schematic cross-sectional view of another embodiment of a nebulizer according to the invention;

FIG. 11 is a schematic cross-sectional view of another embodiment of a nebulizer according to the invention;

FIG. 12 is a schematic view of a partial explosion connection structure of an embodiment of a nebulizer according to the invention;

FIG. 13 is a schematic view of a partial explosion connection structure of an embodiment of a nebulizer according to the invention;

fig. 14 is a schematic partial structure of an embodiment of the atomizer according to the present invention.

Detailed Description

Example 1

The embodiment provides an atomizer external member, can make the user at the in-process of smoking smog through the atomizer external member that this embodiment shows, can inhale the taste that is approximately the same with real cigarette taste, can avoid the tar that produces when real cigarette burns moreover to the injury of user's health.

The following first describes an exemplary structure of the nebulizer kit according to the present embodiment with reference to fig. 1 and fig. 2, where fig. 1 is a schematic overall structure of the nebulizer kit according to the present invention, and fig. 2 is a schematic cross-sectional structure of the nebulizer kit according to the present invention.

The atomizer set shown in this embodiment is used to connect with and cooperate with the suction nozzle assembly to form an atomizer, and in particular, the specific manner of connection between the atomizer set and the suction nozzle assembly is not limited in this embodiment, and for example, multiple manners such as threaded connection, snap connection, and the like may be used.

Specifically, the nebulizer kit shown in this embodiment includes a nebulizer body 100.

More specifically, as shown in fig. 3, fig. 3 is a schematic overall structure of an embodiment of the atomizer provided by the present invention; the atomizer body 100 is connected with the nozzle assembly 101 to form the atomizer.

The following describes a connection manner between the atomizer body 100 and the nozzle assembly 101 in the present embodiment:

as shown in fig. 1 to 3, a first end of the atomizer body 100 is provided with a connection groove 110 for detachable connection with the suction nozzle assembly 101;

the suction nozzle assembly 101 may be inserted into the connection groove 110, so as to achieve the plug connection between the suction nozzle assembly 101 and the atomizer body 100.

Fig. 4 to 6 show another embodiment of the atomizer body according to the present invention, fig. 5 shows an explosion connection structure of the atomizer according to the present invention, and fig. 6 shows a cross-sectional structure of the atomizer according to the present invention.

The first end of the atomizer body 100 is provided with a connection post 120 for detachably connecting with the suction nozzle assembly 101, and the suction nozzle assembly 101 can be sleeved on the outer circumferential surface of the connection post 120 so as to realize plug connection between the suction nozzle assembly 101 and the atomizer body 100.

Alternatively, an external thread section 121 may be disposed on the outer circumferential surface of the connection post 120, and an internal thread section 122 may be disposed on the inner circumferential surface of the nozzle assembly 101, and the nozzle assembly 101 may be detachably connected to the atomizer body 100 through the connection post 120 by means of the threaded connection between the external thread section 121 and the internal thread section 122.

Specifically, taking the example shown in fig. 2 as an example, the second end of the atomizer body 100 is provided with an electrode assembly 111 for electrical connection with an external power source.

Specifically, the atomizer body 100 is provided with a containing chamber 200, an oil storage chamber 103, an atomizing chamber 104, and a heating assembly 105 for atomizing tobacco tar to form smoke.

More specifically, the oil storage chamber 103 for storing tobacco tar in the embodiment is in communication with the atomization chamber 104, so that tobacco tar in the oil storage chamber 103 can flow to the heating component 105 in the atomization chamber 104, and thus the heating component 105 can atomize tobacco tar in the oil storage chamber 103 to form smoke.

In this embodiment, the specific structures of the oil storage chamber 103, the atomizing chamber 104 and the heating unit 105 are not limited, as long as the heating unit 105 located in the atomizing chamber 104 can atomize the tobacco tar located in the oil storage chamber 103 to generate smoke.

The accommodating chamber 200 shown in the present embodiment is provided inside the atomizer body 100.

The following is further described with reference to fig. 7, where fig. 7 is a schematic cross-sectional structure of an embodiment of the atomizer according to the present invention.

The accommodating cavity 200 is arranged inside the atomizer body 100, and tobacco 301 is arranged inside the accommodating cavity 200 in the atomizer body 100.

The tobacco 301 shown in this embodiment may be a conventional cigarette sold in the existing market, i.e. in actual use, the user may insert the cigarette directly inside the receiving chamber 200 or insert a portion of the cigarette inside the receiving chamber 200. Of course, the tobacco shred may be made by self-made tobacco shred, and the like, and is not particularly limited herein.

Of course, the tobacco may be directly placed inside the accommodating cavity 200 in this embodiment, which is not limited in this embodiment.

When the atomizer body 100 of the present embodiment is connected to the nozzle assembly 101, the accommodating chamber 200 is respectively connected to the atomizing chamber 104 and the nozzle assembly 101.

The accommodating cavity 200 is used for accommodating the tobacco 301 and is used as a first smoke channel for flowing smoke, in particular, the interior of the accommodating cavity 200 is used for inserting the tobacco 301, and the interior of the accommodating cavity 200, in which the tobacco 301 is inserted, is formed with the first smoke channel for flowing smoke.

That is, the aerosol atomized by the heating element 105 in the atomizing chamber 104 can flow via the direction of the first aerosol passage, and the flow direction is shown by the arrow in the accommodating chamber 200 in fig. 7, and the direction of the aerosol flowing along the first aerosol passage is the direction toward the suction nozzle assembly 101.

More specifically, the direction of the air flow of the tobacco-inserted atomizer when the user smokes will be described below with reference to fig. 7:

the arrow direction shown in fig. 7 is the airflow direction of the atomizer provided in this embodiment.

The atomizer shown in this embodiment is provided with an air inlet 106, and the air inlet 106 shown in this embodiment is in conduction with the atomizing cavity 104, so that air outside the atomizer can flow into the atomizing cavity 104 via the air inlet 106, and air flow in the atomizing cavity 104 can drive the smoke atomized by the heating component 105 to flow into the accommodating cavity 200.

The smoke located inside the holding chamber 200 in this embodiment has a relatively high humidity and temperature so that the smoke can heat the tobacco 301 inside the holding chamber 200 to produce a mixed smoke.

The mixed aerosol flows along the direction of the first aerosol passage to the mouthpiece assembly 101 to enable a user to inhale the mixed aerosol through the mouthpiece assembly 101.

Alternatively, as shown in fig. 7, the two ports of the accommodating cavity 200 are opposite and coaxially disposed.

By adopting the structure shown in this embodiment, the smoke in the atomization cavity 104 can flow into the accommodating cavity 200 completely so as to heat the tobacco 301, so that the defect that the smoke in the atomization cavity 104 cannot flow into the accommodating cavity 200 completely due to the fact that the positions of the two ports of the accommodating cavity 200 are not opposite or coaxial is avoided, and the smoke in the accommodating cavity 200 can flow into the accommodating cavity 200 in a sufficient amount due to the fact that the positions of the two ports of the accommodating cavity 200 are opposite or coaxial is avoided, so that the tobacco 301 can be heated by the sufficient amount of smoke so as to generate the sufficient amount of mixed smoke.

It should be clear that, the heating component 105 shown in this embodiment is the only heating device in the atomizer, that is, in this embodiment, the only energy source for heating the tobacco is the smoke formed by atomizing tobacco tar by the heating component 105 shown in this embodiment, and by adopting the structure shown in this embodiment, on the premise that the user can inhale the smoke taste of the cigarette, no additional component is required to be added in the atomizer, so that the cost of generating and the difficulty of manufacturing the atomizer are reduced, the difficulty of assembling the atomizer is reduced, and the efficiency of assembling the atomizer is improved.

The beneficial effects of adopting the specific structure of atomizer that this embodiment shows lie in:

the embodiment provides an atomizer external member, this embodiment the atomizer external member can adapt the existing suction nozzle subassembly of user, then the user want to use the atomizer external member that this embodiment provided when inhaling smog, only need with the suction nozzle subassembly connect to on the atomizer external member can, the smog that this embodiment shows in addition can be to being located tobacco in holding the chamber heats to tobacco can produce the same or similar flue gas of taste that produces after the cigarette burning after being heated, then when the user smokes the suction nozzle subassembly, can inhale the mixed smog that contains two kinds of tastes, and part in the mixed smog is for the smog that the heating element atomizes the tobacco tar produces, another is the taste the same or similar flue gas that produces after burning with the cigarette, thereby richened the taste of user's smoking smog.

When the tobacco is heated by the smoke, although the smoke with the same or similar taste as that generated after the cigarette is burnt can be generated by the tobacco under the action of the high temperature of the smoke, the smoke does not contain tar, so that harm of the tar to the body of a user is effectively avoided, and the safety of the atomizer provided by the embodiment is effectively ensured for the user.

Example two

The specific structure of the nebulizer kit according to the first embodiment will be described in detail, and it should be understood that the description of the structure of the nebulizer kit according to the first embodiment is an optional example, and is not limited thereto.

First, when the smoke generated by the atomization of the heating component 105 for heating the tobacco has a considerable humidity, the moisture contained in the tobacco is raised when the smoke heats the tobacco, so that the moisture content in the smoke tends to increase as the time for the user to suck the atomizer increases.

If the moisture content in the smoke is too high, the moisture in the tobacco can obstruct the transmission of the smoke in the process of heating the tobacco, on one hand, the smoke is harder to flow along the first smoke channel in the embodiment, on the other hand, the smoke is harder to drive the smoke which is produced on the tobacco and has the same or similar taste as the cigarette to flow along the first smoke channel in the embodiment, so that a user cannot smoothly inhale the mixed smoke.

In order to solve the above technical problems, a description will be made with reference to fig. 8, wherein fig. 8 is a schematic cross-sectional structure of another embodiment of the atomizer provided by the present invention.

As shown in fig. 8, in this embodiment, the accommodating chamber 200 is disposed inside the atomizer body 100, and a second smoke channel 501 is further disposed in the atomizer body 100, and the second smoke channel 501 is in communication with the suction nozzle assembly 101 and the atomizing chamber 104.

The second fume channel 501 is used to divert a portion of the fume in the atomization chamber 104 and direct the portion of the fume to the nozzle assembly 101.

By the diverting action of the second smoke channel 501, a part of the smoke flowing out of the nebulization chamber 104 flows into the first smoke channel and another part of the smoke flowing out of the nebulization chamber 104 flows into the second smoke channel 501.

Specifically, in the present embodiment, the second smoke channel 501 is configured to allow at least part of the smoke in the aerosol chamber 104 to bypass the accommodating chamber 200 and flow to the nozzle assembly 101 of the nozzle assembly 101 through the second smoke channel 501.

The flow dividing function of the second smoke passage 501 in the present embodiment is described in detail below:

the second smoke channel 501 and the accommodating cavity 200 in this embodiment are respectively connected to the atomizing cavity 104, and with the structure shown in this embodiment, the smoke atomized in the atomizing cavity 104 by the heating component 105 is divided into a first smoke and a second smoke, and the first smoke can flow into the accommodating cavity 200, so that the first smoke can heat the tobacco in the accommodating cavity 200, and the mixed smoke formed after heating flows into the suction nozzle component 101.

And the second smoke can bypass the receiving chamber 200 and flow along the direction of the second smoke channel 501 to the nozzle assembly 101.

It can be seen that, with the structure shown in this embodiment, a user can suck the mixed smoke and the second smoke in the suction nozzle assembly 101, and with the structure described in this embodiment, even if the tobacco contains considerable moisture along with the increment of the usage time of the atomizer, the second smoke channel 501 is provided, so that at least part of the smoke atomized by the heating assembly 105 can be conducted to the suction nozzle assembly 101, and the situation that the smoke is blocked by the tobacco and cannot be transmitted to the suction nozzle assembly 101 is avoided. And through setting up second smog passageway 501, shunted the smog that atomizes in the atomizing chamber 104, therefore not only solved because hold the tobacco of chamber 200 and because of moist and lead to the smog that suction nozzle assembly 101 flows out too little after using for a period, so that user experience is poor problem, increased the time that tobacco taste released moreover, improved user experience greatly.

The specific structure of the second smoke channel 501 is not limited in this embodiment, as long as the second smoke can be transmitted to the suction nozzle assembly 101 through the guidance of the second smoke channel 501.

Specifically, in this embodiment, a vent slot 310 is concavely formed at a wall of the accommodating cavity 200 and disposed along a longitudinal extension of the accommodating cavity 200, one end of the vent slot 310 is communicated with the atomizing cavity 104, and the other end of the vent slot 310 is communicated with the suction nozzle assembly 101.

In this embodiment, in order to improve the service life of the atomizer and reduce the use cost of the user, refer to fig. 9, where fig. 9 is a schematic diagram of an explosion connection structure of an embodiment of the atomizer provided by the present invention.

Specifically, the detachable connection between the suction nozzle assembly 101 and the atomizer body 100 is not limited in this embodiment, for example, a protrusion 112 is provided on the outer peripheral surface of the suction nozzle assembly 101, and a groove 113 matching with the protrusion 112 is provided on the inner peripheral surface of the atomizer body 100, so that the suction nozzle assembly 101 is connected to the atomizer body 100 through the groove 113 and the protrusion 112 that are mutually matched, and of course, the suction nozzle assembly 101 and the atomizer body 100 may also adopt a plurality of ways such as magnetic adsorption connection.

When the tobacco needs to be replaced or added in the atomizer, the suction nozzle assembly 101 can be detached from the atomizer body 100 due to the detachable connection structure between the suction nozzle assembly 101 and the atomizer body 100, when the suction nozzle assembly 101 is detached from the atomizer body 100, the tobacco 301 can be inserted into the accommodating cavity 200, and then the suction nozzle assembly 200 can be mounted on the atomizer body 100 provided with the tobacco.

When the tobacco in the atomizer needs to be taken out, the suction nozzle assembly 101 can be detached from the atomizer body 100 due to the detachable connection structure between the suction nozzle assembly 101 and the atomizer body 100, and the tobacco 301 can be taken out from the accommodating cavity 200.

Therefore, the structure shown in the embodiment is adopted, so that the user can conveniently replace or install tobacco, tobacco with different tastes or brands can be installed according to different requirements of different users on tobacco tastes, personalized requirements of the user are met, and new tobacco can be replaced at any time after the tobacco is used for a certain time, so that the smoke with the same or similar taste as the solid cigarette in mixed smoke sucked by the user can be ensured to keep a certain concentration under the condition that the smoke concentration in the mixed smoke is too low as the solid cigarette in taste, the service life of the atomizer is prolonged, and the use cost of the atomizer is saved.

As further shown in fig. 10, fig. 10 is a schematic cross-sectional structure of another embodiment of the atomizer according to the present invention.

One end of the accommodating cavity 200, which is away from the first cavity opening 302, is provided with a limiting plate 303 for blocking the tobacco 301 from moving in a direction away from the first cavity opening 302. The first cavity opening 302 of the accommodating cavity 200 is an opening of the accommodating cavity 200 near the atomizing cavity 104, and the limiting plate 303 shown in this embodiment is adopted to effectively block the position of the tobacco 301 from being changed, so that the tobacco 301 is stably disposed in the accommodating cavity 200, and the possibility that a user sucks the tobacco due to the change of the position of the tobacco 301 is avoided. If the limiting action of the limiting plate 303 is not performed, when the tobacco 301 moves to a position close to the suction nozzle assembly 101, the heat of the smoke is reduced when the smoke flows onto the tobacco 301, and the smoke with the reduced temperature cannot sufficiently heat the tobacco 301, so that the smoke taste of the tobacco cannot be sufficiently steamed.

A third smoke channel 304 coaxially arranged with the accommodating cavity 200 is arranged on one side of the limiting plate 303 facing the suction nozzle assembly 101, one end of the third smoke channel 304 is communicated with the accommodating cavity 200, and the other end of the third smoke channel 304 is communicated with the suction nozzle assembly 101.

By adopting the structure shown in this embodiment, it can be ensured that the mixed smoke can be smoothly conducted to the suction nozzle assembly 101, and by adopting the third smoke channel 304, the smoke flowing into the third smoke channel 304 via the second smoke channel and the mixed smoke flowing via the first smoke channel can be fully mixed in the third smoke channel 304, so that the suction nozzle assembly 101 can output smoke with uniform concentration.

Optionally, as shown in fig. 4, a partition 307 for blocking the tobacco 301 in the accommodating chamber 200 from moving toward the atomizing chamber 104 is disposed between the atomizing chamber 104 and the accommodating chamber 200.

As shown in fig. 4 and 9, at least one through hole 308 is provided in the partition 307, and the through hole 308 communicates with the accommodating chamber 200 and the atomizing chamber 104.

It can be seen that the partition 307 of the present embodiment is used, so that the tobacco in the holding chamber 200 is not blocked by the partition 307 from the first mouth of the atomizing chamber 104 facing the holding chamber 200, and thus the smoke in the atomizing chamber 104 flows to the holding chamber 200 via the perforations 308 of the partition 307.

Optionally, the partition 307 is disc-shaped, the partition 307 faces the groove wall of the accommodating cavity 200, an annular groove 114 is provided, and an opening direction of the annular groove 114 is opposite to the groove wall of the accommodating cavity 200, an elastic element 115 is provided in the annular groove 114, and the elastic element 115 is propped against and disposed between the annular groove 114 and the groove wall of the accommodating cavity 200, so that the structure shown in the embodiment is adopted to promote the stability of the atomizer structure, and the position of the partition 307 is effectively prevented from changing.

The atomizer shown in this embodiment can also avoid the user from sucking tobacco, and the specific structure is shown in fig. 11, where fig. 11 is a schematic cross-sectional structure of another embodiment of the atomizer provided by the present invention.

The second cavity opening 116 is disposed in the direction of the suction nozzle assembly 101 in the accommodating cavity 200, and the second cavity opening 116 of the accommodating cavity 200 is a cavity opening of the accommodating cavity 200 away from the atomizing cavity 104.

When the mouthpiece assembly 101 is separated from the atomizer body 101 (as shown in fig. 1), the tobacco 301 can be inserted into the housing chamber 200 from the second mouth 116 or the tobacco 301 can be removed from the housing chamber 200.

One end of the accommodating cavity 200, which is away from the second cavity opening 116, is provided with a limiting mechanism 603 for blocking the tobacco 301 from moving away from the first cavity opening 302.

By adopting the limiting mechanism 603 in this embodiment, the limiting mechanism 603 always applies a force to the tobacco 301 located in the accommodating cavity 200 towards the direction of the first cavity opening 302, so that the tobacco 301 is fixed in the accommodating cavity 200, and the smoke flowing out of the atomizing cavity 104 can rapidly heat the tobacco 301 located in the accommodating cavity 200, so that loss of smoke heat before the tobacco 301 is not heated is avoided, and tobacco heating efficiency is improved.

In addition, the limiting mechanism 603 can also prevent the tobacco 301 from moving to the suction nozzle assembly 101, so that a user is effectively prevented from sucking the tobacco 301 through the suction nozzle assembly 101, and safety in the process of using the atomization assembly in the embodiment is guaranteed.

Specifically, the limiting mechanism 603 may be a limiting step disposed around the cavity wall of the accommodating cavity 200.

The specific structure of the limiting mechanism 603 is not limited in this embodiment, as long as the limiting mechanism 603 can prevent the user from sucking the tobacco 301 through the suction nozzle assembly 101, thereby ensuring the safety in the process of using the atomizing assembly shown in this embodiment.

Optionally, in the accommodating cavity 200 shown in this embodiment, a filter screen 604 is further provided, which is covered on one end of the accommodating cavity 200 facing the suction nozzle assembly 101, and the filter screen 604 is used for blocking tobacco 301 particles in the accommodating cavity 200 from entering the oral cavity of the user, so that it can be seen that the filter screen 604 can filter out the tobacco 301 particles but can smoothly pass through mixed smoke, thereby avoiding the possibility that the user sucks the tobacco particles on the premise that the sucking efficiency of the user on the mixed smoke is not affected.

The specific structure of the atomizer body 100 is described in detail below with reference to fig. 11 and 12:

fig. 12 is a schematic view of a local explosion connection structure of an embodiment of the atomizer according to the present invention.

The atomizer body 100 includes an oil storage assembly and an atomizing core assembly 702 inserted in the oil storage assembly, and the oil storage assembly is internally provided with the oil storage cavity 103.

The atomizing core assembly 702 comprises an atomizing sleeve 703, a tobacco tar adsorbing sleeve 705, an upper insulating ring 706, an upper electrode 707, and an electric heating wire 708.

Specifically, an oil inlet 704 communicated with the oil storage cavity 103 is provided on a wall of the atomizing sleeve 703, the tobacco tar adsorbing sleeve 705 is sleeved in the atomizing sleeve 703 and covers the oil inlet 704, and the heating wire 708 is used as the heating component 105. It will be appreciated that the heating assembly 105 is not particularly limited herein, as long as it is capable of atomizing tobacco tar.

The specific functions of the heating assembly 105 are described in detail in the embodiments described above.

The heating wire 708 is wound into a spiral shape and is at least partially sleeved in the tobacco tar adsorption sleeve 705 so as to atomize the tobacco tar in the tobacco tar adsorption sleeve 705, the atomization cavity 104 is formed in the tobacco tar adsorption sleeve 705, the upper insulating ring 706 is sleeved in one end of the atomization sleeve 703, the upper electrode 707 is sleeved in the insulating ring 706, one end of the heating wire 708 is electrically connected with the upper electrode 707, and the other end of the heating wire 708 is electrically connected with the atomization sleeve 703 so as to be electrically connected with an external power supply through the upper electrode 707 and the atomization sleeve 703.

Specifically, an atomization core cover 709 is sleeved in one end of the atomization sleeve 703, which is away from the upper electrode 707, a sealing pad 710 is sleeved outside the atomization core cover 709, an oil separation sleeve 711 is sleeved outside the atomization sleeve 703, a gap for air intake is formed between the oil separation sleeve 711 and the atomization sleeve 703, and the surface of the atomization sleeve 703 provided with the oil inlet 704 is tightly adhered to the oil separation sleeve 711 and is communicated with the oil storage cavity through a through hole (not labeled in the figure) on the side wall of the oil separation sleeve 711.

The following describes a specific structure of the oil storage assembly shown in this embodiment:

specifically, description is made with reference to fig. 12 and fig. 13, where fig. 13 is a schematic view of a local explosion connection structure of an embodiment of the atomizer provided by the present invention.

The oil storage assembly comprises an oil storage assembly main body 801 and an anti-disassembly assembly 802 detachably inserted into one end of the oil storage assembly main body 801.

The oil storage component main body 801 comprises a fixed sleeve 8011, an oil storage sleeve 8012, a first sealing gasket 8013, a second sealing gasket 8014, a first connector 8015, a second connector 8016, a lower insulating ring 8017 and a lower electrode 8018, wherein the oil storage sleeve 8012 is sleeved in the fixed sleeve 8011, the first sealing gasket 8013 and the second sealing gasket 8014 are respectively covered at two ends of the oil storage sleeve 8012, the first connector 8015 and the second connector 8016 are respectively inserted at two ends of the oil storage sleeve 8012, the lower insulating ring 8017 is inserted in the lower connector, the lower electrode 8018 is sleeved in the lower insulating ring 8017, the first connector 8015 is used for being connected with the anti-dismantling component 802, and the lower electrode 8018 and the second connector 6 are used for being electrically connected with an external power supply. It will be appreciated that the oil storage assembly is not particularly limited herein as long as it is capable of storing tobacco tar.

The anti-disassembly component 802 comprises an air adjusting seat 803, an elastic piece 804 and a movable cover 805, one end of the air adjusting seat 803 is inserted into the oil storage component main body 801 and is connected with the first connector 8015 of the oil storage component main body 801 through threads, the other end of the air adjusting seat 803 extends out of the oil storage component main body 801, the elastic piece 804 is fixed on the air adjusting seat 803 and elastically supports against the movable cover 805 so as to provide an elastic force for the movable cover 805 towards a direction far away from the oil storage component main body 801, and the movable cover 805 covers one end of the anti-disassembly component, which is opposite to the oil storage component main body 801.

The following details of how the disassembly prevention assembly according to the present embodiment can avoid the disassembly of the atomizer due to the misoperation are as follows:

fig. 13 to 14 are schematic views showing a partial structure of an embodiment of the atomizer according to the present invention.

The movable cover 805 is provided with an engagement groove 806, and engagement teeth 807 for engaging with the engagement groove 806 are provided on an end surface of the air adjusting seat 803.

The engagement slot 806 is a predetermined distance from the engagement teeth 807 when the atomizer is in normal use as shown in this embodiment.

Under the condition that the meshing groove 806 is away from meshing teeth 807 preset distance, then the user is anyway to the atomizer is revolved and is twisted the operation, can't carry out the right the dismantlement action of atomizer to avoided because of user's maloperation and with the condition that the atomizer was dismantled, avoided children in addition revolve when twisting the atomizer to the accident with the atomizer is dismantled, thereby effectually avoided children to inhale the possibility of tobacco tar, it can be seen that the atomizer that adopts the embodiment to show can promote the safety in utilization of atomizer structure, avoids carrying out the condition of unexpected dismantlement to the atomizer.

When the atomizer needs to be disassembled, that is, when the air regulating seat 803 needs to be disassembled from the oil storage main body, a force towards the air regulating seat 803 needs to be applied to the movable cover 805 until the engagement groove 806 is engaged with the engagement teeth 807, so that the disassembly preventing assembly can be disassembled from the oil storage main body 801 by rotating the movable cover 805 to disassemble the air regulating seat 803 from the oil storage main body 801.

Specifically, the atomization core component 702 is movably inserted into the oil storage component, specifically, one end of the atomization core component 702 is in threaded connection with the disassembly prevention component, more specifically, one end of the oil separation sleeve 711 of the atomization core component 702 is in threaded connection with the air adjustment seat 803, so that the atomization core component 702 can be taken out from the oil storage component main body 801 together with the disassembly prevention component when the disassembly prevention component is taken out from the oil storage component main body 801.

With the structure of the atomizer according to the present embodiment, when the atomization core component 702 needs to be detached, a force in the direction of the air adjusting seat 803 needs to be applied to the movable cover 805 until the engagement groove 806 engages with the engagement tooth 807, and a screwing force needs to be applied to the movable cover 805 until the detachment prevention component is removed from the oil storage component main body 801, so that the detachment prevention component and the atomization core component 702 are removed from the oil storage component main body 801.

Optionally, in the embodiment shown, an insertion slot 808 is formed in the air conditioning seat 803, and the suction nozzle assembly 101 is detachably inserted into the insertion slot 808.

Optionally, a vent pipe 809 is inserted into the air regulating seat 803, a vent groove 810 is provided inside the movable cover 805 in this embodiment, and a vent hole 811 is provided on the air regulating seat 803.

When the user needs to adjust the air inflow, the movable cover 805 can be rotated, and the overlapping area between the ventilation groove 810 of the movable cover 805 and the ventilation hole 811 of the air regulating seat 803 is controlled, that is, the air inflow of the atomizer increases with the increase of the overlapping area between the ventilation holes 811 of the air regulating seat 803.

Therefore, the atomizer shown in the embodiment can be suitable for the requirements of users on different smoke concentrations, and can meet the requirements of users on smoke individuation.

The above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. An atomizer kit is used for being connected and matched with a suction nozzle assembly to form an atomizer, and comprises an atomizer main body, and is characterized in that a connecting column or a connecting groove used for being detachably connected with the suction nozzle assembly is arranged at a first end of the atomizer main body, an electrode assembly used for being electrically connected with an external power supply is arranged at a second end of the atomizer main body, a containing cavity, an oil storage cavity, an atomizing cavity and a heating assembly used for atomizing tobacco tar to form smoke are arranged in the atomizer main body, when the suction nozzle assembly is connected with the atomizer main body, the containing cavity is communicated with the atomizing cavity and the suction nozzle assembly, the containing cavity is used for containing tobacco and is used as a first smoke channel, the heating assembly is arranged in the atomizing cavity and used for atomizing the tobacco tar in the oil storage cavity to form smoke, and the smoke atomized in the atomizing cavity is used for heating the tobacco in the containing cavity to generate mixed smoke, so that when the mixed smoke flows to the suction nozzle assembly through the first smoke channel;

The atomizer body is internally provided with a second smoke channel which is communicated with the suction nozzle assembly and the atomizing cavity, and the second smoke channel is used for shunting part of smoke in the atomizing cavity and guiding the part of smoke into the suction nozzle assembly;

the air vent groove is formed in the cavity wall of the accommodating cavity in a recessed mode, the air vent groove extends longitudinally along the accommodating cavity, one end of the air vent groove is communicated with the atomizing cavity, and when the atomizer body is connected with the suction nozzle assembly, the other end of the air vent groove is communicated with the suction nozzle assembly;

the atomizer body comprises an oil storage component and an atomization core component inserted into the oil storage component;

the oil storage assembly comprises an oil storage assembly main body and an anti-disassembly assembly which is detachably inserted into one end of the oil storage assembly main body, and the anti-disassembly assembly comprises an air regulating seat, an elastic piece and a movable cover;

one end of the air regulating seat is inserted into the oil storage component main body and is connected with the oil storage component main body through threads, the other end of the air regulating seat extends out of the oil storage component main body, the elastic piece is fixed on the air regulating seat and elastically supports against the movable cover so as to provide the movable cover with elastic force in the direction away from the oil storage component main body, the movable cover is arranged at one end of the air regulating seat, which is opposite to the oil storage component main body, the movable cover is provided with a meshing groove, the air regulating seat is provided with meshing teeth matched with the meshing groove, and the meshing groove is a preset distance away from the meshing teeth; when the disassembly prevention assembly is required to be disassembled from the oil storage assembly main body, a force towards the direction of the air regulating seat is required to be applied to the movable cover until the engagement groove is engaged with the engagement teeth, so that the disassembly prevention assembly is disassembled from the oil storage assembly main body by rotating the movable cover.

2. The atomizer kit according to claim 1, wherein a limiting plate for blocking the tobacco from moving towards a direction away from the first cavity opening is arranged at one end of the accommodating cavity, which is opposite to the first cavity opening, the first cavity opening of the accommodating cavity is a cavity opening of the accommodating cavity, which is close to the atomizing cavity, a third smoke channel coaxially arranged with the accommodating cavity is arranged at one side of the limiting plate, one end of the third smoke channel is communicated with the accommodating cavity, and the other end of the third smoke channel is communicated with the suction nozzle assembly.

3. The atomizer kit according to claim 1, wherein a partition for blocking movement of said tobacco in said holding chamber towards said atomizing chamber is provided between said atomizing chamber and said holding chamber, said partition being provided with at least one perforation, said perforation being in communication with said holding chamber and said atomizing chamber.

4. A nebulizer kit as claimed in claim 3, wherein the baffle is disposed within the receiving chamber and removably connected to a wall of the receiving chamber such that the baffle can be removed from the receiving chamber after removal of the nozzle assembly.

5. The nebulizer kit of claim 4, wherein the partition plate is disc-shaped, an annular groove is formed in the partition plate facing the groove wall of the accommodating cavity, the opening direction of the annular groove is opposite to the groove wall of the accommodating cavity, an elastic piece is arranged inside the annular groove, and the elastic piece is propped against and arranged between the annular groove and the groove wall of the accommodating cavity.

6. The nebulizer kit of claim 1, wherein the receiving cavity is provided with a second cavity opening in a direction of the suction nozzle assembly, the second cavity opening of the receiving cavity being a cavity opening of the receiving cavity away from the nebulizing cavity, the second cavity opening of the receiving cavity being provided with a limiting mechanism for blocking movement of the tobacco in a direction away from the receiving cavity in a direction away from the second cavity opening when the suction nozzle assembly is separated from the nebulizer body, the tobacco being insertable into or removable from the receiving cavity from the second cavity opening.

7. The nebulizer kit of claim 6, wherein the stop mechanism is a stop step disposed around a cavity wall of the receiving cavity.

8. The nebulizer kit of claim 6, wherein the receiving chamber is further provided with a screen covering the second chamber opening of the receiving chamber, the screen for impeding the tobacco within the receiving chamber from entering the nozzle assembly.

9. The nebulizer kit of claim 1, wherein the oil reservoir is formed within the oil reservoir assembly; the atomizing core component comprises an atomizing sleeve, a tobacco tar adsorption sleeve, an electric heating wire, an upper insulating ring and an upper electrode, wherein an oil inlet communicated with the oil storage cavity is formed in the pipe wall of the atomizing sleeve, the tobacco tar adsorption sleeve is sleeved in the atomizing sleeve and covers the oil inlet, the electric heating wire is used as the heating component, the electric heating wire is wound into a spiral shape and is at least partially sleeved in the tobacco tar adsorption sleeve so as to atomize tobacco tar in the tobacco tar adsorption sleeve, the atomizing cavity is formed in the tobacco tar adsorption sleeve, the upper insulating ring is sleeved in one end of the atomizing sleeve, the upper electrode is sleeved in the upper insulating ring, one end of the electric heating wire is electrically connected with the upper electrode, and the other end of the electric heating wire is electrically connected with the atomizing sleeve so as to be electrically connected with an external power supply through the upper electrode and the atomizing sleeve.

10. The nebulizer kit of claim 1, wherein the nebulization cartridge assembly is movably inserted within the reservoir assembly, one end of the nebulization cartridge assembly being threadably connected to the tamper-evident assembly such that the nebulization cartridge assembly can be removed from the reservoir assembly body along with the tamper-evident assembly when the tamper-evident assembly is removed from the reservoir assembly body.