CN215455387U - Electronic atomization device and atomization assembly thereof - Google Patents

Abstract

The utility model discloses an electronic atomization device and an atomization assembly thereof, wherein the atomization assembly comprises a soft atomization seat, a breather pipe, an atomization core and a liquid storage box, and the atomization seat comprises an air inlet; the atomization assembly further comprises a supporting pipe, wherein the supporting pipe penetrates through the air inlet hole along the axial direction and is tightly matched with the hole wall of the air inlet hole so as to prevent the hole wall from deforming. According to the utility model, the supporting tube which is tightly matched with the hole wall of the air inlet hole is arranged in the air inlet hole, so that the reduction of the aperture of the air inlet hole caused by the contraction of the atomizing base under the action of external force is avoided, good resistance to inhalation is ensured, and the stability of air flow in the process of inhalation is improved.

Description

Electronic atomization device and atomization assembly thereof

Technical Field

The present disclosure relates to an atomizing device, and more particularly, to an electronic atomizing device and an atomizing assembly thereof.

Background

The electronic atomization device in the related art comprises an atomization assembly, wherein the atomization assembly comprises a soft atomization seat, an atomization core, a breather pipe, a liquid storage box and the like, the atomization core, the breather pipe, the liquid storage box and the like are mounted on the atomization seat, and the atomization seat is provided with a longitudinally through air inlet hole. This atomizing subassembly satisfies the user demand that uses to a certain extent, however, because the atomizing seat is soft, when breather pipe or stock solution casket were installed on the atomizing seat, brought pressure for the atomizing seat easily, atomizing seat pressurized deformation can arouse the change in inlet port aperture to lead to the uniformity of product poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an improved electronic atomization device and an atomization assembly thereof.

In order to achieve the purpose, the utility model provides an atomization component, which comprises a soft atomization seat, a vent pipe, an atomization core and a liquid storage box, wherein the atomization seat comprises an air inlet; the atomization assembly further comprises a supporting pipe, wherein the supporting pipe penetrates through the air inlet hole along the axial direction and is tightly matched with the hole wall of the air inlet hole so as to prevent the hole wall from deforming.

In some embodiments, the air inlet hole penetrates from the bottom surface to the top surface of the atomizing base, and the support pipe fills the whole length of the air inlet hole.

In some embodiments, the support tube comprises a stainless steel tube.

In some embodiments, the atomizing base comprises a body part and a columnar mounting part erected on the top surface of the body part, the air inlet hole extends from the bottom surface of the body part to the top surface of the mounting part, and the support pipe fills the whole length of the air inlet hole; the lower end of the breather pipe is sleeved on the installation part, and the lower end of the liquid storage box is sleeved on the body part.

In some embodiments, the vent pipe comprises a pipe body with a bevel cut and a reinforcing pipe sleeved on the bevel cut, and the pipe body is further provided with a pair of mounting holes for the atomizing core to transversely penetrate through the pipe body; the lower end of the pipe body is sleeved on the installation part.

In some embodiments, the atomizing core comprises a liquid absorbing part and a heating part wound on the liquid absorbing part, the liquid absorbing part is arranged in the mounting hole in a penetrating manner, and the heating part is exposed in the pipe body.

In some embodiments, the liquid storage box comprises a sleeve body and a liquid storage piece, wherein the lower end of the sleeve body is sleeved on the atomizing base, and the liquid storage piece is filled between the inner wall surface of the sleeve body and the outer wall surface of the vent pipe; the lower end of the sleeve body is sleeved on the body part.

The electronic atomization device comprises a shell and the atomization assembly, wherein the atomization assembly is arranged in the shell.

In some embodiments, the microphone assembly further comprises a suction nozzle assembly, wherein the suction nozzle assembly comprises a suction nozzle provided with a suction channel and a microphone arranged on the suction nozzle.

In some embodiments, the housing includes an integrally formed back shell and an integrally formed face shell, and the face shell is disposed on the back shell to define a receiving cavity for receiving the atomizing assembly.

The utility model has the beneficial effects that: through set up the stay tube in the inlet port, avoid atomizing seat to result in the inlet port aperture to reduce when receiving the exogenic action shrink, guaranteed good inhaling hindering nature, still improved the air mass flow stability of inhaling the in-process simultaneously.

Drawings

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

FIG. 1 is a schematic perspective view of an electronic atomizer in accordance with a preferred embodiment of the present invention;

FIG. 2 is an exploded perspective view of the electronic atomizer of FIG. 1;

FIG. 3 is a longitudinal cross-sectional view of the electronic atomizer of FIG. 1;

FIG. 4 is a schematic perspective view of the atomizing assembly of FIG. 2;

FIG. 5 is a schematic perspective view of the combination snorkel and atomizing core of the atomizing assembly of FIG. 2;

FIG. 6 is an exploded view of the combination snorkel and atomizing core shown in FIG. 5;

FIG. 7 is a perspective view of the nozzle assembly of FIG. 2;

FIG. 8 is a longitudinal cross-sectional view of the suction nozzle assembly shown in FIG. 7;

FIG. 9 is a schematic perspective view of an atomizing assembly in accordance with a preferred embodiment of the present invention;

fig. 10 is an exploded view of the atomizing assembly of fig. 9.

Detailed Description

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

Fig. 1-3 illustrate an electronic aerosol device 1 for a user to inhale an aerosol, which may include an aerosol assembly 10, a battery assembly 20, a nozzle assembly 30, and a housing 40, in some embodiments of the utility model. The aerosol generating assembly 10 is for storing an aerosol generating substrate and for heat atomising the aerosol generating substrate. The battery assembly 20 is electrically connected to the atomizing assembly 10 for supplying power to the atomizing assembly 10. The nozzle assembly 30 is mounted on the atomizing assembly 10 for guiding the aerosol, and the housing 40 is used for accommodating the atomizing assembly 10, the battery assembly 20 and the nozzle assembly 30. The electronic atomizer 1 may be a flat cylinder that is convenient to hold in some embodiments, and it is understood that it is not limited to this shape, and it may be other shapes such as a cylinder.

Figure 4 illustrates an atomising assembly 10 according to some embodiments of the utility model, the atomising assembly 10 being arranged to receive an aerosol-generating substrate and atomise the aerosol-generating substrate. The atomizing assembly 10 may include a soft atomizing base 11, and a vent tube 12, a support tube 13, an atomizing core 14 and a reservoir 15 mounted on the atomizing base 11.

The atomizing base 11 may be made of soft material such as silica gel in some embodiments, and has a cylindrical air inlet hole 110 penetrating up and down. The atomizing base 11 serves to carry the air tube 12, the atomizing core 14 and the reservoir 15. The atomizing base 11 may include a main body 111 with a substantially racetrack cross-section and a cylindrical mounting portion 112 with a smaller diameter standing on the top surface of the main body 111, the main body 111 may be sleeved with the cartridge 15, the mounting portion 112 may be sleeved with the vent pipe 12, and the air inlet 110 extends from the bottom surface of the main body 111 to the top surface of the mounting portion 112.

The vent pipe 12 is vertically arranged on the top surface of the atomizing base 11, the lower end of the vent pipe 12 is sleeved on the mounting part 112 of the atomizing base 11, the vent pipe 12 is communicated with the air inlet 110, and the vent pipe 12 is used for guiding air flow. It will be appreciated that air will flow into the vent tube 12 through the air inlet holes 110 and that air passing through the vent tube 12 will flow with the atomised aerosol-generating substrate out of the atomising assembly 10 for consumption by a user.

As shown in fig. 4, 5 and 6, the vent tube 12 may include a tube body 121 and a reinforcement tube 122 in some embodiments. A tube body 121 stands on the atomizing base 11, and the tube body 121 is used for guiding air to flow along the inner wall thereof. The tube body 121 is formed with an inclined cut 1210 and a mounting hole 1211, and the inclined cut 1210 is formed to break the tube body 121 during the assembling process so as to insert the atomizing core 14 into the mounting hole 1211. The reinforcing tube 122 is sleeved on the oblique notch 1210, and the reinforcing tube 122 is used for preventing the tube body 121 from being bent or torn from the oblique notch 1210 and plays a role in protecting the tube body 121. The atomizing core 14 is disposed through the mounting hole 1211, such that the atomizing core 14 is transversely disposed through the tube 121.

It can be understood that after the atomization core 14 is put in, the reinforcing tube 122 is slid to a predetermined position of the tube body 121, so that the portion of the atomization core 14 exposed outside the tube body 121 can be clamped between the tube body 121 and the reinforcing tube 122, and the clamping and fixing of the atomization core 14 are completed.

The support tube 13 is in a cylindrical shape in some embodiments, and is disposed in the air inlet hole 110 and preferably fills the entire length of the air inlet hole 110, and the outer diameter of the support tube 13 is slightly larger than the diameter of the air inlet hole 110, so as to be tightly fitted with the hole wall of the air inlet hole 110 when the support tube is inserted into the air inlet hole 110, thereby preventing the change of the diameter of the air inlet hole 110 caused by the deformation of the soft atomizing base 1 when receiving external pressure. The external pressure may include the pressure of the vent tube 12 engaging the mounting portion 112 and the pressure of the sleeve 151 of the cartridge 15 engaging the body of the atomizing base 11. The support pipe 13 may be a single pipe, or two or more pipes may be sequentially inserted into the air inlet hole 110.

As shown in fig. 6, the atomizing core 14 may include a liquid absorbing member 141 and a heat generating member 142 in some embodiments. A liquid absorbing member 141 is perforated in the mounting hole 1211, and the liquid absorbing member 141 absorbs the aerosol-generating substrate. The heat generating member 142, which in some embodiments may be a heat filament, is wrapped around the central portion of the wicking member 141 and is energized to generate heat to heat and atomize the liquid aerosol-generating substrate drawn by the wicking member 141.

As will be appreciated, the portion of the wicking member 141 exposed to the exterior of the vent tube 12 will absorb the aerosol-generating substrate and deliver it to its respective location; when the heating element 142 is energized, the aerosol-generating substrate on the liquid absorbing element 141 is heated at a high temperature, so that the aerosol-generating substrate is atomized, and the atomized aerosol-generating substrate flows out of the atomizing assembly 10 along the ventilation tube 12 along with the air.

As shown in fig. 5 and 6, the wicking member 141 may be a cotton strand in some embodiments. It will be appreciated that the sponge stick may absorb and transport the aerosol-generating substrate to the location where the heat generating member 142 is located, and the heat generating member 142 may operate to heat and atomize the aerosol-generating substrate; of course, the liquid absorbing member 141 may be provided with other structures capable of absorbing and delivering the aerosol-generating substrate as in the prior art, as long as the aerosol-generating substrate can be delivered to the heat generating member 142 for thermal atomization.

As shown in fig. 4, the atomizing assembly 10 may further include a cartridge 15 in some embodiments, and the cartridge 15 includes a sleeve 151 and a reservoir 152. The lower end of the sleeve body 151 is sleeved on the atomizing base 11, and the sleeve body 151 plays a role of enclosing the liquid storage part 152, so that the aerosol generating substrate can be enclosed in a certain space all the time. The reservoir 152 is in contact with the atomizing cartridge 14 and functions to deliver the aerosol-generating substrate to the atomizing cartridge 14.

It will be appreciated that when the content of aerosol-generating substrate is low, aerosol-generating substrate located low within the housing 151 can still be delivered through the reservoir 152 into the vent tube 12 for nebulisation for inhalation by a user. As shown in fig. 4, the reservoir 152 may be a sponge block in some embodiments. As will be appreciated, the sponge mass is capable of absorbing and delivering the aerosol-generating substrate to itself at various locations, thereby enabling the aerosol-generating substrate to be delivered to the ventilation tube 12.

As shown in fig. 4, the support tube 13 may be a stainless steel tube in some embodiments. Understandably, the stainless steel pipe has the characteristics of high durability and strong corrosion resistance, and can improve the durability of products; meanwhile, the air inlet structure has the characteristics of easiness in processing and high strength, the aperture of the air inlet hole 110 can be kept constant, the stability of air inlet is ensured, and the consistency of products is improved.

The battery assembly 20 may include a battery 21 and a light emitting element 22 in some embodiments. The battery 21 and the light emitting element 22 are provided on the housing 40, respectively, and the battery 21 is used to supply power to the light emitting element 22 and other electric components. The light emitting element 22 is connected to the battery 21, and the light emitting element 22 emits light when energized. It is understood that the battery 21 may be a pouch battery or other device structure capable of serving as a power supply unit. The light emitting element 22 may be an LED lamp, and during the smoking process, the light emitting element 22 is powered on, so that the user can confirm the normal operation of the electronic atomization device 1.

As shown in fig. 2, the battery assembly 20 may further include a light guide 23 in some embodiments, the light guide 23 is disposed on the housing 40, and the light guide 23 is located above the light emitting element 22. It will be appreciated that the light guide 23 is capable of transmitting light emitted by the light emitting element 22 out of the housing 40 for easy viewing by a user. The light guide 23 may be made of an acryl material so that light can be uniformly diffused through the light guide 23.

As shown in fig. 4, the electronic atomizing device 1 may further include a suction nozzle assembly 30 in some embodiments, and the suction nozzle assembly 30 includes a suction nozzle 31 having a suction channel 311 and a microphone 32 disposed on the suction nozzle 31. The inhalation passage 311 communicates with the ventilation tube 12 and serves to direct a flow of air carrying the aerosolized aerosol-generating substrate into the mouth of the user. The microphone 32 is used to sense the flow of the airflow.

It will be appreciated that the microphone 32 will be switched on when it senses the flow of the airflow, thereby controlling the electronic atomising device 1 to atomise the aerosol-generating substrate and controlling the operation of electronic components such as the light emitting element. Specifically, the air suction channel 311 can be communicated with the sensing end of the microphone 32, so that the air flow can be timely sensed by the microphone 32.

As shown in fig. 7 and 8, the nozzle assembly 30 is used for the electronic atomizing device 1, in some embodiments, the nozzle assembly 30 may include a nozzle 31 and a microphone 32, the nozzle 31 further defines a sensing channel 312 communicated with the air suction channel 311, the microphone 32 is disposed on the nozzle 31, and a sensing end of the microphone 32 is communicated with the sensing channel 312 to sense the air flow in the air suction channel 311.

It can be understood that, when the user uses the product, the microphone 32 will sense the airflow change in the air suction channel 311 through the sensing channel 312, that is, the microphone 32 can sense the airflow flowing in the air suction channel 311 in time, so, when the user uses the product, the electronic atomization device 1 can atomize the aerosol generating substrate in time, and control the electronic components such as the light emitting element to work, thereby improving the reaction sensitivity of the product.

As shown in fig. 8, the side wall of the end of the sensing passage 312 is provided with an air diffusion amount inclined opening 3121, and the opening direction of the air diffusion amount inclined opening 3121 is set toward the air suction passage 311. It can be understood that the opening of the air diffusion amount inclined opening 3121 enlarges the size of the air exchange cross section between the end of the induction channel 312 and the outside of the channel, prevents the internal structure of the suction nozzle 31 from obstructing the air flow, improves the pressure synchronization degree of the induction channel 312 and the suction channel 311 as much as possible, and further improves the reaction sensitivity of the product.

As shown in fig. 7 and 8, the suction nozzle 31 further has a mounting groove 313, a wall of the mounting groove 313 is communicated with the suction channel 311, and the microphone 32 is embedded in the mounting groove 313. It can be understood that the shape of the mounting groove 313 may be designed to be a shape adapted to the microphone 32, so that the microphone 32 embedded in the mounting groove 313 can form a sealed state with the wall of the mounting groove 313, and the situation that the sensing end of the microphone 32 cannot sense the airflow flowing due to the connection of the mounting groove 313 with the outside is avoided.

As shown in fig. 7 and 8, the bottom of the mounting groove 313 is provided with a limit step 314 for supporting the housing of the microphone 32 when the microphone 32 is inserted into the mounting groove 313, so that a space is left between the sensing end of the microphone 32 and the bottom of the mounting groove 313. It can understand ground, the setting of spacing step 314 can avoid the response end of miaow head 32 and the tank bottom contact of mounting groove 313 and unable response air current flows, secondly, can also prevent that the shell of miaow head 32 from causing the jam to the port that induction channel 312 dew was arranged in mounting groove 313, ensures that miaow head 32 can sense the air current and flow.

As shown in fig. 7 and 8, the limiting step 314 is provided with a position avoiding gap 3141, and the position avoiding gap 3141 is communicated with the sensing channel 312. As can be understood, the clearance gap 3141 is formed, so that air between the bottom of the mounting groove 313 and the sensing end of the microphone 32 is communicated with air between the sensing channels 312, the air flowing is prevented from being blocked by the limiting step 314, the sensing end of the microphone 32 can sense the air flow in time, and the reaction sensitivity of the product is improved.

As shown in fig. 8, the suction nozzle 31 is made of a soft material, and the suction nozzle assembly 30 may further include a support pipe 33, the support pipe 33 being disposed in the suction passage 311, the support pipe 33 being for preventing the sidewall of the suction passage 311 from being deformed. It can be understood that, during the assembling process and the like of the suction nozzle 31, the suction nozzle may be squeezed by an external force, so that the suction channel 311 tends to deform under stress, and the support tube 33 can always tightly abut against the hole wall of the suction channel 311 to prevent the deformation of the suction channel 311; therefore, the technical problem of suction resistance increase caused by the deformation of the suction channel 311 can be prevented, and the consistency of products is improved. Preferably, the support tube 33 comprises a hollow column of stainless steel. Understandably, the stainless steel hollow column has the advantages of high strength and corrosion resistance, and the side wall of the air suction channel 311 is supported by the stainless steel hollow column, so that the service life of the product can be prolonged.

As further shown in fig. 2, the housing 40 may include a back shell 41 and a front shell 42, which are integrally formed, and the front shell 42 is covered on the back shell 41 to define a receiving cavity 43 for receiving the atomizing assembly 10. It is understood that the back shell 41 and the face shell 42 together function to protect the internal structure and the device of the electronic atomization device 1. It is also understood that the back shell 41 may be formed by assembling two or more parts formed by separate molding, or may be formed by directly molding by integral molding. The face shell 42 may be formed by integral molding or by separate molding and then assembled. The end of the housing 40 remote from the mouthpiece may be provided with an air inlet.

As shown in fig. 2, the back case 41 may be configured to be elongated in some embodiments, and the face case 42 may also be configured to be elongated, so that the back case 41 and the face case 42 are assembled together to define an elongated flat receiving cavity 43, the battery module 20, the atomizing module 10 and the nozzle module 30 are sequentially received in the receiving cavity 43, the atomizing module 10 is electrically connected to the battery module 20, and the nozzle module 30 is connected to the atomizing module 10 in an air-guiding manner.

It can be understood that the flat containing cavity 43 can be more stably contained with the battery assembly 20, the atomizing assembly 10 and the nozzle assembly 30, so as to eliminate the fit clearance between the battery assembly 20, the atomizing assembly 10 and the nozzle assembly 30 and the inner wall of the housing 40 as much as possible, avoid the three from shaking and deviating in the housing 40, and improve the stability and reliability of the product.

It can also be appreciated that the face shell and the back shell are separately formed by integral molding, which eliminates the complexity of assembling each split part in the later period, eliminates the fit clearance between the split parts, and avoids the aerosol generating substrate from leaking through the fit clearance between the split parts.

As shown in fig. 4, 9 and 10, the end surface of the atomizing base 11 opposite to the battery assembly may be further opened with a flared air inlet groove 1110 in some embodiments, and the air inlet hole 110 is located at the bottom of the flared air inlet groove 1110.

It can be understood that, the flared air inlet groove 1110 can prevent components such as a battery module from blocking air inlet of the air inlet hole 110, and prevent the suction resistance of the product from being too large.

As further shown in fig. 9 and 10, the wall of the flared inlet channel 1110 may be provided with a first inlet notch 1111 and a second inlet notch 1112 in some embodiments.

It can be understood that the air can also enter the flared air inlet groove 1110 through the first air inlet notch 1111 and the second air inlet notch 1112 and further flow into the air inlet hole 110, further ensuring the air inlet amount of the air inlet hole 110 and further reducing the suction resistance of the product.

As shown in fig. 9 and 10, in some embodiments, the atomizing base 11 may further have a transverse clearance groove 1113, and the transverse clearance groove 1113 intersects with the first air inlet notch 1111 and the second air inlet notch 1112 to form a cross shape. It will be appreciated that the opening of transverse clearance groove 1113 allows air to flow into flared inlet channel 1110 along the walls of transverse clearance groove 1113; secondly, the first air inlet notch 1111 and the second air inlet notch 1112 intersect to form a cross shape, so that air can flow into the air inlet 110 from each direction of each transverse empty avoiding groove 1113, and a product can keep low suction resistance.

As shown in fig. 9 and 10, in some embodiments, the atomizing base 11 includes a body 111 and a sealing ring 113 disposed on a circumferential direction of a sidewall of the body 111, a lower end of the cartridge 15 is sleeved on the body 111, and the sealing ring 113 tightly abuts against an inner sidewall of the cartridge 15.

It is understood that the seal ring 113 may be provided as soft; after the lower end of the cartridge 15 is fitted over the body 111, the seal ring 113 seals the cartridge 15 in the cross-sectional direction, so that the liquid aerosol-generating substrate can be accommodated in the cartridge 15, and leakage of the liquid aerosol-generating substrate is prevented.

As further shown in fig. 9 and 10, the aerosol mounting 11 in some embodiments further comprises a sealing skirt 114 disposed on the bottom surface of the body portion 111, the sealing skirt 114 being adapted to seal against the lower end of the cartridge 15 to prevent leakage of liquid aerosol-generating substrate from the lower end of the cartridge 15.

It is understood that the containment sealing skirt 114 may be provided as soft; the lower port of the cartridge 15 is covered and sealed by the limiting sealing skirt 114, thereby preventing the liquid aerosol generating substrate from leaking.

In some embodiments, the back shell 41 and the face shell 42 may be connected by a snap-fit structure.

Understandably, the arrangement of the buckle structure can improve the assembly convenience of the back shell 41 and the face shell 42 and improve the processing efficiency; of course, the assembly of the back shell 41 and the face shell 42 can also be completed by adopting a magnetic attraction structure or a screw locking structure.

As shown in fig. 2, the face shell 42 may be provided with a limiting plate 420 in some embodiments, and the limiting plate 420 is used for limiting the atomization assembly 10 in the longitudinal direction.

It can be appreciated that the retainer plate 420 prevents the atomization assembly 10 from sliding within the face housing 42 when the product is not horizontally positioned, thereby improving the structural stability of the product.

In some embodiments, the electronic atomising device 1 may further comprise a plug 50 that is removably plugged onto the mouthpiece 31 to prevent dirt from entering the mouthpiece 31 when not in use, and also to prevent the liquid aerosol-generating substrate from leaking through the mouthpiece 31.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and are intended to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the scope of the present invention. All equivalent changes and modifications made within the scope of the claims of the present invention should be covered by the claims of the present invention.

Claims (10)

1. An atomization assembly comprises a soft atomization seat (11), a vent pipe (12), an atomization core (14) and a liquid storage box (15), wherein the atomization seat (11) comprises an air inlet hole (110); the atomizing component (10) is characterized by further comprising a support pipe (13), wherein the support pipe (13) penetrates through the air inlet hole (110) along the axial direction and is tightly matched with the hole wall of the air inlet hole (110) so as to prevent the hole wall from deforming.

2. Atomizing assembly according to claim 1, characterized in that said air intake (110) passes through from the bottom to the top of said atomizing seat (11), said support tube (13) filling the entire length of said air intake (110).

3. A nebulising assembly according to claim 1, characterized in that the support tube (13) comprises a stainless steel tube.

4. The atomizing assembly of claim 1, characterized in that said atomizing base (11) includes a body portion (111) and a cylindrical mounting portion (112) erected on the top surface of said body portion (111), said air intake hole (110) extends from the bottom surface of said body portion to the top surface of said mounting portion, said support pipe (13) fills the entire length of said air intake hole (110); the lower end of the vent pipe (12) is sleeved on the installation part (112), and the lower end of the liquid storage box (15) is sleeved on the body part (111).

5. The atomizing assembly according to claim 4, characterized in that said vent tube (12) comprises a tube body (121) having an oblique cut (1210) and a reinforcing tube (122) fitted over said oblique cut (1210), said tube body (121) further having a pair of mounting holes (1211), said mounting holes (1211) being used for allowing the atomizing core (14) to transversely pass through said tube body (121); the lower end of the pipe body (121) is sleeved on the installation part (112).

6. The atomizing assembly of claim 5, characterized in that said atomizing core (14) includes a liquid absorbing member (141) and a heat generating member (142) wound on said liquid absorbing member (141), said liquid absorbing member (141) being disposed through said mounting hole (1211), said heat generating member (142) being exposed in said tube body (121).

7. The atomizing assembly according to claim 4, wherein the reservoir (15) includes a sleeve body (151) sleeved on the atomizing base (11) at a lower end thereof, and a reservoir (152) filled between an inner wall surface of the sleeve body (151) and an outer wall surface of the vent pipe (12); the lower end of the sleeve body (151) is sleeved on the body part (111).

8. An electronic atomizer device comprising a housing (40), and further comprising the atomizing assembly (10) of any one of claims 1 to 7, said atomizing assembly (10) being disposed in said housing (40).

9. The electronic atomizer device according to claim 8, further comprising a nozzle assembly (30), wherein the nozzle assembly (30) comprises a nozzle (31) defining a suction channel (311) and a microphone (32) disposed on the nozzle (31).

10. The electronic atomizer device according to claim 8, wherein the housing (40) comprises an integrally formed back shell (41) and an integrally formed front shell (42), and the front shell (42) is disposed on the back shell (41) to define a receiving chamber (43) for receiving the atomizer assembly (2).

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