WO2018018608A1

WO2018018608A1 - Atomizing assembly and electronic cigarette

Info

Publication number: WO2018018608A1
Application number: PCT/CN2016/092304
Authority: WO
Inventors: 刘秋明; 向智勇; 牛建华; 韦志林
Original assignee: 惠州市吉瑞科技有限公司深圳分公司
Priority date: 2016-07-29
Filing date: 2016-07-29
Publication date: 2018-02-01
Also published as: CN208425511U

Abstract

An atomizing assembly and an electronic cigarette. The atomizing assembly comprises: an oil reservoir assembly (200), a suction nozzle assembly (300), a connection assembly (400) and an atomizing core assembly (500); a first gas passage (313) for discharging fog is provided in the suction nozzle assembly (300), an oil reservoir chamber (208) and a ventilation pipe (202) are provided in the oil reservoir assembly (200), a second gas passage (2021) communicated with the first gas passage (313) is formed in the ventilation pipe (202), an oil supply hole (217) communicated with the oil reservoir chamber (208) is provided at an end face of the oil reservoir assembly (200) facing the suction nozzle assembly (300), a gas discharge groove (1200) extending in the longitudinal direction of the atomizing assembly is provided at the connection between the suction nozzle assembly (300) and the ventilation pipe (202). The advantage of using the atomizing assembly lies in that, in the process of connecting the suction nozzle assembly (300) to the oil reservoir assembly (200), the gas in the oil reservoir chamber (208) can be discharged timely through the oil supply hole (217) and the gas discharge groove (1200), effectively avoiding the occurrence of tobacco oil leakage caused by the pressure of the gas squeezing the tobacco oil.

Description

A atomizing component and electronic cigarette

Technical field

The field relates to the field of electronic cigarettes, and particularly relates to an atomizing component and an electronic cigarette which are convenient for adding smoke oil, effectively preventing leakage of smoke oil, long service life and hygienic use.

Background technique

The prior art provides an atomization assembly capable of atomizing smoke oil to form a smoke. The specific structure of the atomization assembly provided by the prior art is described in detail below with reference to FIG. 1 and FIG. 2, the atomization. The assembly includes a suction nozzle 100, a vent pipe 101 that is electrically connected to the suction nozzle 100, and an upper cover 102 that is tightly fitted to an end of the vent pipe 101. The vent pipe 101 is inserted inside the atomization sleeve 103. An oil reservoir 104 capable of storing the oil is formed between the vent tube 101 and the atomizing sleeve 103, and the atomizing core assembly 105 is inserted into the end of the vent tube 101 away from the upper cover 102. An oil injection hole 106 is provided in communication with the oil reservoir 104.

When it is required to fill the oil storage chamber 104 with the oil, the atomization core assembly 105 needs to be disassembled to expose the oil injection hole 106, so that the oil is injected into the oil storage chamber through the oil injection hole 106. 104.

The defect of the atomization assembly shown in the prior art is that: (1) since the oil injection hole 106 is disposed higher than the end portion of the vent pipe 101, it is easy to pour the smoke oil into the pass when adding the smoky oil. The trachea 101, the user is very easy to inhale the smoke oil located in the snorkel 101, posing a hidden danger to the user's health; (2) because the atomizing core assembly 105 is at one end of the oil injection hole 106, resulting in the said The oil inlet hole 106 formed by the wall of the vent pipe 101 and the wall of the atomization sleeve 103 has a small oil inlet diameter, which causes inconvenience of adding smoke oil, affecting customer experience and efficiency of adding smoke oil; (3) the snorkel The end surface of the atomizing sleeve 103 is lower than the end surface of the atomizing sleeve 103, and the oil is easily spilled into the vent pipe 101 after being dropped into the oil reservoir 104; (4) the atomizing core assembly 105 is unscrewed. In the case of smoke oil, a lot of smoke oil adheres to the atomizing core assembly 105, and it is easy to leak oil, causing the hand to be contaminated with smoke oil during the disassembly process, affecting the user experience; (5) after adding the smoke oil When the atomizing core assembly 105 is inserted into the vent pipe, the air in the oil reservoir 104 is compressed, so that the oil is stored after normal placement. The air inside the cigarette 104 normally pressing the oil in the oil chamber 104, so that the smoke oil leaked through the atomizing core assembly 105, causing the user to easily suck smoke oil leakage.

Summary of the invention

The invention provides an atomizing assembly and an electronic cigarette which are convenient for adding smoke oil, effectively preventing leakage of smoke oil, long service life and hygienic use.

The invention provides an atomization assembly for forming an electronic cigarette in combination with a battery assembly, comprising: a nozzle assembly, an oil storage assembly, an atomization core assembly and a connection assembly, the nozzle assembly being detachably coupled to the One end of the oil storage assembly, a first air passage for discharging smoke is disposed in the nozzle assembly, and the atomizing core assembly is inserted into the oil storage assembly for atomizing the oil in the oil storage assembly One end of the connecting component is connected to an end of the oil storage component opposite to the position of the nozzle assembly, and the other end of the connecting component is connected to the battery component;

An oil storage chamber and a vent pipe for discharging the atomization atomization of the atomization core assembly into the nozzle assembly are disposed in the oil storage assembly, and the first air passage is formed in the snorkel a second air passage communicating with the second air passage, the first air passage and the second air passage forming a smoke passage, wherein the oil storage assembly is disposed at an end surface of the nozzle assembly and is connected to the oil storage chamber a fueling hole, the nozzle assembly is disposed on the oiling hole and is sleeved with one end of the vent pipe;

a venting groove disposed along a longitudinal extension of the atomizing assembly is disposed at a junction of the nozzle assembly and the vent tube, and the venting groove is disposed at an end of the nozzle assembly adjacent to the snorkel And the exhaust groove is in communication with the first air passage, or the exhaust groove is disposed at an end of the air pipe adjacent to the nozzle assembly, and the exhaust groove and the first The two air passages are in communication such that air in the oil reservoir can flow into the smoke through the fuel filler port and the exhaust groove during connection of the nozzle assembly to the oil storage assembly In the passage, and after the nozzle assembly and the oil storage assembly are inserted into the preset position, the exhaust groove is blocked by the end of the vent pipe or the end of the nozzle assembly, thereby automatically The passage between the venting channel and the smoke passage is closed.

Optionally, the oil storage assembly includes an oil storage sleeve, the vent tube, a first connecting seat and a second connecting seat, and the oil storage chamber is formed between the vent tube and the oil storage sleeve;

One end of the oil storage sleeve is connected to the first connecting seat, and the other end of the oil storage sleeve is connected to the second connecting seat. The first connecting seat and the connecting component are detachable. connection;

One end outer surface of the vent pipe is provided with a first outer thread segment, and the first outer thread segment is provided with a first limiting protrusion away from the end of the nozzle assembly, and the second connecting seat is provided with First internal thread a nozzle assembly is provided with a second internal thread segment, the second connecting seat is sleeved on the vent pipe, and is connected to the first externally threaded segment by the first internal thread segment, One end of the second connecting base abuts against the first limiting protrusion, the nozzle assembly is detachably inserted at one end of the second connecting seat, and the nozzle assembly passes the second An internally threaded section is coupled to the first externally threaded section.

Optionally, the second internal thread segment is disposed toward the end of the vent tube with the venting groove disposed along a longitudinal extension of the atomizing assembly.

Optionally, the first outer thread segment is disposed toward the end of the nozzle assembly with the exhaust groove disposed along a longitudinal extension of the atomizing assembly.

Optionally, the nozzle assembly is provided with the first air passage extending in a longitudinal direction thereof and a first slot communicating with the first air passage, and an inner wall of the first air passage is provided with a ring shape An oil barrier ring, an angle formed between an end surface of the oil damper facing away from the oil storage assembly and an axial line of the nozzle assembly is an acute angle, and the oil damper is used to block leakage of the oil storage assembly The smoke oil and the condensed smoke oil are drained toward the oil storage assembly, the vent pipe is inserted in the first slot to make the second air passage in the snorkel and the first An airway is connected.

Optionally, a first sealing ring is formed between the first slot and the vent tube, and the second air passage is separated from the first position by the hollow position of the first sealing ring The air passage is conductive, and the first sealing ring is elastically resisted by an inner wall of the nozzle assembly.

Optionally, the nozzle assembly includes a nozzle body and a second sealing ring, wherein an outer circumferential surface of one end of the nozzle body is provided with a first annular groove, and an opening of the first annular groove is opposite to the first The inner walls of the two connecting seats are oppositely disposed, the second sealing ring is sleeved in the first annular groove, and the second sealing ring is elastically resisted by the inner wall of the second connecting seat.

Optionally, the second connecting base comprises an annular sleeve body, and an inner wall of the sleeve body extends inwardly to form an annular oil blocking wall, and an inner wall edge of the oil blocking wall extends away from the nozzle assembly. An annular connecting portion, the connecting portion facing away from the end surface of the nozzle assembly abuts against the first limiting protrusion, the inner wall surface of the connecting portion is provided with the first internal thread segment, One end of the nozzle assembly is inserted into the sleeve body, and the sleeve body is connected to the oil storage sleeve.

Optionally, the second connecting seat is disposed with an annular second slot away from an end surface of the nozzle assembly, and a fourth sealing ring is disposed in the second slot, and the oil storage sleeve is detachably inserted. Located in the second In the slot, an end surface of the oil storage sleeve elastically abuts against the fourth sealing ring.

Optionally, a distance between the end surface of the vent pipe adjacent to the nozzle assembly and an end surface of the nozzle assembly facing away from the oil storage assembly is a first distance, and the oiling hole is away from the nozzle assembly The distance between the end faces of the oil storage assembly is a second distance, and the first distance is less than the second distance.

Optionally, the first connecting seat is disposed with a second annular groove toward the end of the nozzle assembly, a fifth sealing ring is disposed in the second annular groove, and the fifth sealing ring is Elastically resisting the end of the oil reservoir away from the nozzle assembly.

Optionally, the atomizing core assembly comprises an atomizing cover and an atomizing core sleeve, and one end of the atomizing cover is inserted and fixed at an end of the air pipe away from the nozzle assembly, the atomizing cover The other end of the nozzle is connected to the atomization core sleeve, and the atomization cover is disposed away from the end of the nozzle assembly with a second limiting protrusion, and the atomizing core sleeve is adjacent to the end of the nozzle assembly Resisting on the second limiting protrusion, the second limiting protrusion is for preventing the atomizing core sleeve from moving along an end portion of the nozzle assembly;

An oil storage cotton is disposed in the atomization core sleeve, and at least one oil passage hole is disposed through a peripheral wall of the atomization core sleeve to make the oil oil stored between the oil storage sleeve and the ventilation tube The oil absorbing cotton can be electrically connected to the oil storage cotton, and an atomizing space is disposed along the axial direction of the oil absorbing cotton, and the electric heating wire is disposed inside the atomizing space, so that the electric heating wire is The atomized smoke is sequentially conducted to the nozzle assembly via the atomizing core sleeve, the atomizing cover and the vent tube;

The outer peripheral wall of the atomizing cover is provided with a third annular groove, and the third annular groove is sleeved with a sixth sealing ring, and the sixth sealing ring is elastically resisted by the vent pipe.

Optionally, the connecting component includes a first connecting member and a second connecting member made of a conductive material, and the second connecting member is movably sleeved on an outer peripheral wall of the first connecting member, a connecting member is provided with a first through hole communicating with the atomizing space, and a second through hole is disposed through the second connecting member, so that the first through hole can be adjusted when the second connecting member is rotated The area of overlap with the second perforation to adjust the amount of intake air of the atomizing assembly.

Optionally, the first connecting member is disposed adjacent to an inner peripheral wall of the end of the nozzle assembly with a third internal thread segment, and the atomizing core sleeve is disposed away from the outer peripheral wall of the end of the nozzle assembly with a second outer portion. a threaded section, the third internal thread section of the first connecting member is threaded onto the second externally threaded section of the atomizing core sleeve;

The first connecting member is disposed near the outer peripheral wall of the end of the nozzle assembly with a third externally threaded portion, and the inner peripheral wall of the first connecting seat is provided with a fourth internal thread segment, the first connecting member The third outer threaded section is threaded onto the fourth female threaded section of the first connector.

Optionally, a fourth annular groove is disposed on the outer peripheral wall of the first connecting member near the end of the nozzle assembly, and the fourth annular groove is sleeved with a seventh sealing ring, and the The seven sealing ring is elastically resisted by the first connecting seat;

a fifth annular groove is disposed on an inner peripheral wall of the first connecting member near an end of the nozzle assembly, and an eighth sealing ring is disposed in the fifth annular groove, and the eighth sealing ring is The atomizing core sleeve is elastically resisted.

Optionally, the outer peripheral wall of the first connecting member is provided with at least one sixth annular groove, the sixth annular groove is sleeved with a ninth sealing ring, and the ninth sealing ring and the first The two connectors are elastically resisted.

Optionally, a target end portion of the first connecting member is disposed with a third limiting protrusion, and a target end portion of the first connecting member corresponds to an end portion of the second connecting member away from the nozzle assembly Abutting the end of the second connecting member away from the nozzle assembly against the third limiting protrusion, the third limiting protrusion is for preventing the second connecting member from being away from the The end of the nozzle assembly moves.

Optionally, the atomizing core assembly further includes a first inner electrode and a first insulating ring;

The connection assembly further includes a second inner electrode and a second insulating ring, and the first inner electrode and the second inner electrode are electrically connected to each other;

The first inner electrode is inserted at an end of the atomizing core sleeve away from the nozzle assembly, and the first insulating ring is disposed between the atomizing core sleeve and the first inner electrode. Providing a third through hole through the first inner electrode such that an air flow outside the atomization assembly is sequentially conducted to the atomization space via the second through hole, the first through hole, and the third through hole ;

The second inner electrode is disposed to be opposite to the end of the first inner electrode away from the nozzle assembly, and the second insulation is disposed between the first connecting member and the second inner electrode a ring, two ends of the heating wire are electrically connected to the first connecting member and the first inner electrode, respectively.

The invention also provides an electronic cigarette comprising an atomizing component and a battery component, the battery component for supplying power to the atomizing component to atomize the atomizing component to form smoke, and the atomizing Group The component is detachably connected to the battery component;

The atomizing assembly is as described in any of the above.

The invention provides an atomization assembly and an electronic cigarette, the atomization assembly comprising: an oil storage assembly, a nozzle assembly, a connection assembly and an atomization core assembly, wherein the nozzle assembly and the connection assembly are respectively detachably connected At the opposite ends of the oil storage assembly, the connecting assembly is capable of removing the atomizing core assembly from the oil storage assembly when the connecting assembly is detached; a first air passage for exhausting smoke, wherein the oil storage assembly is provided with an oil storage chamber and a smog for discharging the mist atomized by the atomizing core assembly into the nozzle assembly, the snorkel Forming a second air passage communicating with the first air passage, the first air passage and the second air passage forming a smoke passage, and the oil storage assembly is disposed at an end surface of the nozzle assembly a fueling hole communicating with the oil storage chamber, the nozzle assembly is disposed on the oiling hole and is sleevedly connected to one end of the air pipe, and is located at the nozzle assembly and the air pipe The connection is provided with a longitudinal extension along the atomizing assembly Gas tank. The advantage of using the atomizing assembly shown in the present invention is that the nozzle assembly, the oil storage assembly, the connecting assembly and the atomizing core assembly can be easily disassembled, thereby enabling the user to conveniently replace or clean the nozzle assembly. The nozzle assembly, the oil storage assembly, the connecting assembly and the atomizing core assembly effectively improve the service life of the atomizing assembly and the hygienic use. In the process of adding the smoke oil, it is not necessary to disassemble the remaining components, and only the nozzle assembly needs to be detached from the oil storage assembly, thereby effectively improving the efficiency of the user to add the smoke oil, and is convenient for the user to operate, and In the process of adding the smoke oil, the user does not need to touch the atomization core assembly, so that the user's hand does not touch the smoke oil on the atomization core assembly, which effectively improves the user's process of adding the smoke oil. Experience, and in the process of connecting the nozzle assembly to the oil storage assembly, gas in the oil reservoir can be discharged from the fuel filler port and the exhaust tank in time, thereby avoiding gas It is not possible to discharge in time, so that the undischarged gas squeezes the smoke oil in the oil storage chamber, and effectively avoids the leakage of the smoke oil under the action of the gas pressure due to the gas being squeezed by the gas.

DRAWINGS

1 is a schematic cross-sectional structural view of an atomizing assembly provided by the prior art;

2 is a schematic view showing an explosive connection structure of an atomizing assembly provided by the prior art;

3 is a schematic cross-sectional structural view of an embodiment of an atomizing assembly provided by the present invention;

4 is a schematic view showing an explosion connection structure of an embodiment of the atomization assembly provided by the present invention;

5 is a schematic cross-sectional exploded connection structure of an embodiment of an atomizing assembly provided by the present invention;

6 is a cross-sectional structural view showing another embodiment of the atomization assembly provided by the present invention;

7 is a schematic exploded view of an embodiment of an atomizing assembly provided by the present invention;

8 is a partial cross-sectional structural view showing an embodiment of an atomizing assembly according to the present invention;

9 is a schematic cross-sectional exploded connection structure of an embodiment of an atomizing assembly provided by the present invention;

10 is a partial structural schematic view of an embodiment of an atomizing assembly provided by the present invention;

11 is a schematic view showing a partial explosion connection structure of another embodiment of the atomization assembly provided by the present invention;

12 is a schematic cross-sectional exploded connection structure of another embodiment of the atomization assembly provided by the present invention;

Figure 13 is a cross-sectional structural view showing another embodiment of the atomizing assembly provided by the present invention;

FIG. 14 is a schematic view showing a cross-sectional exploded connection structure of another embodiment of the atomization assembly according to the present invention.

detailed description

Embodiment 1 This embodiment provides an atomizing assembly that facilitates the addition of smoke oil, effectively prevents leakage of smoke oil, has a long service life, and is hygienic in use.

The structure of the atomization assembly is described in detail with reference to FIG. 3 and FIG. 4 , wherein FIG. 3 is a cross-sectional structural view of an embodiment of the atomization assembly provided by the present invention, and FIG. 4 is provided by the present invention. An embodiment of an atomizing assembly is an exploded connection structure schematic.

First of all, it should be clarified that the atomization assembly provided in this embodiment is used to form an electronic cigarette in combination with a battery assembly, and the atomization assembly is used to atomize the smoke oil to form smoke when the battery assembly is powered.

The atomization assembly includes an oil storage assembly 200, a nozzle assembly 300, a connection assembly 400, and an atomization core assembly 500.

The nozzle assembly 300 is detachably coupled to one end of the oil storage assembly 200, and the nozzle assembly 300 and the connecting assembly 400 are detachably coupled to opposite ends of the oil storage assembly 200, respectively.

The oil storage assembly 200 is provided with an oil storage chamber 208 and a vent pipe 202 for discharging the mist atomized by the atomizing core assembly 500 into the nozzle assembly 300.

The atomizing core assembly 500 is inserted into the oil storage assembly 200 for atomizing the oil in the oil storage assembly 200. Specifically, the atomizing core assembly 500 and the oil storage chamber 208 are guided. The atomization core assembly 500 is capable of atomizing the smoke oil stored in the oil reservoir 208.

One end of the connecting component 400 is connected to an end of the oil storage component 200 opposite to the nozzle assembly 300, and the other end of the connecting component 400 is connected to the battery component.

The following further describes how the atomization assembly provided in this embodiment specifically prevents smoke leakage from the following in conjunction with FIG. 5 to FIG. 7:

5 is a schematic cross-sectional exploded connection structure of an embodiment of the atomization assembly provided by the present invention, and FIG. 6 is a cross-sectional structural view of another embodiment of the atomization assembly provided by the present invention, and FIG. 7 is a schematic diagram of the present invention. An exploded view of one embodiment of an atomizing assembly provided.

A first air passage 313 for discharging smoke is disposed in the nozzle assembly 300.

A second air passage 2021 communicating with the first air passage 313 is formed in the vent pipe 202, and the first air passage 313 and the second air passage 2021 constitute a smoke passage.

That is, the atomizing core assembly 500 can atomize the smoke oil stored by the oil storage assembly 200 to form smoke, and the smoke is transmitted along the smoke passage to allow the user to suction through the nozzle assembly 300. .

In order to facilitate the user to add the oil to the oil storage chamber 208, the oil storage assembly 200 faces the end surface of the nozzle assembly 300 and is provided with a fueling hole 217 communicating with the oil reservoir 208.

The nozzle assembly 300 is disposed on the oiling hole 217 and is sleeved with one end of the vent pipe 202.

The atomization assembly shown in the embodiment of the present invention is further provided with an exhaust groove, and the arrangement of the exhaust groove shown in this embodiment has two structures.

5 to FIG. 7 , wherein FIG. 7 is a schematic exploded view of an embodiment of the atomizing assembly provided by the present invention.

An exhaust groove 1200 disposed along a longitudinal extension of the atomizing assembly is disposed at a junction of the nozzle assembly 300 and the vent tube 202.

Specifically, the exhaust groove 1200 is disposed at an end of the nozzle assembly 300 near the vent pipe 202, and the exhaust groove 1200 is in communication with the first air passage 313.

As shown in FIG. 5, when the nozzle assembly 300 is detached from the oil storage assembly 200, the oil can be added to the oil reservoir 208 through the fuel filler port 217.

As shown in FIGS. 6 and 7, air in the oil reservoir 208 can pass through the fuel filler port 217 and the exhaust gas tank 1200 during connection of the nozzle assembly 300 to the oil reservoir assembly 200. Flowing into the smoke passage, and after the nozzle assembly 300 and the oil storage assembly 200 are inserted into a preset position, the exhaust groove 1200 is blocked by the vent pipe end 202, thereby automatically The passage between the exhaust slot 1200 and the smoke passage is closed.

The preset position is a position at which the nozzle assembly 300 is successfully connected to the oil storage assembly 200.

It can be seen that, in the process of connecting the nozzle assembly 300 to the oil storage assembly 200 by using the atomization assembly shown in this embodiment, the gas in the oil reservoir 208 can be timely from the fuel filler port 217. And the exhausting tank 1200 is discharged, thereby avoiding the situation that the gas is not discharged in time, so that the undischarged gas is pressed into the oil in the oil storage chamber 208, thereby effectively preventing the gas from being squeezed by the gas. The leakage of the smoke oil under the action of the gas pressure, the flow of the specific gas discharged through the exhaust groove 1200, as shown by the arrow shown in FIG.

12 is a schematic view showing a cross-sectional explosive connection structure of another embodiment of the atomization assembly provided by the present invention, and FIG. 13 is another embodiment of the atomization assembly provided by the present invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 14 is a schematic cross-sectional view of a cross-sectional exploded connection structure of another embodiment of an atomizing assembly according to the present invention.

A venting groove 1201 is provided at a junction of the nozzle assembly 300 and the vent tube 202 along a longitudinal extension of the atomizing assembly.

Specifically, the exhaust groove 1201 is disposed at an end of the vent pipe 202 near the nozzle assembly 300, and the exhaust groove 1201 is in communication with the second air passage 2021.

As shown in FIG. 12, when the nozzle assembly 300 is detached from the oil storage assembly 200, the oil can be added to the oil reservoir 208 through the fuel filler port 217.

As shown in FIGS. 13 and 14, when the nozzle assembly 300 is connected to the oil storage assembly 200 During the process, air in the oil reservoir 208 can flow into the smoke passage through the fuel filler 217 and the exhaust groove 1201, and when the nozzle assembly 300 is inserted into the oil storage assembly 200 After the preset position, the exhaust slot 201 is blocked by the end of the nozzle assembly 300, thereby automatically closing the passage between the exhaust slot 1201 and the smoke passage.

It can be seen that, in the process of connecting the nozzle assembly 300 to the oil storage assembly 200 by using the atomization assembly shown in this embodiment, the gas in the oil reservoir 208 can be timely from the fuel filler port 217. And the exhaust groove 1201 is discharged, thereby avoiding the situation that the gas is not discharged in time, so that the undischarged gas is pressed into the oil in the oil storage chamber 208, thereby effectively preventing the smoke from being squeezed by the gas. The smoke oil leaks under the action of the gas pressure, and the flow direction of the specific gas discharged through the exhaust groove 1201 is shown by the arrow shown in FIG.

Continuing to refer to FIGS. 1 through 6, the other end of the atomizing core assembly 500 is detachably inserted into the connecting assembly 400.

In this embodiment, the connecting assembly 400 is detachably coupled to the atomizing core assembly 500 and the oil storage assembly 200, respectively, such that when the connecting assembly 400 is detached from the oil storage assembly 200 The connection assembly 400 can be detached from the oil storage assembly 200 together with the atomization core assembly 500, that is, the connection assembly 400 can remove the atomization core assembly 500 from the oil storage assembly 200. Removed.

When the connecting assembly 400 is detached from the oil storage assembly 200 together with the atomizing core assembly 500, the atomizing core assembly 500 can be further detached from the connecting assembly 400, thereby realizing The detachable component of the atomizing assembly.

The embodiment of the present invention is not limited to how the connection assembly 400 is detachably connected to the atomization core assembly 500 and the oil storage assembly 200, for example, by any means or combination of threads, snaps, magnets, and the like. .

It can be seen that the disassembly of the nozzle assembly 300, the oil storage assembly 200, the connection assembly 400, and the atomization core assembly 500 can be conveniently implemented by using the atomization assembly shown in this embodiment, thereby enabling the user to Conveniently replacing or cleaning the nozzle assembly 300, the oil storage assembly 200, the The connecting assembly 400 and the atomizing core assembly 500 effectively improve the service life of the atomizing assembly and the hygienic use.

Moreover, the existing smoky oil has a plurality of flavors, and if the smoky oil stored in the atomizing component has the taste A, and the taste of the smoky oil added by the user to the oil storage component 200 is B, and the tastes of A and B are not Similarly, in this embodiment, the user can disassemble the atomization core assembly 500 from the connection assembly 400 and the oil storage assembly 200, so that the user can clean the atomization core assembly 500. The cleaning of the remaining smoke oil of the atomizing core assembly 500 does not cause the occurrence of the situation that the A flavor remaining on the atomizing core assembly 500 is mixed with the B flavor stored in the oil storage assembly 200, thereby effectively improving the suction. The taste of the smoke.

Embodiment 2 This embodiment describes in detail the specific structure of the atomization component:

The specific structure of the oil storage assembly 200 provided by the present embodiment will be described in detail below with reference to FIG. 8 and FIG.

8 is a partial cross-sectional structural view of an embodiment of an atomizing assembly provided by the present invention, and FIG. 11 is a schematic view showing a partial exploded connection structure of another embodiment of the atomizing assembly provided by the present invention.

The oil storage assembly 200 includes an oil storage jacket 201, a vent pipe 202, a first connecting seat 203, and a second connecting seat 204.

The vent tube 202 is inserted into the oil storage jacket 201 and communicates with the atomizing core assembly 500.

In this embodiment, an oil reservoir 208 capable of storing smoke oil is formed between the vent pipe 202 and the oil storage jacket 201.

Optionally, the oil storage sleeve 201 can be made of a transparent material, so that the user can view the amount of remaining oil stored in the oil storage chamber 208 at any time, thereby improving the convenience of the user during use.

Specifically, one end of the vent tube 202 is in communication with the nozzle assembly 300, and the other end of the vent tube 202 is in communication with the atomizing core assembly 500 to atomize the atomizing core assembly 500. Smoke is conducted to the nozzle assembly 300 via the vent tube 202.

One end of the oil storage sleeve 201 is connected to the first connecting base 203, and the other end of the oil storage sleeve 201 is connected to the second connecting base 204. The first connecting base 203 is Connection group The piece 400 is detachably connected.

The following is a detailed description of how the oil storage assembly 200 and other components of the atomizing assembly are connected:

Continuing to refer to FIG. 7, one end outer surface of the vent tube 202 is provided with a first externally threaded section 205.

The second connecting seat 204 is provided with a first internal thread segment 207, and the nozzle assembly 300 is provided with a second internal thread segment 301, and the second connecting seat 204 is sleeved on the vent pipe 202.

The second internally threaded section 301 of the nozzle assembly 300 is threaded onto the first externally threaded section 205 of the vent tube 202 to connect the nozzle assembly 300 to the vent tube 202.

Optionally, the second internal thread segment 301 is provided with the exhaust groove 1200 disposed along a longitudinal extension of the atomization assembly.

The nozzle assembly 300 is detachably inserted into one end of the second connecting base 204, and the nozzle assembly 300 is connected to the first externally threaded section 205 by the second internal thread section 301.

In order to improve the stability of the structure of the atomizing assembly, the first outer thread segment 205 is disposed away from the end of the nozzle assembly 300 with a first limiting protrusion 206, and one end of the second connecting seat 204 is abutted. Holding on the first limiting protrusion 206.

The first limiting protrusion 206 can effectively prevent the nozzle assembly 300 from moving toward the oil storage assembly 200, effectively improving the structure between the nozzle assembly 300 and the oil storage assembly 200. Stability.

Optionally, as shown in FIG. 12 to FIG. 14 , the first externally threaded section 205 is disposed at an end of the nozzle assembly 300 with the exhaust groove 1201 extending along a longitudinal direction of the atomizing assembly. .

It can be seen that the atomizing assembly shown in this embodiment can be used, and the nozzle assembly 300 can be detached from the oil storage assembly 200, thereby facilitating the user to replace or clean the nozzle assembly 300, thereby effectively improving the atomization. The life and use of the components are hygienic.

Moreover, when the user removes the nozzle assembly 300 from the oil storage assembly 200, the fuel filler port 217 at the port of the oil reservoir 208 may leak out, and the user may pass the smoke oil through the chamber. The fuel filler port 217 is added to the interior of the oil storage chamber 208. It can be seen that, in the manner of adding the smoke oil in the prior art, the present embodiment does not need to disassemble the remaining components in the process of adding the smoke oil, and only needs to be described. Suck The mouth assembly 300 can be detached from the oil storage assembly 200, effectively improving the efficiency of the user to add the oil, and is convenient for the user to operate, and the user does not need to touch the atomizing core assembly during the process of adding the oil. 500, so that the user's hand does not touch the smoke oil on the atomizing core assembly 500, effectively improving the user's experience in adding the smoke oil.

The nozzle assembly 300 is provided with the first air passage 313 extending in a longitudinal direction thereof and a first slot 304 communicating with the first air passage 313.

In order to prevent the user from smoking the oil, in the embodiment, the inner wall of the first air passage 313 is provided with an annular oil-blocking ring 303.

The angle formed by the oil damper 303 facing away from the end surface of the oil storage assembly 200 and the axial line of the nozzle assembly 300 is an acute angle, and the oil damper 303 is used to block the leakage of the oil storage assembly 200. The smoke oil and the condensed smoke oil are drained toward the oil storage assembly 200;

Specifically, if the smoke oil condenses in the first air passage 313 to form the smoke oil, the condensed smoke oil can be drained along the guiding edge of the oil damper 303 toward the oil storage assembly 200, thereby The condensed smoky oil is returned to the oil storage assembly 200, and the waste of the smoky oil can be effectively avoided while avoiding the user's consumption of the smoky oil, thereby effectively improving the use time of the smoky oil.

The vent tube 202 is inserted into the first slot 304, or the end of the vent tube 202 facing the nozzle assembly 300 and the end of the first slot 304 are mutually abutted so that The first air passage 313 is in communication with the vent tube 202.

It can be seen that the first air passage 313 shown in this embodiment is in communication with the second air passage 2021 in the snorkel 202, so that the smoke flowing through the second air passage 2021 is turned on. The first airway 313 is described to be used by the user.

A first sealing ring 210 is formed in a circular shape between the first slot 304 and the vent tube 202, and the second air passage 2021 is separated from the hollow position of the first sealing ring 210 by the first position An air passage 313 is turned on, and the first seal ring 210 elastically abuts against an inner wall of the nozzle assembly 300.

The first sealing ring 210 effectively prevents the smoke oil in the oil reservoir 208 from leaking into the nozzle assembly 300 and the inside of the vent pipe 202, thereby preventing the user from smoking the smoke oil through the nozzle assembly 300. .

The specific structure of the nozzle assembly 300 provided by the embodiment is described below:

The nozzle assembly 300 includes a nozzle body 305 and a second sealing ring 306.

One end outer circumferential surface of the nozzle body 305 is provided with a first annular groove 308.

The opening of the first annular groove 308 is disposed opposite to the inner wall of the second connecting seat 204.

The second sealing ring 306 is sleeved in the first annular groove 308 , and the second sealing ring 306 is elastically resisted by the inner wall of the second connecting seat 204 .

The specific structure of the second connector 204 will be described in detail below:

The second connecting base 204 includes an annular sleeve 212, and an inner wall of the sleeve 212 extends inwardly to form an annular oil blocking wall 213.

The oil blocking wall 213 can effectively prevent the leakage of the oil to the nozzle assembly 300.

An inner wall edge of the oil-repellent wall 213 extends away from the nozzle assembly 300 to form an annular connecting portion 214. The connecting portion 214 faces away from the end surface of the nozzle assembly 300 to resist the first limiting protrusion. From 206, the inner wall surface of the connecting portion 214 is provided with the first female thread segment 207.

One end of the nozzle assembly 300 is inserted into the sleeve body 212, and the sleeve body 212 is connected to the oil storage sleeve 201.

It can be seen that the structure of the second connecting base 204 shown in this embodiment can effectively prevent the second connecting base 204 from moving toward the oil storage assembly 200, avoiding thread misalignment and over-squeezing. The oil jacket effectively improves the stability of the structure of the atomizing assembly.

The following is a detailed description of how the sleeve 212 is connected to the oil storage sleeve 201:

The second connecting seat 204 is disposed away from the end surface of the nozzle assembly 300 and has an annular second slot 215.

A fourth sealing ring 216 is disposed in the second slot 215, and the oil storage sleeve 201 is detachably inserted into the second slot 215, and an end surface of the oil storage sleeve 201 is opposite to the first The four seal rings 216 are elastically abutted.

The structure shown in this embodiment can effectively prevent the leakage of the oil in the oil reservoir 208 along the gap between the second connector 204 and the oil reservoir 201 to the atomization assembly. Externally, the sealing of the oil reservoir 208 is effectively guaranteed.

As shown in FIG. 5, the oiling hole 217 shown in this embodiment is in communication with the oil reservoir 208.

The nozzle assembly when the nozzle assembly 300 is screwed onto the second connector 204 One end face of the 300 is disposed on the oiling hole 217.

As shown in FIG. 10, FIG. 10 is a partial structural schematic view of an embodiment of an atomizing assembly provided by the present invention.

When the user needs to add the oil to the oil reservoir 208, the nozzle assembly 300 is only required to be rotated to disassemble the nozzle assembly 300 from the second connector 204. The hole 217 is exposed, and at this time, the user can add the oil to the oil reservoir 208 through the oil hole 217.

The number of the oiling holes 217 can be set to be multiple, and the aperture is also relatively large, thereby effectively improving the efficiency of the user to add the smoke oil, and is convenient for the user to operate.

Moreover, the atomizing core assembly 500 shown in this embodiment is disposed at a position away from the oiling hole 217, that is, the atomizing core assembly is not disposed near the end of the oiling hole 217, thereby adding smoke. During the process of the oil, it is not blocked by the atomizing core assembly 500, and the number of the oiling holes 217 is large, so that the formation of air bubbles in the oil storage chamber 208 after the addition of the smoke oil can be prevented, thereby affecting the appearance.

In this embodiment, as shown in FIG. 5 and FIG. 7 , an excessive wall 221 is formed between the end surface of the sleeve body 212 and the oil-repellent wall 213, thereby allowing the user to add smoke oil to the oil-filling hole 217. At the same time, the smoke oil will flow through the excess wall 221 to flow into the oiling hole 217. It can be seen that during the process of adding the oil, there will be a buffering time, and under the action of the buffering time, the smoke oil will uniformly and continuously flow in. The oiling hole 217 does not cause oiling, thereby saving smoke oil, and effectively avoiding the situation where the user's hand touches the emerging oil in the process of adding the oil.

a distance between the end surface of the vent pipe 202 adjacent to the nozzle assembly 300 and an end surface of the nozzle assembly 300 facing away from the oil storage assembly 200 is a first distance;

The distance between the oiling hole 217 and the end surface of the nozzle assembly 300 facing away from the oil storage assembly 200 is a second distance, and the first distance is smaller than the second distance.

That is, when the nozzle assembly 300 is detached from the second connecting base 204, the end surface of the vent pipe 202 adjacent to the nozzle assembly 300 is higher than the end surface of the oiling hole 217, thereby allowing the user to When the oiling hole 217 is added with the smoky oil, the smoky oil is not easily dripped in the snorkel 202, and the possibility of the user taking the smoky oil is further avoided.

With continued reference to FIG. 8, the first connector 203 is provided with a second annular groove 218 toward the end of the nozzle assembly 300.

A fifth sealing ring 219 is sleeved in the second annular groove 218.

The fifth sealing ring 219 is elastically resisted from the end of the oil storage sleeve 201 away from the nozzle assembly 300.

The specific structure of the atomizing core assembly 500 will be described in detail below with reference to FIGS. 6 and 9.

The atomizing core assembly 500 includes an atomizing cover 501 and an atomizing core sleeve 502. One end of the atomizing cover 501 is inserted and fixed at an end of the vent pipe 202 away from the nozzle assembly 300. The other end of the cover 501 is connected to the atomizing core sleeve 502.

The end of the atomizing cover 501 away from the nozzle assembly 300 is provided with a second limiting protrusion 503, and the end of the atomizing core sleeve 502 adjacent to the nozzle assembly 300 is in the second The second limiting protrusion 503 is configured to prevent the atomizing core sleeve 502 from moving along an end portion of the nozzle assembly 300.

It can be seen that the structure shown in this embodiment can effectively improve the stability of the structure of the atomization core assembly 500, and effectively improve the service life of the atomization assembly.

An oil storage cotton 504 is disposed in the atomization core sleeve 502.

At least one oil passage 505 is disposed through the peripheral wall of the atomization core sleeve 502 to enable the smoke oil stored between the oil reservoir 201 and the vent pipe 202 to be electrically connected via the oil passage 505 To the oil storage cotton 504.

An atomizing space 506 is provided through the axial direction of the oil absorbing cotton 504.

The atomizing space 506 is internally provided with a heating wire 507, so that the mist atomized by the heating wire 507 is sequentially turned on to the atomizing core sleeve 502, the atomizing cover 501 and the vent pipe 202 to The nozzle assembly 300;

Optionally, the heating wire 507 shown in this embodiment has a cylindrical structure, thereby effectively improving the area of the heating wire 507 and the oil storage cotton 504, and avoiding the heating wire 507 being empty. Burning to generate a harmful gas, and because the heating wire 507 is in uniform contact with the oil storage 504, the smoke atomized by the heating wire 507 is uniform, which enhances the taste of the user in the process of smoking the smoke.

The outer peripheral wall of the atomizing cover 501 is provided with a third annular groove 508.

A sixth sealing ring 509 is sleeved in the third annular groove 508, and the sixth sealing ring 509 is elastically resisted by the vent pipe 202.

By providing the sixth sealing ring 509, the snorkeling of the snorkel 202 can be effectively prevented, and the smoke with uniform concentration can be effectively ensured to be connected to the nozzle assembly 300, thereby effectively improving the taste of the user. .

The specific structure of the connecting component 400 will be further described in detail below with reference to FIG. 6 and FIG. 11. FIG. 11 is a schematic diagram of a partial exploded connection structure of another embodiment of the atomizing component provided by the present invention.

The connection assembly 400 includes a first connector 401 and a second connector 402 made of a conductive material.

The second connecting member 402 is movably sleeved on the outer peripheral wall of the first connecting member 401.

A first through hole 403 communicating with the atomizing space is disposed through the first connecting member 401 , and a second through hole 404 is disposed through the second connecting member 402 .

When the second connecting member 402 is rotated, the overlapping area of the first through hole 403 and the second through hole 404 can be adjusted to adjust the amount of intake air of the atomizing assembly.

It can be seen that the atomization assembly shown in this embodiment can effectively adjust the intake air amount of the atomization assembly, thereby enabling the user to adjust the smoke by adjusting the overlapping area of the first through hole 403 and the second through hole 404. Concentration, because different people have different requirements on the concentration of smoke, so that the atomization assembly shown in this embodiment can meet the user's demand for different smoke concentrations, meet the personalized needs of the user, and effectively protect the user. The smoke concentration can be adjusted.

The first connecting member 401 is disposed near the inner peripheral wall of the end of the nozzle assembly 300 with a third internal thread segment 405.

The atomizing core sleeve 502 is disposed away from the outer peripheral wall of the end of the nozzle assembly 300 with a second externally threaded section 510.

The third internally threaded section 405 of the first connector 401 is threaded onto the second externally threaded section 510 of the atomizing core sleeve 502.

The first connecting member 401 is provided with a third externally threaded section 407 near the outer peripheral wall of the end of the nozzle assembly 300.

The inner peripheral wall of the first connecting seat 203 is provided with a fourth female thread segment 220, and the third outer thread segment 407 of the first connecting member 401 is screwed to the fourth of the first connecting seat 203 The internal thread section 220 is on.

A fourth annular groove 408 is disposed on the outer peripheral wall of the end of the first connector 401 adjacent to the nozzle assembly 300.

A seventh sealing ring 409 is sleeved in the fourth annular groove 408 , and the seventh sealing ring 409 is elastically resisted by the first connecting seat 203 .

As shown in FIG. 5, the inner peripheral wall of the first connecting member 401 near the end of the nozzle assembly 300 is provided with a fifth annular groove 410, and the fifth annular groove 410 is sleeved with an eighth seal. The ring 411 and the eighth sealing ring 411 are elastically resisted by the atomizing core sleeve 502.

The first connecting member 401 is interference-fitted with the atomizing core assembly 500 by the eighth sealing ring 411, thereby effectively avoiding the possibility of shaking of the atomizing core assembly 500, effectively ensuring the smoke concentration. Stable.

The outer peripheral wall of the first connecting member 401 is provided with at least one sixth annular groove 412, the sixth annular groove 412 is sleeved with a ninth sealing ring 413, and the ninth sealing ring 413 is The second connecting member 402 is elastically resisted.

This embodiment is exemplified by taking the number of the ninth sealing rings 413 as two as an example.

In this embodiment, the structure between the first connecting member 401 and the second connecting member 402 is stabilized by the ninth sealing ring 413, and if the user rotates the second connecting member 402, the atomizing assembly is advanced. When the air volume is adjusted to the optimal state, the ninth sealing ring 413 is resisted, thereby effectively preventing the second connecting member 402 from rotating along the first connecting member 401, thereby ensuring the stability of the intake air amount. In addition, it effectively protects the smoke concentration from being satisfied by users.

The target end portion of the first connecting member 401 is provided with a third limiting protrusion 414 , and the target end portion of the first connecting member 401 and the second connecting member 402 are away from the end of the nozzle assembly 300 . correspond.

The second connecting member 402 is disposed on the third limiting protrusion 414 away from the end of the nozzle assembly 300. The third limiting protrusion 414 is annular in the embodiment. The first connecting member 401 is rotatable along the guiding of the third limiting protrusion 414.

The third limiting protrusion 414 is configured to prevent the second connecting member 402 from being away from the nozzle assembly The end of the 300 is moved to effectively ensure the stability of the structure between the first connector 401 and the second connector 402.

The electrical connection structure of the atomization assembly will be described in detail below:

Optionally, the following is combined with Figure 5 and Figure 11:

The atomizing core assembly 500 further includes a first inner electrode 415 and a first insulating ring 417;

The first insulating ring 417 is used to electrically isolate the first inner electrode 415 and the first connecting member 401.

The first inner electrode 415 is inserted at an end of the atomization core sleeve 502 away from the nozzle assembly 300, and the atomization core sleeve 502 and the first inner electrode 415 are disposed between The first insulating ring 417.

A third through hole 419 is disposed through the first inner electrode 415 such that an air flow outside the atomization assembly is sequentially conducted to the second through hole 404, the first through hole 403, and the third through hole 419 to The atomization space 506.

The connection assembly 400 further includes a second inner electrode 416 and a second insulating ring 418.

Specifically, the second inner electrode 416 is disposed opposite to the end of the first inner electrode 415 away from the nozzle assembly 300, and the first connecting member 401 and the second inner electrode 416 are The second insulating ring 418 is disposed therebetween.

The second insulating ring 418 is used to electrically isolate the first connecting member 401 and the second inner electrode 416.

In order to enable the heating wire 507 to atomize the smoke oil to form a smoke, both ends of the heating wire 507 are electrically connected to the first connecting member 401 and the first inner electrode 415, respectively.

Embodiment 3, this embodiment further provides an electronic cigarette, the electronic cigarette comprising an atomizing component and a battery component, wherein the battery component is configured to supply power to the atomizing component to atomize the atomizing component To form a smoke, and the atomizing assembly is detachably coupled to the battery assembly.

The specific structure of the battery component is not limited in this embodiment, as long as the battery component can supply power to the atomization component, and the specific structure of the atomization component can be as shown in the first embodiment to the second embodiment. It will not be described in detail in this embodiment.

It will be apparent to those skilled in the art that the above description is convenient and concise for the description. For the specific working process of the system, the device and the unit, reference may be made to the corresponding process in the foregoing method embodiment, and details are not described herein again.

The above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to be limiting; although the present 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 solutions are described as being modified, or equivalent to some of the technical features, and the modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims

An atomizing assembly for forming an electronic cigarette in combination with a battery assembly, comprising: a nozzle assembly, an oil storage assembly, an atomizing core assembly and a connecting assembly, wherein the nozzle assembly is detachably connected to the oil storage a first air passage for discharging smoke is disposed in the nozzle assembly, and the atomizing core assembly is inserted into the oil storage assembly for atomizing the oil in the oil storage assembly. One end of the connecting component is connected to an end of the oil storage component opposite to the position of the nozzle assembly, and the other end of the connecting component is connected to the battery component;

An oil storage chamber and a vent pipe for discharging the atomization atomization of the atomization core assembly into the nozzle assembly are disposed in the oil storage assembly, and the first air passage is formed in the snorkel a second air passage communicating with the second air passage, the first air passage and the second air passage forming a smoke passage, wherein the oil storage assembly is disposed at an end surface of the nozzle assembly and is connected to the oil storage chamber a fueling hole, the nozzle assembly is disposed on the oiling hole and is sleeved with one end of the vent pipe;

a venting groove disposed along a longitudinal extension of the atomizing assembly is disposed at a junction of the nozzle assembly and the vent tube, and the venting groove is disposed at an end of the nozzle assembly adjacent to the snorkel And the exhaust groove is in communication with the first air passage, or the exhaust groove is disposed at an end of the air pipe adjacent to the nozzle assembly, and the exhaust groove and the first The two air passages are in communication such that air in the oil reservoir can flow into the smoke through the fuel filler port and the exhaust groove during connection of the nozzle assembly to the oil storage assembly In the passage, and after the nozzle assembly and the oil storage assembly are inserted into the preset position, the exhaust groove is blocked by the end of the vent pipe or the end of the nozzle assembly, thereby automatically The passage between the venting channel and the smoke passage is closed.
The atomizing assembly according to claim 1, wherein the oil storage assembly comprises an oil storage sleeve, the vent pipe, a first connecting seat and a second connecting seat, the snorkel and the oil storage sleeve Forming the oil storage chamber therebetween;

One end of the oil storage sleeve is connected to the first connecting seat, and the other end of the oil storage sleeve is connected to the second connecting seat. The first connecting seat and the connecting component are detachable. connection;

One end outer surface of the vent pipe is provided with a first outer thread segment, and the first outer thread segment is provided with a first limiting protrusion away from the end of the nozzle assembly, and the second connecting seat is provided with a first internal thread segment, the nozzle assembly is provided with a second internal thread segment, and the second connecting seat is sleeved on the ventilation tube And connecting, by the first internal thread segment, the first externally threaded segment, one end of the second connecting seat abuts on the first limiting protrusion, and the nozzle assembly is detachably inserted At one end of the second connector, the nozzle assembly is coupled to the first externally threaded section by the second internally threaded section.
The atomizing assembly of claim 2 wherein said second internally threaded section is disposed toward said end of said vent tube with said venting groove disposed along a longitudinal extent of said atomizing assembly.
The atomizing assembly of claim 2 wherein said first outer threaded section is disposed toward said end of said nozzle assembly with said venting groove disposed along a longitudinal extent of said atomizing assembly.
The atomizing assembly according to claim 1, wherein said nozzle assembly is provided with said first air passage extending in a longitudinal direction thereof and a first slot communicating with said first air passage, An inner wall of the first air passage is provided with an annular oil damper, and an angle formed between an end surface of the oil damper facing away from the oil storage assembly and an axial line of the nozzle assembly is an acute angle, The oil damper is configured to block the smoke oil leaking from the oil storage assembly and to drain the condensed oil in the direction of the oil storage assembly, the vent pipe is inserted in the first slot to make the snorkel The second air passage is in communication with the first air passage.
The atomizing assembly according to claim 5, wherein a first sealing ring is formed in a circular shape between the first slot and the vent pipe, and the second air passage is via the first A hollow position of a seal ring is electrically connected to the first air passage, and the first seal ring is elastically abutted against an inner wall of the nozzle assembly.
The atomizing assembly according to claim 2, wherein the nozzle assembly comprises a nozzle body and a second sealing ring, and an outer circumferential surface of one end of the nozzle body is provided with a first annular groove, An opening of an annular groove is disposed opposite the inner wall of the second connecting seat, the second sealing ring is sleeved in the first annular groove, and the second sealing ring and the second connecting seat The inner wall is elastically resisted.
The atomizing assembly according to claim 2, wherein said second connecting seat comprises an annular sleeve body, and an inner wall of said sleeve body extends inwardly to form an annular oil-repellent wall, said oil-repellent wall The inner wall edge extends away from the nozzle assembly to form an annular connecting portion, and the connecting portion faces away from the end surface of the nozzle assembly against the first limiting protrusion, and the inner wall surface of the connecting portion is disposed Having the first internal thread segment, one end of the nozzle assembly is inserted into the sleeve body, the sleeve body and the oil storage sleeve Plug and connect.
The atomizing assembly according to claim 8, wherein the second connecting seat is provided with an annular second slot away from the end surface of the nozzle assembly, and a fourth seal is disposed in the second slot. The oil storage sleeve is detachably inserted into the second slot, and an end surface of the oil storage sleeve is elastically abutted with the fourth sealing ring.
The atomizing assembly according to claim 9, wherein a distance between the end surface of the vent pipe adjacent to the nozzle assembly and an end surface of the nozzle assembly facing away from the oil storage assembly is a first distance, The distance between the oiling hole and the end surface of the nozzle assembly facing away from the oil storage assembly is a second distance, and the first distance is smaller than the second distance.
The atomizing assembly according to claim 2, wherein the first connecting seat is provided with a second annular groove toward the end of the nozzle assembly, and the second annular groove is sleeved with the second a five seal ring, and the fifth seal ring is elastically resisted from the end of the oil reservoir sleeve away from the nozzle assembly.
The atomizing assembly according to claim 1, wherein the atomizing core assembly comprises an atomizing cover and an atomizing core sleeve, and one end of the atomizing cover is inserted and fixed to the vent pipe away from the suction An end of the nozzle assembly, the other end of the atomization cover is connected to the atomization core sleeve, and the atomization cover is disposed at a distal end of the nozzle assembly with a second limiting protrusion, the atomization The end of the core sleeve adjacent to the nozzle assembly abuts against the second limiting protrusion, the second limiting protrusion is configured to prevent the atomizing core sleeve from being adjacent to the end of the nozzle assembly mobile;

An oil storage cotton is disposed in the atomization core sleeve, and at least one oil passage hole is disposed through a peripheral wall of the atomization core sleeve to make the oil oil stored between the oil storage sleeve and the ventilation tube The oil absorbing cotton can be electrically connected to the oil storage cotton, and an atomizing space is disposed along the axial direction of the oil absorbing cotton, and the electric heating wire is disposed inside the atomizing space, so that the electric heating wire is The atomized smoke is sequentially conducted to the nozzle assembly via the atomizing core sleeve, the atomizing cover and the vent tube;

The outer peripheral wall of the atomizing cover is provided with a third annular groove, and the third annular groove is sleeved with a sixth sealing ring, and the sixth sealing ring is elastically resisted by the vent pipe.
The atomizing assembly according to claim 12, wherein the connecting assembly comprises a first connecting member and a second connecting member made of a conductive material, and the second connecting member is movably disposed on the first connecting member a peripheral wall of a connecting member disposed through the first connecting member and communicating with the atomizing space a first through hole, wherein the second connecting member is provided with a second through hole, so that when the second connecting member is rotated, an overlapping area of the first through hole and the second through hole can be adjusted to adjust the fog The amount of intake air of the component.
The atomizing assembly according to claim 13, wherein the first connecting member is disposed adjacent to an inner peripheral wall of the end of the nozzle assembly with a third internal thread segment, and the atomizing core sleeve is away from the nozzle The end outer peripheral wall of the assembly is provided with a second externally threaded section, and the third internal threaded section of the first connecting member is screwed onto the second externally threaded section of the atomizing core sleeve;

The first connecting member is disposed near the outer peripheral wall of the end of the nozzle assembly with a third externally threaded portion, and the inner peripheral wall of the first connecting seat is provided with a fourth internal thread segment, the first connecting member The third outer threaded section is threaded onto the fourth female threaded section of the first connector.
The atomizing assembly according to claim 13 or 14, wherein the first connecting member is provided with a fourth annular groove adjacent to the outer peripheral wall of the end of the nozzle assembly, the fourth annular groove The inner sleeve is provided with a seventh sealing ring, and the seventh sealing ring is elastically resisted by the first connecting seat;

a fifth annular groove is disposed on an inner peripheral wall of the first connecting member near an end of the nozzle assembly, and an eighth sealing ring is disposed in the fifth annular groove, and the eighth sealing ring is The atomizing core sleeve is elastically resisted.
The atomizing assembly according to claim 13 or 14, wherein the outer peripheral wall of the first connecting member is provided with at least one sixth annular groove, and the sixth annular groove is provided with a ninth seal. a ring, and the ninth sealing ring is elastically resisted by the second connecting member.
The atomizing assembly according to claim 16, wherein the target end of the first connecting member is provided with a third limiting protrusion, and the target end of the first connecting member is connected to the second end Corresponding to the end of the nozzle assembly corresponding to the end of the second connecting member away from the nozzle assembly, the third limiting protrusion is used for the third limiting protrusion The second connecting member is prevented from moving along an end away from the nozzle assembly.
The atomizing assembly according to claim 17, wherein the atomizing core assembly further comprises a first inner electrode and a first insulating ring;

The connection assembly further includes a second inner electrode and a second insulating ring, and the first inner electrode and the second inner electrode are electrically connected to each other;

The first inner electrode is inserted at an end of the atomizing core sleeve away from the nozzle assembly, and the first insulating ring is disposed between the atomizing core sleeve and the first inner electrode. Providing a third through hole through the first inner electrode such that an air flow outside the atomization assembly is sequentially conducted to the atomization space via the second through hole, the first through hole, and the third through hole ;

The second inner electrode is disposed to be opposite to the end of the first inner electrode away from the nozzle assembly, and the second insulation is disposed between the first connecting member and the second inner electrode a ring, two ends of the heating wire are electrically connected to the first connecting member and the first inner electrode, respectively.
An electronic cigarette characterized by comprising an atomizing component and a battery component, the battery component for supplying power to the atomizing component to atomize the atomizing component to form smoke, and the atomizing The component is detachably connected to the battery component;

The atomizing assembly is as claimed in any one of claims 1 to 18.