CN220831922U - Electronic atomization device with double heating structures - Google Patents

Abstract

The utility model relates to an electronic atomization device with a double heating structure, which comprises a shell, a liquid storage assembly, a first atomization assembly, a second atomization assembly and a gas circuit adjusting assembly, wherein the shell is provided with a fog outlet. The liquid storage component is arranged in the shell, and a first atomization cavity and a second atomization cavity for discharging aerosol to the mist outlet are arranged in the liquid storage component. The first atomization assembly is located in the first atomization cavity, and the second atomization assembly is located in the second atomization cavity. The air path adjusting component is positioned in the shell. According to the utility model, the air flow passages of the first atomization cavity and the second atomization cavity are controlled by the air passage adjusting component, so that the first atomization cavity or the second atomization cavity is communicated with the mist outlet. Therefore, redundant air can not be sucked, the taste is improved, and the user experience is high.

Description

Electronic atomization device with double heating structures

Technical Field

The utility model relates to the technical field of electronic atomization, in particular to an electronic atomization device with a double heating structure.

Background

The electronic atomization device generally comprises a shell, an atomization assembly, a liquid storage assembly and a battery assembly, wherein a suction nozzle is arranged on the shell, a fog outlet is arranged in the suction nozzle, and a heating assembly and the atomization assembly are arranged in the liquid storage assembly. The atomizing assembly and the suction nozzle are communicated with each other to form an air passage allowing air flow to circulate. The liquid storage component is used for storing atomized liquid and is provided with an atomization cavity. The atomizing assembly comprises a liquid guide rope, an electric heating wire is wound on the liquid guide rope, and the liquid guide rope is used for guiding atomized liquid. The heating wire is electrically connected with the battery assembly. When the aerosol inhalation device is used, the battery supplies power to the electric heating wire, and the atomized liquid is atomized at the high temperature of the electric heating wire to generate a certain amount of aerosol, so that the aerosol inhalation device can inhale.

In order to avoid dry heating of the heating wire caused by insufficient liquid supply, a person skilled in the art adds an atomization assembly in the existing liquid storage assembly, so that the two atomization assemblies work in turn in a time-sharing manner. However, when a user sucks aerosol atomized by one of the atomizing assemblies, air on the air path of the other atomizing assembly is also sucked passively, so that the concentration of the aerosol is low and the taste is poor. In addition, in the use process of the existing aerosol generating device, aerosol flows out along with air under the action of suction force of a user, and when the aerosol flows out through a fog outlet with low temperature in the flowing process, the aerosol is easy to condense to form condensate, and the condensate is easy to be sucked by the user, so that the user experience and the taste are greatly reduced.

Disclosure of utility model

The utility model aims to provide an electronic atomization device with a double heating structure, which can improve the taste.

The scheme of the utility model for solving the problems is that an electronic atomization device with a double heating structure is constructed, the electronic atomization device comprises a shell, a liquid storage component, a first atomization component, a second atomization component and a gas circuit adjusting component, wherein the shell is provided with a fog outlet; the liquid storage assembly is positioned in the shell, and a first atomization cavity and a second atomization cavity for discharging aerosol to the mist outlet are arranged in the liquid storage assembly; the first atomization assembly is positioned in the first atomization cavity, and the second atomization assembly is positioned in the second atomization cavity; the gas circuit adjusting component is positioned in the shell and is used for controlling the airflow passages of the first atomizing cavity and the second atomizing cavity so that the first atomizing cavity or the second atomizing cavity is communicated with the mist outlet.

Preferably, a connection cavity is formed between the shell and the liquid storage component, a first end of the connection cavity is communicated with the fog outlet, and a second end of the connection cavity is communicated with the first atomization cavity and the second atomization cavity; the gas path adjusting component is at least partially positioned in the connecting cavity, and in a first state, the gas path adjusting component blocks a gas path passage between the second atomizing cavity and the mist outlet hole to enable the first atomizing cavity to be communicated with the mist outlet hole; and in a second state, the air passage adjusting component blocks the air passage between the first atomizing cavity and the mist outlet hole, so that the second atomizing cavity is communicated with the mist outlet hole.

Preferably, the air path adjusting assembly comprises a motor, a screw rod and a partition plate, wherein the first end of the screw rod is connected with the motor, and the second end of the screw rod is in threaded connection with the partition plate; the partition plate is positioned between the outlet of the first atomization cavity and the outlet of the second atomization cavity; the orthographic projection of the fog outlet hole in the connecting cavity is positioned between the outlet of the first atomization cavity and the outlet of the second atomization cavity.

Preferably, the electronic atomization device with the double heating structure further comprises condensate adsorption cotton, an accommodating groove communicated with the mist outlet hole is formed in the end face, facing the mist outlet hole, of the liquid storage assembly, and the condensate adsorption cotton is located in the accommodating groove.

Preferably, the receiving groove communicates with the engagement cavity.

Preferably, the first atomization cavity is communicated with the engagement cavity through the accommodating groove, or/and the second atomization cavity is communicated with the engagement cavity through the accommodating groove.

Preferably, the electronic atomization device with the double heating structure further comprises a sealing piece, wherein the sealing piece is located on the bottom wall of the connecting cavity and covers the notch of the containing groove, the first end of the partition plate is abutted to the top wall of the connecting cavity, and the second end of the partition plate is abutted to the bottom wall of the connecting cavity.

Preferably, the electronic atomization device with the double heating structure further comprises a controller and a fan, wherein the controller is electrically connected with the first atomization component, the second atomization component and the fan; the fan is positioned in the shell and is used for supplying air to the first atomization component and the second atomization component.

Preferably, the electronic atomization device with the double heating structure further comprises a fixing seat, the fixing seat is connected with the liquid storage assembly, and the fan is installed at the fixing seat.

Preferably, the liquid storage assembly comprises a liquid storage pipe, a first sealing element, a second sealing element and atomized liquid adsorption cotton, wherein the first sealing element is connected with the first end of the liquid storage pipe, and the first sealing element is provided with a first through hole and a second through hole; the second sealing piece is connected with the second end of the liquid storage pipe, atomized liquid adsorption cotton is located in the liquid storage pipe, the atomized liquid adsorption cotton is provided with a third through hole and a fourth through hole, the first through hole and the third through hole form a first atomization cavity, and the second through hole and the fourth through hole form a first atomization cavity.

The beneficial effects of the utility model are as follows: according to the utility model, the air passage adjusting assembly is arranged in the shell and is used for controlling the air flow passages of the first atomizing cavity and the second atomizing cavity, so that the first atomizing cavity or the second atomizing cavity is communicated with the mist outlet. Therefore, when a user sucks aerosol, the mist outlet is communicated with the first atomization cavity or the second atomization cavity only, redundant air cannot be sucked, and the aerosol formed by atomization cannot be diluted by the redundant air, so that the mouthfeel is improved, the mouthfeel is good, and the user experience is high.

Drawings

The utility model is described below with reference to the accompanying drawings, in which:

Fig. 1 is a schematic structural diagram of an electronic cigarette atomizing device with a dual heat generating structure according to an embodiment of the present utility model in a first state;

Fig. 2 is a schematic structural diagram of an electronic cigarette atomizing device with a dual heat generating structure according to an embodiment of the present utility model in a second state;

Fig. 3 is an enlarged view of the area a shown in fig. 2.

Detailed Description

The present utility model will be described in detail below with reference to the drawings and detailed description.

Referring to fig. 1 to 3, the present utility model provides an electronic cigarette atomizer with a dual heat generating structure, which comprises a housing 1, a liquid storage component 2, a first atomizing component 3, a second atomizing component 4 and a gas path adjusting component 5, wherein the housing 1 comprises a suction nozzle 11, the suction nozzle 11 is provided with a mist outlet 111, and the mist outlet 111 is used for discharging aerosol formed by atomizing atomized liquid of the first atomizing component 3 and the second atomizing component 4 from the mist outlet 111 for a user to inhale; wherein the housing 1 may be formed by combining one or more components, the structure of which is not particularly limited herein.

The liquid storage assembly 2 is located in the housing 1, and a first atomization cavity 201 and a second atomization cavity 202 for discharging aerosol to the mist outlet 111 are provided in the liquid storage assembly 2. In this embodiment, the liquid storage assembly 2 includes a liquid storage tube 21, a first sealing member 22, a second sealing member 23 and an atomized liquid adsorption cotton 24, the first sealing member 22 is connected to a first end of the liquid storage tube 21, the first sealing member 22 is provided with a first through hole 221 and a second through hole 222, and the first through hole 221 and the second through hole 222 are spaced apart.

The second sealing member 23 is connected to the second end of the liquid storage tube 21, and the first end of the liquid storage tube 21 is disposed opposite to the second end of the liquid storage tube 21. The atomized liquid adsorption cotton 24 is located in the liquid storage tube 21 and is used for adsorbing atomized liquid so as to supply liquid for the first atomization component 3 and the second atomization component 4. The atomized liquid adsorption cotton 24 is provided with a third through hole 241 and a fourth through hole 242, the first through hole 221 corresponds to the third through hole 241 in position, and the first through hole 221 and the third through hole 241 form a first atomization cavity 201. The second through hole 222 corresponds to the fourth through hole 242 in position, and the second through hole 222 and the fourth through hole 242 form the first atomization cavity 201.

The first atomizing assembly 3 is located within the first atomizing chamber 201 and the second atomizing assembly 4 is located within the second atomizing chamber 202. In this embodiment, the first atomizing assembly 3 includes a first liquid absorbent cotton column 31 and a first heating element 32, and the first liquid absorbent cotton column 31 is located in the third through hole 241 and contacts with the atomized liquid absorbent cotton 24. The first heating element 32 is located in the first liquid-absorbing cotton column 31 and is in contact with the first liquid-absorbing cotton column 31 for atomizing the atomized liquid in the first liquid-absorbing cotton column 31. The first heat generating member 32 may be a heat generating wire wound in a tubular shape, a heat generating sheet wound in a tubular shape, or the like, and the structure thereof is not particularly limited herein. More specifically, in the present embodiment, the first heat generating member 32 is a heat generating wire wound in a tubular shape, and the heat generating wire is disposed coaxially with the first liquid absorbent cotton column 31.

The second atomizing assembly 4 is arranged in parallel with the first atomizing assembly 3 at intervals. The second atomizing assembly 4 includes a second liquid-absorbent cotton column 41 and a second heat generating member 42, and the second liquid-absorbent cotton column 41 is disposed in the fourth through hole 242 and contacts the atomized liquid-absorbent cotton 24. The second heating element 42 is located in the second liquid-absorbing cotton column 41 and contacts with the second liquid-absorbing cotton column 41, and is used for atomizing atomized liquid in the second liquid-absorbing cotton column 41. The second heat generating member 42 may be a heat generating wire wound in a tubular shape, a heat generating sheet wound in a tubular shape, or the like, and the structure thereof is not particularly limited herein.

The air path adjusting assembly 5 is located in the housing 1, and is used for controlling the air flow paths of the first atomization cavity 201 and the second atomization cavity 202, so that the first atomization cavity 201 or the second atomization cavity 202 is communicated with the mist outlet 111. In this embodiment, a connection cavity 6 is formed between the housing 1 and the liquid storage component 2, a first end of the connection cavity 6 is communicated with the mist outlet 111, and a second end of the connection cavity 6 is communicated with the first atomization cavity 201 and the second atomization cavity 202.

The air passage adjusting component 5 is located in the connecting cavity 6, and in the first state, the air passage adjusting component 5 blocks the air passage between the second atomizing cavity 202 and the mist outlet 111, so that the first atomizing cavity 201 is communicated with the mist outlet 111. In the second state, the air passage adjusting assembly 5 blocks the air passage between the first atomization cavity 201 and the mist outlet 111, so that the second atomization cavity 202 is communicated with the mist outlet 111. The device has the advantages of reliable structure and easiness in assembly and control.

In this embodiment, the air path adjusting assembly 5 includes a motor 51, a screw 52 and a partition 53, wherein a first end of the screw 52 is connected with the motor 51, and a second end of the screw 52 is in threaded connection with the partition 53. The partition 53 is located between the outlet of the first nebulization chamber 201 and the outlet of the second nebulization chamber 202. The orthographic projection of the fog outlet 111 in the connecting cavity 6 is located between the outlet of the first atomization cavity 201 and the outlet of the second atomization cavity 202, so that the partition plate 53 moves between the outlet of the first atomization cavity 201 and the outlet of the second atomization cavity 202, not only can the air path passage be controlled, but also condensate in the connecting cavity 6 can be removed, and the probability that a user sucks the condensate is reduced.

Preferably, the electronic atomization device with the double heating structure further comprises condensate adsorption cotton 7, the end face of the liquid storage component 2 facing the mist outlet 111 is provided with a containing groove 25 communicated with the mist outlet 111, and the condensate adsorption cotton 7 is positioned in the containing groove 25, so that condensate flowing down from the mist outlet 111 can be adsorbed, and the probability of sucking the condensate by a user is reduced. In this embodiment, the engagement cavity 6 is formed between the first sealing member 22 and the housing 1, and the accommodating groove 25 is located on the surface of the first sealing member 22 facing the mist outlet 111, and the accommodating groove 25 communicates with the engagement cavity 6, so that more condensate can be accommodated, and leakage of condensate can be prevented well. In the present embodiment, the first atomizing chamber 201 communicates with the engagement chamber 6 through the accommodating groove 25, and the second atomizing chamber 202 communicates with the engagement chamber 6 through the accommodating groove 25. Therefore, even if too much condensate is not discharged in the direction of the mist outlet 111, the condensate is prevented from being sucked by the user.

In this embodiment, the electronic atomizing device with dual heat generating structure of the present utility model further includes a battery 81, a sealing plate 82, a fixing base 83, an air flow sensor 84, a controller 85, and a fan 86, wherein the battery 81 is used for supplying power to the electric devices such as the first atomizing assembly 3 and the second atomizing assembly 4. The sealing piece 82 is located at the bottom wall of the connecting cavity 6 and covers the notch of the accommodating groove 25, the sealing piece 82 is provided with a first air passing hole 821 and a second air passing hole 822, the first air passing hole 821 is communicated with the connecting cavity 6 and the first atomization cavity 201, and the second air passing hole 822 is communicated with the connecting cavity 6 and the second atomization cavity 202. The first end of the partition 53 abuts against the top wall of the engagement chamber 6, and the second end of the partition 53 abuts against the bottom wall of the engagement chamber 6. The structure not only avoids air leakage, but also can easily push condensate on the sealing piece 82 into the condensate adsorption cotton 7, thereby well reducing the probability of sucking condensate by a user.

The fixing seat 83 is connected with the liquid storage component 2 and is positioned at one end of the liquid storage component 2 back to the connecting cavity 6, and has the advantages of simple and compact structure and convenience in assembly. An air flow sensor 84 is mounted at the fixing base 83. The air flow sensor 84 is electrically connected to the controller 85 for detecting whether the user is inhaling. The controller 85 is electrically connected to the first atomizing assembly 3, the second atomizing assembly 4, and the fan 86. The fan 86 is located in the housing 1 and is mounted at the fixing seat 83 for supplying air to the first atomizing assembly 3 and the second atomizing assembly 4.

The working principle of the utility model is as follows: when a user sucks, the airflow sensor 84 detects the sucking action of the user and sends a sucking signal to the controller 85, the controller 85 controls the first atomization component 3 to work, the partition plate 53 is positioned at the left side of the air inlet of the mist outlet 111, and the partition plate 53 blocks the air path between the second atomization cavity 202 and the mist outlet 111. After the user sucks the aerosol at one time, the controller 85 controls the fan 86 to blow the aerosol into the first atomization cavity 201 so that the residual aerosol is blown out, and then controls the motor 51 to drive the partition plate 53 to move to the right side of the air inlet of the mist outlet 111 so as to block the air passage between the first atomization cavity 201 and the mist outlet 111, and the air passage between the second atomization cavity 202 and the mist outlet 111 is communicated. When the user sucks again, the controller 85 controls the second atomizing assembly 4 to work, and after the user sucks the aerosol once, the controller 85 controls the fan 86 to blow air into the first atomizing chamber 201, and then controls the motor 51 to drive the partition plate 53 to move to the left side of the air inlet of the mist outlet 111. And the process is repeated in a circulating way. Wherein the arrows in the figure point in the direction of flow of the aerosol.

In summary, in the present utility model, the air path adjusting assembly 5 is disposed in the housing 1, and the air path adjusting assembly 5 is used for controlling the air flow paths of the first atomization cavity 201 and the second atomization cavity 202, so that the first atomization cavity 201 or the second atomization cavity 202 is communicated with the mist outlet 111. Therefore, when the user sucks aerosol, the aerosol outlet 111 is only communicated with the first atomization cavity 201 or the second atomization cavity 202, redundant air cannot be sucked, and the aerosol formed by atomization cannot be diluted by the redundant air, so that the mouthfeel is improved, the mouthfeel is good, and the user experience is high.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The electronic atomization device with the double heating structures is characterized by comprising a shell, a liquid storage assembly, a first atomization assembly, a second atomization assembly and a gas circuit adjusting assembly, wherein the shell is provided with a fog outlet; the liquid storage assembly is positioned in the shell, and a first atomization cavity and a second atomization cavity for discharging aerosol to the mist outlet are arranged in the liquid storage assembly; the first atomization assembly is positioned in the first atomization cavity, and the second atomization assembly is positioned in the second atomization cavity; the gas circuit adjusting component is positioned in the shell and is used for controlling the airflow passages of the first atomizing cavity and the second atomizing cavity so that the first atomizing cavity or the second atomizing cavity is communicated with the mist outlet.

2. The electronic atomizer with double heat generating structures according to claim 1, wherein a connecting cavity is formed between the housing and the liquid storage assembly, a first end of the connecting cavity is communicated with the fog outlet, and a second end of the connecting cavity is communicated with the first atomizing cavity and the second atomizing cavity; the gas path adjusting component is at least partially positioned in the connecting cavity, and in a first state, the gas path adjusting component blocks a gas path passage between the second atomizing cavity and the mist outlet hole to enable the first atomizing cavity to be communicated with the mist outlet hole; and in a second state, the air passage adjusting component blocks the air passage between the first atomizing cavity and the mist outlet hole, so that the second atomizing cavity is communicated with the mist outlet hole.

3. The electronic atomizing device with the double heating structure according to claim 2, wherein the air path adjusting assembly comprises a motor, a screw and a partition plate, a first end of the screw is connected with the motor, and a second end of the screw is in threaded connection with the partition plate; the partition plate is positioned between the outlet of the first atomization cavity and the outlet of the second atomization cavity; the orthographic projection of the fog outlet hole in the connecting cavity is positioned between the outlet of the first atomization cavity and the outlet of the second atomization cavity.

4. The electronic atomizing device with the double heating structure according to claim 3, further comprising condensate adsorbing cotton, wherein an accommodating groove communicated with the mist outlet hole is formed in the end face, facing the mist outlet hole, of the liquid storage component, and the condensate adsorbing cotton is located in the accommodating groove.

5. The dual heat generating structure electronic atomizing device of claim 4, wherein the receiving slot is in communication with the engagement cavity.

6. The dual heat generating structure electronic atomizing device of claim 5, wherein the first atomizing chamber is in communication with the engagement chamber via the receiving slot, or/and the second atomizing chamber is in communication with the engagement chamber via the receiving slot.

7. The electronic atomizer with double heat generating structures according to claim 5, further comprising a sealing sheet, wherein the sealing sheet is positioned at the bottom wall of the engagement cavity and covers the notch of the receiving groove, the first end of the partition is abutted with the top wall of the engagement cavity, and the second end of the partition is abutted with the bottom wall of the engagement cavity.

8. The dual heat generating structure electronic atomizing device of claim 1, further comprising a controller and a fan, wherein the controller is electrically connected to the first atomizing assembly, the second atomizing assembly, and the fan; the fan is positioned in the shell and is used for supplying air to the first atomization component and the second atomization component.

9. The electronic atomizing device with the dual heat generation structure according to claim 8, further comprising a fixing base, wherein the fixing base is connected with the liquid storage component, and the fan is installed at the fixing base.

10. The electronic atomizer with double heat generating structures according to claim 1, wherein the liquid storage assembly comprises a liquid storage tube, a first sealing member, a second sealing member and atomized liquid adsorption cotton, the first sealing member is connected with a first end of the liquid storage tube, and the first sealing member is provided with a first through hole and a second through hole; the second sealing piece is connected with the second end of the liquid storage pipe, atomized liquid adsorption cotton is located in the liquid storage pipe, the atomized liquid adsorption cotton is provided with a third through hole and a fourth through hole, the first through hole and the third through hole form a first atomization cavity, and the second through hole and the fourth through hole form a first atomization cavity.