CN217958742U - Atomization device - Google Patents

Abstract

The application discloses an atomization device which comprises an atomization component and a power supply component, wherein a groove is formed in one end of the power supply component, the atomization component is inserted into the groove, the atomization component is provided with an air inlet end, the air inlet end is abutted to the bottom surface of the groove, a first air vent and a second air vent are formed in one of the air inlet end and the bottom surface, a third air vent is formed in the other of the air inlet end and the bottom surface, and when the atomization component and the power supply component are in a first connection state, the first air vent and the third air vent are matched to form a first air inlet channel; when the atomization component and the power supply component are in a second connection state, the second air vent and the third air vent are matched to form a second air inlet channel, and the air suction resistance of the first air inlet channel is different from that of the second air inlet channel. Atomizing subassembly and power supply module connect with two kinds of different connection states and can form the inlet channel that has the different resistance of breathing in this application, make atomizing device have the different resistance of breathing in, have solved the single problem of current atomizing device resistance of breathing in, satisfy the demand that different users experienced to inhaling.

Description

Atomization device

Technical Field

The application belongs to the technical field of electronic atomization, and particularly relates to an atomization device.

Background

The electronic atomizer may vaporize the liquid by electrical heating so that it may be inhaled by a user. Electronic atomization devices typically include an atomization assembly, which typically includes an atomizer, a reservoir, and a gas channel, and a power supply assembly, which typically includes a power supply, a circuit board, and other related components.

Traditional electronic atomization device is provided with a gas passage, and the user inhales from the suction port and drives external gas and admit air from electronic atomization device's air inlet, and then starts the atomizer with liquid vaporization and follow external gas and together be inhaled and eat, because gas passage is fixed, atomization device's the unable adjustment of resistance of breathing in is difficult to satisfy different users and is experienced the demand of inhaling. There is therefore a need for an atomising device that can meet the inhalation experience of different users by varying the resistance to inhalation.

SUMMERY OF THE UTILITY MODEL

The main technical problem who solves of this application provides an atomizing device that can inhale resistance, can solve the single technical problem of atomizing device resistance of breathing in among the prior art.

In order to solve the technical problem, the application adopts a technical scheme that: providing an atomizing device, wherein the atomizing device comprises an atomizing component and a power supply component, one end of the power supply component is provided with an assembling groove, the atomizing component is inserted into the assembling groove, the atomizing component is provided with an air inlet end, the air inlet end is abutted against the bottom surface of the assembling groove, one of the air inlet end and the bottom surface is provided with a first vent hole and a second vent hole, and the other one is provided with a third vent hole;

when the atomization component and the power supply component are in a first connection state, the first air vent and the third air vent are matched to form a first air inlet channel, when the atomization component and the power supply component are in a second connection state, the second air vent and the third air vent are matched to form a second air inlet channel of the atomization component, and the air suction resistance of the first air inlet channel and the air suction resistance of the second air inlet channel are different.

Wherein the first ventilation hole has a greater air suction resistance than the second ventilation hole.

The air suction resistance of the third vent hole is not greater than the air suction resistance of the second vent hole, or the air suction resistance of the third vent hole is greater than the air suction resistance of the second vent hole and smaller than the air suction resistance of the first vent hole.

Wherein the first vent hole and the second vent hole are symmetrically arranged.

Wherein the atomization device further comprises a projection provided on one of the air intake end and the bottom surface, the projection being configured to shield the first vent hole or the second vent hole.

The air inlet end is provided with a first vent hole and a second vent hole, and the bottom surface is provided with a third vent hole and a first protruding part; when the atomization assembly and the power supply assembly are in a first connection state, the first bulge part shields the second vent hole; when the atomization assembly and the power supply are in a second connection state, the first protruding portion shields the first vent hole.

The air inlet end is provided with a third vent hole and a second protruding part, and the bottom surface is provided with a first vent hole and a second vent hole; when the atomizing assembly and the power supply assembly are in a first connection state, the second protrusion part shields the second vent hole; when the atomization component and the power supply are in a second connection state, the second protruding portion shields the first vent hole.

The convex part is provided with a fourth vent hole, and the air suction resistance of the fourth vent hole is not less than the air suction resistance of the first vent hole; the fourth vent hole is configured to communicate with one of the first vent hole and the first vent hole.

The atomization assembly further comprises a first shell, the air inlet end is formed at one end of the first shell, and an air suction port is formed at one end, away from the air inlet end, of the first shell; wherein the suction port communicates with the first intake passage or the second intake passage.

The power supply assembly further comprises a second shell, the second shell is arranged to enclose to form an accommodating space and an assembling groove, the accommodating space is configured to accommodate the power supply and the circuit board, and the first shell is inserted into the assembling groove.

Wherein, the second shell is provided with an air inlet communicated with the accommodating space; when the atomizing component and the power supply component are in a first connection state, the air inlet is communicated with the first air inlet channel; when the atomization assembly and the power supply are in a second connection state, the air inlet is communicated with the second air inlet channel.

The beneficial effect of this application is: when the atomization component and the power supply component are in a first connection state, the first air vent and the third air vent are matched to form a first air inlet channel; when the atomization assembly and the power supply assembly are in a second connection state, the second air vent and the third air vent are matched to form a second air inlet channel, and the air suction resistance of the first air inlet channel is different from that of the second air inlet channel. And then when atomization component and power supply module are connected with the connected state of two kinds of differences respectively, atomization component can admit air via first inlet channel or second inlet channel respectively, makes atomization device have the different resistance of breathing in, has solved the single problem of current atomization device resistance of breathing in, satisfies different users and to inhaling the demand of experiencing.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic diagram of the construction of an atomizing device according to some embodiments of the present disclosure;

FIG. 2 is a schematic, broken away view of an atomizing device according to some embodiments of the present disclosure;

FIG. 3 is a schematic cross-sectional view of an atomizing device according to some embodiments of the present disclosure;

FIG. 4 is a schematic diagram of an atomizing assembly according to some embodiments of the present disclosure;

FIG. 5 is a schematic diagram of the structure of a power supply assembly according to some embodiments of the present application;

FIG. 6 is a schematic diagram of the construction of an atomizing assembly according to some embodiments of the present disclosure;

FIG. 7 is a schematic diagram of the structure of a power supply assembly according to some embodiments of the present application;

FIG. 8 is a schematic diagram of an atomizing assembly according to still other embodiments of the present disclosure;

FIG. 9 is a schematic diagram of the structure of a power module according to further embodiments of the present application;

FIG. 10 is a schematic view of another embodiment of an atomizing assembly according to the present application;

FIG. 11 is a schematic diagram of a power module according to further embodiments of the present application;

FIG. 12 is a schematic illustration of the construction of an atomizing assembly according to further embodiments of the present disclosure;

FIG. 13 is a schematic diagram of a power module according to further embodiments of the present application;

FIG. 14 is a schematic view of an atomizing assembly according to another embodiment of the present application;

fig. 15 is a schematic diagram of a power module according to further embodiments of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings and embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application. The embodiments described below and the features of the embodiments can be combined with each other without conflict.

It should be noted that if the description refers to "first", "second", etc. in the implementation of the present application, the description of "first", "second", etc. is only used for descriptive purposes and is not to be construed as indicating or implying any relative importance or implicitly indicating the number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments can be combined with each other, but must enable one of ordinary skill in the art to realize the basis, and when the technical solutions are mutually contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not be within the protection scope of the present application.

Referring to fig. 1 and 2, fig. 1 is a schematic structural diagram of an atomizing device 100 according to some embodiments of the present disclosure, and fig. 2 is a schematic structural diagram of the atomizing device 100 according to fig. 1. The atomizing device 100 generally includes an atomizing assembly 12 and a power assembly 14, the atomizing assembly 12 being insertable into the power assembly 14, the atomizing assembly 12 being removably connectable to the power assembly 14. The atomizing assembly 12 stores a liquid that can be atomized and can vaporize the stored liquid into a gas for aspiration. The power supply assembly 14 is used to power the atomizing assembly 12. When the user uses the atomizing device 100, the sensor in the power supply assembly 14 senses the airflow and sends a sensing signal to establish an electrical connection between the power supply assembly 14 and the atomizing assembly 12, such that the power supply assembly 14 powers the atomizing assembly 12, and the atomizing assembly 12 vaporizes the internally stored liquid into gas for inhalation upon actuation of the power supply assembly 14.

Referring to fig. 3-7, fig. 3 isbase:Sub>A cross-sectional structural schematic view (alongbase:Sub>A-base:Sub>A) of the atomizing device 100 of fig. 1, fig. 4 isbase:Sub>A structural schematic view of the atomizing assembly 12 of fig. 1, fig. 5 isbase:Sub>A structural schematic view of the power supply assembly 14 of fig. 1, fig. 6 is another structural schematic view of the atomizing assembly 12 of fig. 1, and fig. 7 is another structural schematic view of the power supply assembly 14 of fig. 1. The power supply assembly 14 is provided with a mounting groove 42 at one end, the atomizing assembly 12 can be inserted into the mounting groove 42 and can be electrically connected with the power supply assembly 14, and the power supply assembly 14 can supply power to the atomizing assembly 12.

The atomizing assembly 12 generally includes a first housing 20, a suction port 21 provided at one end of the first housing 20, and an atomizer 22 provided at the first housing 20. Wherein, first casing 20 encloses to establish and forms first holding chamber, and first holding chamber can be divided into liquid storage cavity 23 and the atomizing space 24 of mutual isolation, and liquid can be stored in liquid storage cavity 23, and atomizing space 24 is linked together with suction opening 21. The atomizer 22 is disposed in the first accommodating cavity, and an atomizing surface of the atomizer 22 is exposed to the atomizing space 24.

Specifically, the first housing 20 generally includes a cover 201 and a base 202, the cover 201 and the base 202 cooperate to define a first accommodating cavity, the cover 201 generally includes a bottom wall and an outer sidewall extending from an edge of the bottom wall, the bottom wall and the outer sidewall cooperate to define a cavity structure of the first housing 20, and the base 202 is covered on the cavity structure, that is, the base 202 cooperates with the cover 201 to define the first accommodating cavity. Wherein, be equipped with suction opening 21 on the diapire, lid 201 still includes the wall structure that extends to the inside first holding chamber from the edge of suction opening 21, and this wall structure encloses with suction opening 21 and establishes the gas passage that forms and be linked together with atomizing space 24.

In one embodiment, as shown in fig. 6, the base 202 is provided with a first vent hole 31 and a second vent hole 32 communicating with the atomizing space 24, the first vent hole 31 and the second vent hole 32 are symmetrically arranged, and the suction resistance of the first vent hole 31 is greater than the suction resistance of the second vent hole 32. The first and second vent holes 31 and 32 may communicate the atomization space 24 with the outside, and the outside air may enter the atomization space 24 via the first and second vent holes 31 and 32.

The power supply module generally includes a second housing 40, and components such as a power supply 44, a circuit board 45, and a sensor 46 provided in the second housing. The second housing 40 is enclosed to form a second accommodating cavity, the second accommodating cavity can be divided into an accommodating space 41 and an assembling groove 42, the accommodating space 41 can be used for accommodating a power supply 44, a circuit board 45, a sensor 46 and the like, and the atomizing assembly 12 can be assembled and connected with the power supply assembly 14 by means of the assembling groove 42, that is, the atomizing assembly 12 can be inserted into the assembling groove 42.

Specifically, the second casing 40 generally includes a bottom wall 401 and a side wall 402 extending from an edge of the bottom wall, the bottom wall 401 and the side wall 402 enclose a second accommodating cavity, a partition 403 is disposed in the second casing 40, and the partition 403 is configured to divide the second accommodating cavity into an accommodating space 41 and a mounting groove 42. The partition 403 is spaced from the bottom wall 401, and an outer periphery of the partition 403 abuts against an inner side of the sidewall 402 to divide the second accommodating cavity into the accommodating space 41 and the assembling groove 42. In other words, the partition 403 forms a bottom wall of the assembly groove 42, a part of the side wall 402 forms a side wall of the assembly groove 42, that is, the partition 403, the bottom wall 401 and a part of the side wall 402 between the partition 403 and the bottom wall 401 enclose to form the accommodating space 41, and the partition 403 and a part of the side wall 402 on a side of the partition 403 away from the bottom wall 401 enclose to form the assembly groove 42.

The power source 44, the circuit board 45, the sensor 46 and the like are disposed in the accommodating space 41, and the second housing 40 is further provided with an air inlet hole 43 communicating with the accommodating space 41. The external air can enter into the accommodating space 41 through the air inlet hole 43.

In one embodiment, as shown in fig. 7, the partition 403 is provided with a third vent hole 33 and a first protrusion 34 communicating with the accommodating space 41, and the suction resistance of the third vent hole 33 is smaller than the suction resistance of the first vent hole 31 and the second vent hole 32.

When the atomizing assembly 12 is inserted into the power supply assembly 14 to form the first connection state, the first vent hole 31 and the third vent hole 33 cooperate to form a first air inlet channel, and the first protrusion 34 blocks the second vent hole 32. Since the first vent hole 31 and the second vent hole 32 are symmetrically arranged, that is, the atomizer assembly 12 can be rotated 180 ° and then inserted into the power module 14, the atomizer assembly 12 and the power module 14 are in the second connection state, the second vent hole 32 and the third vent hole 33 cooperate to form the second air inlet channel, and the first protrusion 34 blocks the first vent hole 31.

When the user inhales from the suction opening 21, it can be understood that there is a pressure difference between the inside and the outside of the atomization device 100, the outside air enters the accommodation space 41 through the air inlet hole 43, and meanwhile, the air in the accommodation space 41 enters the atomization space 24 through one of the first air inlet channel and the second air inlet channel. At this time, the sensor 46 in the accommodating space 41 detects the gas flow and sends a sensing signal to enable the power supply assembly 14 to establish electrical connection with the atomizing assembly 12, the power supply assembly 14 supplies power to the atomizing assembly 12, the liquid in the atomizer 22 is vaporized into gas in the atomizing space 24, and the gas is mixed with the gas entering the atomizing space 24 and sucked out of the suction port 21 by the user. When the atomizing assembly 12 and the power supply assembly 14 are in the first connection state, the external air enters the atomizing assembly 12 from the first air inlet channel, and the air suction resistance of the atomizing device 100 depends on the air suction resistance of the first air vent 31; when the atomizing assembly 12 and the power supply assembly 14 are in the second connection state, the external air enters the atomizing assembly 12 from the second air inlet, the air suction resistance of the atomizing device 100 depends on the air suction resistance of the second vent hole 32, because the air suction resistance of the first vent hole 31 is greater than the air suction resistance of the second vent hole 32, the atomizing device 100 has two different air suction resistances in two different connection states of the atomizing assembly 12 and the power supply assembly 14, the problem of single air suction resistance of the existing atomizing device is solved, and the requirements of different customers on air suction experience are met.

Referring to fig. 8 and 9, fig. 8 is a schematic bottom view of the atomizing assembly 12 in other embodiments, and fig. 9 is a schematic bottom view of the power module 14 in other embodiments. The atomization device 200 in this embodiment is different from the atomization device 100 in the embodiments of fig. 1 to 7 in that the suction resistance of the third ventilation hole 33 is smaller than that of the first ventilation hole 31 and larger than that of the second ventilation hole 32. When the atomizing assembly 12 is inserted into the power module 14 in the first connection state, the first air vent 31 and the third air vent 33 cooperate to form a first air inlet channel, and the first protrusion 34 blocks the second air vent 32. Since the first vent hole 31 and the second vent hole 32 are arranged in a central symmetry manner, that is, when the atomizer assembly 12 can be rotated 180 ° and then inserted into the power module 14, the atomizer assembly 12 and the power module 14 are in the second connection state, the second vent hole 32 and the third vent hole 33 cooperate to form the second air inlet channel, and the first protrusion 34 blocks the first vent hole 31.

When the user inhales from the suction opening 21, it can be understood that there is a pressure difference between the inside and the outside of the atomization device 200, and the outside air enters the accommodating space 41 through the air inlet hole 43, and meanwhile, the air in the accommodating space 41 enters the atomization space 24 through one of the first air inlet channel and the second air inlet channel. At this time, the sensor 46 in the accommodating space 41 detects the gas flow and sends a sensing signal to establish an electrical connection between the atomizing assembly 12 and the power supply assembly 14, the power supply assembly 14 supplies power to the atomizing assembly 12, and the liquid droplets in the atomizer 22 are vaporized into gas in the atomizing space 24 and mixed with the gas entering the atomizing space 24 to be sucked out of the suction port 21 by the user. When the atomizing assembly 12 and the power assembly 14 are in the first connection state, the external air enters the atomizing assembly 12 from the first air inlet channel, and the air suction resistance of the atomizing device 200 depends on the air suction resistance of the first air vent 31; when the atomization component 12 and the power supply component 14 are in the second connection state, the air suction resistance of the atomization device 200 depends on the air suction resistance of the third vent hole 33, and because the air suction resistance of the first vent hole 31 is different from the air suction resistance of the third vent hole 33, the atomization device 200 has two different air suction resistances in two different connection states of the atomization component 12 and the power supply component 14, so that the problem that the air suction resistance of the existing atomization device is single is solved, and the requirements of different customers on air suction experience are met.

Referring to fig. 10 and 11, fig. 10 is a schematic structural diagram of an atomizing assembly 12 in another embodiment, and fig. 11 is a schematic structural diagram of a power supply assembly 14 in another embodiment. The atomizing device 300 in this embodiment is different from the atomizing device in fig. 1 to 7 in that a partition 403 of the power module 14 is provided with a first vent hole 31 and a second vent hole 32 for communicating the accommodating space 41, the first vent hole 31 and the second vent hole 32 are symmetrically arranged, and the air suction resistance of the first vent hole 31 is greater than the air suction resistance of the second vent hole 32; the base 202 of the atomizing assembly 12 is provided with a third vent hole 33 and a second protrusion 35 communicating with the atomizing space, and the suction resistance of the third vent hole 33 is smaller than the suction resistance of the first vent hole 31 and the second vent hole 32. When the atomizing assembly 12 is inserted into the power supply assembly 14 to assume the first connection state, the first vent hole 31 and the third vent hole 33 cooperate to form a first air inlet channel, and the second protrusion 35 blocks the second vent hole 32. Since the first vent hole 31 and the second vent hole 32 are symmetrically disposed, that is, when the atomizing assembly 12 can be rotated 180 ° and then inserted into the power module 14, the atomizing assembly 12 and the power module 14 are in the second connection state, the second vent hole 32 and the third vent hole 33 cooperate to form the second air inlet channel, and the second protrusion 35 blocks the first vent hole 31.

When a user inhales from the suction opening 21, it can be understood that there is a pressure difference between the inside and the outside of the atomizing device 300, and the outside air enters the accommodating space 41 through the air inlet hole 43, and meanwhile, the air in the accommodating space 41 enters the atomizing space 24 through one of the first air inlet channel and the second air inlet channel. The sensor 46 in the receiving space 41 detects the gas flow and sends a sensing signal to establish an electrical connection between the atomizing assembly 12 and the power supply assembly 14, the power supply assembly 14 supplies power to the atomizing assembly 12, and the liquid in the atomizer 22 is vaporized into gas in the atomizing space 24 and mixed with the gas entering the atomizing space 24 to be sucked out from the suction opening 21 by the user. When atomization component 12 is first connected state with power module 14, during the external air enters atomization component 12 from first intake duct, the resistance of breathing in of atomizing device 300 depends on the resistance of breathing in of first air vent 31, when atomization component 12 is second connected state with power module 14, the external air enters atomization component 12 from the second intake duct, the resistance of breathing in of atomizing device 300 depends on the resistance of breathing in of third air vent 33, because the resistance of breathing in of first air vent 31 and the resistance of breathing in of third air vent 33 are different, under two kinds of different connected states of atomization component 12 and power module 14, atomizing device 300 has two kinds of different resistances of breathing in, the problem that current atomization device resistance of breathing in is single has been solved, satisfy the demand of different customers to the experience of breathing in.

Referring to fig. 12 and 13, fig. 12 is a schematic structural diagram of an atomizing assembly 12 in another embodiment, and fig. 13 is a schematic structural diagram of a power supply assembly 14 in another embodiment. The atomizing device 400 of this embodiment is different from the atomizing device 100 of fig. 1 to 7 in that a partition of the power module 14 is provided with a first vent hole 31 and a second vent hole 32 communicating with the accommodating space 41, the first vent hole 31 and the second vent hole 32 are symmetrically arranged, and the suction resistance of the first vent hole 31 is greater than that of the second vent hole 32; the base 202 of the atomizing assembly 12 is provided with a third vent hole 33 and a second protrusion 35 which are communicated with the atomizing space, and the suction resistance of the third vent hole 33 is smaller than that of the first vent hole 31 and larger than that of the second vent hole 32. When the atomizing assembly 12 is inserted into the power supply assembly 14 to assume the first connection state, the first vent hole 31 and the third vent hole 33 cooperate to form a first air inlet channel, and the second protrusion 35 blocks the second vent hole 32. Since the first vent hole 31 and the second vent hole 32 are symmetrically arranged, that is, when the atomizer assembly 12 can be rotated 180 ° and then inserted into the power module 14, the atomizer assembly 12 and the power module 14 are in the second connection state, the second vent hole 32 and the third vent hole 33 cooperate to form the second air inlet channel, and the second protrusion 35 blocks the first vent hole 31.

When a user inhales from the suction opening 21, it can be understood that there is a pressure difference between the inside and the outside of the atomizing device 400, and the outside air enters the accommodating space 41 through the air inlet hole 43, and meanwhile, the air in the accommodating space 41 enters the atomizing space 24 through one of the first air inlet channel and the second air inlet channel. The sensor 46 in the receiving space 41 detects the flow of gas, an electrical connection is established between the atomizing assembly 12 and the power supply assembly 14, the power supply assembly 14 supplies power to the atomizing assembly 12, the liquid in the atomizer 22 is vaporized into gas in the atomizing space 24, and the gas mixed with the gas entering the atomizing space 24 is sucked out of the suction opening 21 by the user. When atomization component 12 is first connected state with power module 14, during external air enters atomization component 12 from first intake duct, the resistance of breathing in depends on first air vent 31, when atomization component 12 is second connected state with power module 14, external air enters atomization component 12 from the second intake duct, the resistance of breathing in of atomizing device 400 depends on the resistance of breathing in of third air vent 33, because the resistance of breathing in of second air vent 32 is different with the resistance of breathing in of third air vent 33, under two kinds of different connected states of atomization component 12 and power module 14, atomizing device 400 has two kinds of different resistances of breathing in, the problem that current atomizing device resistance of breathing in is single is solved, satisfy the demand of different customers to the experience of breathing in.

Referring to fig. 14 and 15, fig. 14 is a schematic structural view of the atomizing device 12 in another embodiment, and fig. 15 is a schematic structural view of the power module 14 in another embodiment. The atomization device 500 in this embodiment is different from the atomization device 100 in the embodiments of fig. 1 to 7 in that the first protrusion 34 is provided with a fourth ventilation hole 36, and the suction resistance of the fourth ventilation hole 36 is greater than the suction resistance of the first ventilation hole 31. When the atomizing assembly 12 is inserted into the power module 14 to form the first connection state, the first vent hole 31 and the third vent hole 33 cooperate to form a first air inlet passage, and the fourth vent hole communicates with the second vent hole 32 to form a third air inlet passage. Because the first vent hole 31 and the second vent hole 32 are symmetrically arranged, that is, when the atomizing assembly 12 is horizontally rotated by 180 ° and then inserted into the power module 14, the atomizing assembly 12 and the power module 14 are in the second connection state, the second vent hole 32 and the third vent hole 33 cooperate to form the second air inlet channel, and the fourth vent hole 36 communicates with the first vent hole 31 to form the fourth air inlet channel.

When the user inhales from the suction opening 21, it can be understood that there is a pressure difference between the inside and the outside of the atomizing device 500, the outside air enters the accommodating space 41 through the air inlet hole 43, and meanwhile, the air in the accommodating space 41 enters the atomizing space through one of the first air inlet channel and the second air inlet channel and one of the third air inlet channel and the fourth air inlet channel. The sensor 46 in the accommodating space 41 detects the gas flow and sends out a sensing signal to establish an electrical connection between the atomizing assembly 12 and the power supply assembly 14, the power supply assembly 14 supplies power to the atomizing assembly 12, and the liquid droplets in the atomizer 22 are vaporized into gas in the atomizing space 24 and mixed with the outside air entering the atomizing space 24 to be sucked out from the suction port 21 by the user. When the atomizing assembly 12 and the power supply assembly 14 are in the first connection state, the external air enters the atomizing assembly 12 from the first air inlet channel and the third air inlet channel, and the air suction resistance of the atomizing device 500 depends on the first air vent 31 and the fourth air vent 36; when the atomizing assembly 12 and the power supply assembly 14 are in the second connection state, the outside air enters the atomizing assembly 12 from the second air inlet, the air suction resistance of the atomizing device 500 depends on the second vent hole 32 and the fourth vent hole 36, because the air suction resistance of the first vent hole 31 and the second vent hole 32 is different, under the two different connection states of the atomizing assembly 12 and the power supply assembly 14, the atomizing device 500 has two different air suction resistances, the problem of single air suction resistance of the existing atomizing device is solved, and the requirements of different customers on air suction experience are met.

It should be noted that, compared with the atomization device 100 in the embodiments of fig. 1 to 7, due to the fourth ventilation hole 36, the inhalation resistance of the atomization device 500 is smaller than that of the atomization device 100, that is, more possibilities are provided for adjusting the inhalation resistance of the atomization device, so as to meet the needs of different customers for inhalation experiences. It should be understood that the suction resistance of the first ventilation hole, the second ventilation hole, the third ventilation hole and the fourth ventilation hole is related to the hole diameter, the end surface area of the hole, the internal width of the hole and other factors. For example, for regular round holes of the same type, the larger the aperture, the relatively smaller the resistance to inhalation. In other words, the suction resistance can be understood as the ease of suction through the hole, and the larger the resistance, the harder suction. Alternatively, the suction resistance can also be understood as the amount of gas passing through the hole with equal suction.

In summary, in the present application, one of the air inlet end of the atomizing assembly and the bottom surface of the recess of the power supply assembly is provided with a first air vent and a second air vent, and the other is provided with a third air vent, further, when the atomizing assembly and the power supply assembly are in a first connection state, the first air vent and the third air vent cooperate to form a first air inlet channel; when the atomizing assembly and the power supply assembly are in a second connection state, the second vent hole and the third vent hole are matched to form a second air inlet channel, and the air suction resistance of the first air inlet channel is different from that of the second air inlet channel. When the user that can understand breathes in from the suction opening, there is pressure difference inside and outside the atomizing device, during the inlet port entering accommodation space can be followed to the ambient air, and simultaneously, the ambient air in the accommodation space also can enter into the atomizing space via one in first inlet channel and the second inlet channel, sensor in the accommodation space detects gaseous flow, establish electric connection between atomizing subassembly and the power supply module, the power supply module is the power supply of atomizing subassembly, the liquid drop in the atomizer, it is present in the atomizing space for gaseous by the vaporization, and with the ambient gas mixture that enters into the atomizing space by the user from the suction opening suction. When atomization component is first connected state with power supply module, during the external air enters into atomization component via first intake duct, when atomization component is the second connected state with power supply module, the external air enters into atomization component via the second intake duct, because the resistance of breathing in of first air vent is greater than the resistance of breathing in of second air vent, and the resistance of breathing in of third air vent is not more than the resistance of breathing in of second air vent, or the resistance of breathing in of third air vent is greater than the resistance of breathing in of second air vent and is less than the resistance of breathing in of first air vent, first air inlet channel and second air inlet channel resistance of breathing in also have the difference, namely under atomization component and two kinds of different connected states of power supply module, atomization device has two kinds of different resistances of breathing in, the problem that current atomization device resistance of breathing in is single is solved, satisfy the demand of different customers to the experience of breathing in.

The above description is only an embodiment of the present application, and not intended to limit the scope of the present application, and all modifications that can be made by using equivalent structures or equivalent processes in the specification and drawings of the present application, or applied to other related technical fields directly or indirectly, are included in the scope of the present application.

Claims (11)

1. An atomizing device is characterized by comprising an atomizing component and a power supply component, wherein one end of the power supply component is provided with an assembling groove, and the atomizing component is inserted into the assembling groove;

the atomization assembly is provided with an air inlet end, and the air inlet end is abutted against the bottom wall of the assembling groove;

one of the air inlet end and the bottom wall is provided with a first vent hole and a second vent hole, and the other is provided with a third vent hole;

when the atomization assembly and the power supply assembly are in a first connection state, the first air vent and the third air vent are matched to form a first air inlet channel; when the atomization assembly and the power supply assembly are in a second connection state, the second vent hole and the third vent hole are matched to form a second air inlet channel;

wherein the first air intake passage and the second air intake passage differ in air intake resistance.

2. The atomizing device of claim 1, wherein the first vent has a greater resistance to inhalation than the second vent.

3. The atomizing device of claim 2, wherein the suction resistance of the third vent is not greater than the suction resistance of the second vent; or,

and the air suction resistance of the third air vent is greater than that of the second air vent and smaller than that of the first air vent.

4. The atomizing device of claim 3, wherein the first vent and the second vent are symmetrically disposed.

5. The atomizing device of claim 3, further comprising a protrusion disposed on one of the air inlet end and the bottom wall, the protrusion configured to block the first vent or the second vent.

6. The atomizing device of claim 5, wherein the air inlet end is provided with a first vent hole and a second vent hole, and the bottom wall is provided with a third vent hole and a first protrusion;

when the atomizing assembly and the power supply assembly are in a first connection state, the first protrusion part shields the second vent hole;

when the atomization assembly and the power supply are in a second connection state, the first protruding portion shields the first vent hole.

7. The atomizing device according to claim 5, wherein the air inlet end is provided with a third vent hole and a second protrusion, and the bottom wall is provided with a first vent hole and a second vent hole;

when the atomizing assembly and the power supply assembly are in a first connection state, the second protrusion part shields the second vent hole;

when the atomization assembly and the power supply are in a second connection state, the second protruding part shields the first vent hole.

8. The atomizing device according to claim 5, wherein the projection is provided with a fourth vent hole having a suction resistance not smaller than that of the first vent hole; the fourth vent hole is configured to communicate with one of the first vent hole and the second vent hole.

9. The atomizing device according to any one of claims 1 to 8, wherein the atomizing assembly further comprises a first housing, the air inlet end is formed at one end of the first housing, and an air suction port is formed at one end of the first housing, which is away from the air inlet end; wherein the suction port communicates with the first intake passage or the second intake passage.

10. The atomizing device of claim 9, wherein the power supply assembly further includes a second housing that encloses a receiving space configured to receive the power supply and the circuit board and a mounting slot into which the first housing is inserted.

11. The atomizing device according to claim 10, wherein the second housing is provided with an air inlet hole communicating with the accommodating space; when the atomizing component and the power supply component are in a first connection state, the air inlet is communicated with the first air inlet channel; when the atomization assembly and the power supply are in a second connection state, the air inlet is communicated with the second air inlet channel.

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