CN218389801U - Electronic atomizer - Google Patents

Abstract

The present application provides an electronic atomizer. The electronic atomizer comprises a suction nozzle cover, a shell assembly, an atomizing assembly and a hydrogen-oxygen separation assembly; the suction nozzle cover is provided with an air outlet; the suction nozzle cover is positioned in the mounting hole and is detachably connected with the shell assembly; the first containing groove is also communicated with the air outlet hole, and the center line of the first containing groove and the center line of the mounting hole are on the same straight line; the atomizing assembly is positioned in the first accommodating groove and connected with the shell assembly, the diameter of the mounting hole is larger than or equal to that of the atomizing assembly, a first air outlet channel communicated with the air outlet hole is formed in the atomizing assembly, and the atomizing assembly is used for generating atomizing gas; the oxyhydrogen separation subassembly is connected with the casing subassembly, and the second outlet channel and the first accepting groove intercommunication of oxyhydrogen separation subassembly. When the atomizing nozzle is installed, the atomizing assembly can be assembled in the first accommodating groove through the installation hole, and then the suction nozzle cover is assembled in the installation hole; therefore, the atomization assembly is convenient and quick to disassemble and assemble.

Description

Electronic atomizer

Technical Field

The utility model relates to an electronic atomization technical field especially relates to an electronic atomizer.

Background

An electronic atomizer is a device for atomizing a liquid (e.g., tobacco tar) into an aerosol, which is widely used in various fields, such as medical treatment, electronic cigarettes, and the like. The traditional medical electronic atomizer only carries out physical transformation on liquid, namely, a medium to be atomized is converted into smoke with extremely small particle size from liquid, and the smoke is mixed with air to be inhaled. For example, chinese patent CN 109219675A discloses an electrolytic hydrogen inhalation tool, which generates hydrogen by electrolyzing water and dedicated electrolyte, and simultaneously generates aromatic gas by mixing with an aromatic heating component, and the aromatic gas is finally discharged through a nozzle, wherein the electrolyte used in an electrolytic cell needs the dedicated electrolyte, the space required to store water in a corresponding reducing part is larger, and a matched mesh electrode has a larger size, i.e., under the premise of a preset hydrogen demand requirement, the whole volume is larger.

However, the atomizing assembly of the electronic atomizer needs to be disassembled, assembled and replaced after the atomized liquid is used, so as to be used continuously. For example, CN 109219675A discloses an electrolytic hydrogen inhalation device, which has a complicated layout of parts, such as a mixer needs to be locked or released by two opposite locking buttons, when an aromatic heating component needs to be replaced, the mixer needs to be taken out first, and because the mixer is respectively connected and sealed with a screw cap and the aromatic heating component, such as a cylindrical component is arranged on the mixer, the traditional electronic atomizer has a complicated structure, and the atomization component is complex to assemble and disassemble.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, provide one kind can produce hydrogen, oxygen and atomizing gas's the less and dismouting and simple structure's of being convenient for of volume simultaneously electron atomizer.

The purpose of the utility model is realized through the following technical scheme:

an electronic atomizer comprising:

a nozzle cover formed with an air outlet hole;

the suction nozzle cover is positioned in the mounting hole and is detachably connected with the shell assembly; the first accommodating groove is also communicated with the air outlet hole, and the center line of the first accommodating groove and the center line of the mounting hole are on the same straight line;

the atomizing assembly is positioned in the first accommodating groove and connected with the shell assembly, the diameter of the mounting hole is larger than or equal to that of the atomizing assembly, a first air outlet channel communicated with the air outlet hole is formed in the atomizing assembly, and the atomizing assembly is used for generating atomizing gas;

oxyhydrogen separating element, with casing subassembly is connected, just oxyhydrogen separating element's second air outlet channel with first accepting groove intercommunication, oxyhydrogen separating element includes electrolysis catalytic membrane structure, electrolysis catalytic membrane structure is used for producing hydrogen and oxygen respectively when electrically conductive and with water contact.

In one embodiment, the shell assembly comprises a shell and a fixed frame; the mounting hole is formed in the shell, the shell is also provided with an accommodating cavity communicated with the mounting hole, and the suction nozzle cover is positioned in the mounting hole and is detachably connected with the shell;

the fixing frame is located hold the intracavity and with the casing is connected, first accepting groove form in the fixing frame, atomizing component is located in first accepting groove and with the fixing frame is connected, oxyhydrogen separating element with the fixing frame is connected.

In one embodiment, the housing comprises a housing body and a cover plate, the accommodating cavity is formed in the housing body, the housing body is further formed with a connecting port which is communicated with the accommodating cavity, the cover plate is partially positioned in the connecting port and connected with the housing body, and the mounting hole is formed in the cover plate; the suction nozzle cover is positioned in the mounting hole and is detachably connected with the cover plate.

In one embodiment, the cover plate is removably coupled to the housing body.

In one embodiment, the cover plate is snap-fit connected to the housing body.

In one embodiment, the cover plate abuts against the fixing frame, and the fixing frame is provided with a vent groove which is respectively communicated with the first accommodating groove and the second gas outlet channel of the hydrogen-oxygen separation assembly; one end of the suction nozzle cover is abutted to the atomizing assembly, a flow passing groove is formed in the suction nozzle cover, and the vent groove is communicated with the air outlet hole through the flow passing groove.

In one embodiment, the fixing frame is further formed with a gas passing hole communicated with the first accommodating groove, and the gas passing hole is further communicated with the second gas outlet channel of the hydrogen-oxygen separation assembly.

In one embodiment, the fixing frame is further formed with a second accommodating groove communicated with the air passing hole, the first accommodating groove is communicated with the second accommodating groove through the air passing hole, and the hydrogen-oxygen separation assembly is located in the second accommodating groove and connected with the fixing frame.

In one embodiment, the nozzle cover is removably connected to the housing assembly.

In one embodiment, the nozzle cover comprises a nozzle cover main body and a sealing connecting piece, wherein a connecting ring groove is formed in the peripheral wall of the nozzle cover main body, the sealing connecting piece is located in the connecting ring groove and connected with the nozzle cover main body, and the sealing connecting piece is elastically abutted to the inner peripheral wall of the mounting hole.

Compared with the prior art, the utility model discloses at least, following advantage has:

in the electronic atomizer, the atomizing component is provided with the first gas outlet channel communicated with the gas outlet hole, the second gas outlet channel of the hydrogen-oxygen separation component is communicated with the first accommodating groove, and the hydrogen-oxygen separation component comprises the electrolytic catalytic membrane structure which is used for respectively generating hydrogen and oxygen when conducting electricity and contacting water, and the first accommodating groove is communicated with the gas outlet hole, so that the first gas outlet channel and the second gas outlet channel are both communicated with the gas outlet hole, and the hydrogen and the oxygen generated by the hydrogen-oxygen separation component and the atomized gas generated by the atomizing component all flow out through the gas outlet hole; because the nozzle cover is positioned in the mounting hole and is detachably connected with the shell assembly, the center line of the first accommodating groove and the center line of the mounting hole are on the same straight line, and the diameter of the mounting hole is larger than or equal to that of the atomization assembly, when the nozzle cover is detached, the nozzle cover can be detached firstly, and then the atomization assembly is taken out through the mounting hole; similarly, when the nozzle cover is installed, the atomizing assembly can be assembled in the first accommodating groove through the installation hole, and then the nozzle cover is assembled in the installation hole; so, compare in traditional electrolysis formula hydrogen and inhale the apparatus, the dismouting of the atomizing subassembly of the electronic atomizer of this application is convenient and fast more.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic structural diagram of an electronic atomizer according to an embodiment;

FIG. 2 is a cross-sectional view of the electronic atomizer shown in FIG. 1;

FIG. 2a is a schematic diagram showing the structure of an electrolytic catalytic membrane of the hydrogen-oxygen separation assembly of the electronic atomizer shown in FIG. 2;

FIG. 2b is a schematic view of a portion of the structure of the electrolytic catalytic membrane shown in FIG. 2 a;

FIG. 3 is an enlarged partial schematic view of the electronic atomizer shown in FIG. 2;

fig. 4 is an exploded view of the electronic atomizer shown in fig. 1.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The utility model relates to an electronic atomizer, which comprises a suction nozzle cover, a shell component, an atomizing component and an oxygen-hydrogen separation component; the suction nozzle cover is provided with an air outlet; the suction nozzle cover is positioned in the mounting hole and is detachably connected with the shell assembly; the first accommodating groove is also communicated with the air outlet hole, and the center line of the first accommodating groove and the center line of the mounting hole are on the same straight line; the atomizing assembly is positioned in the first accommodating groove and connected with the shell assembly, the diameter of the mounting hole is larger than or equal to that of the atomizing assembly, a first air outlet channel communicated with the air outlet hole is formed in the atomizing assembly, and the atomizing assembly is used for generating atomizing gas; the oxyhydrogen separating unit is connected with the shell assembly, just the second air outlet channel of oxyhydrogen separating unit with first holding tank intercommunication, the oxyhydrogen separating unit includes electrolysis catalytic membrane structure, electrolysis catalytic membrane structure is used for producing hydrogen and oxygen respectively when electrically conductive and contact with water.

In the electronic atomizer, the atomizing component is provided with the first gas outlet channel communicated with the gas outlet hole, the second gas outlet channel of the hydrogen-oxygen separation component is communicated with the first accommodating groove, and the hydrogen-oxygen separation component comprises the electrolytic catalytic membrane structure which is used for respectively generating hydrogen and oxygen when conducting electricity and contacting water, and the first accommodating groove is communicated with the gas outlet hole, so that the first gas outlet channel and the second gas outlet channel are both communicated with the gas outlet hole, and the hydrogen and the oxygen generated by the hydrogen-oxygen separation component and the atomized gas generated by the atomizing component all flow out through the gas outlet hole; because the nozzle cover is positioned in the mounting hole and is detachably connected with the shell assembly, the center line of the first accommodating groove and the center line of the mounting hole are on the same straight line, and the diameter of the mounting hole is larger than or equal to that of the atomization assembly, when the nozzle cover is detached, the nozzle cover can be detached firstly, and then the atomization assembly is taken out through the mounting hole; similarly, during installation, the atomizing assembly can be assembled in the first accommodating groove through the installation hole, and then the suction nozzle cover is assembled in the installation hole; so, compare in traditional electrolysis formula hydrogen inhalation apparatus, the dismouting of the atomization component of the electronic atomizer of this application is convenient and fast more.

Please refer to fig. 1, which is a schematic structural diagram of an electronic atomizer 10 according to an embodiment of the present invention.

Referring also to fig. 2, the electronic atomizer 10 of an embodiment includes a mouthpiece cover 100, a housing assembly 200, an atomizing assembly 300, and a hydrogen-oxygen separation assembly 400. The nozzle cover 100 is formed with an air outlet hole 102. The housing assembly 200 is formed with a mounting hole 202 and a first receiving groove 204 which are communicated with each other, and the nozzle cover 100 is located in the mounting hole 202 and detachably connected to the housing assembly 200. The first receiving groove 204 is further communicated with the air outlet hole 102, and a center line of the first receiving groove 204 is on the same straight line with a center line of the mounting hole 202, so that the first receiving groove 204 is correspondingly communicated with the air outlet hole 102. The atomizing element 300 is located in the first receiving groove 204 and connected to the housing element 200, and the diameter of the mounting hole 202 is greater than or equal to the diameter of the atomizing element 300. The atomizing assembly 300 is formed with a first air outlet channel 302 communicated with the air outlet hole, the atomizing assembly 300 is used for generating atomizing gas, and the atomizing gas flows out through the first air outlet channel 302. The hydrogen-oxygen separation module 400 is connected to the housing module 200, and the second gas outlet channel 402 of the hydrogen-oxygen separation module 400 is communicated with the first receiving groove 204, the hydrogen-oxygen separation module 400 comprises an electrolysis catalytic membrane structure 400a, the electrolysis catalytic membrane structure 400a is used for respectively generating hydrogen and oxygen when conducting electricity and contacting with water, so that the hydrogen and oxygen generated by the hydrogen-oxygen separation module 400 both flow out through the second gas outlet channel 402.

The utility model provides an electronic atomizer, electrolytic catalysis membrane structure 400a is when contact with water and electrically conduct and chemical reaction takes place, namely electrolytic catalysis membrane structure 400a takes place chemical reaction when the aquatic circular telegram, in order to produce hydrogen and oxygen respectively, under the same volume condition, compare in traditional electrolytic reaction hydrogen production mode electrolytic hydrogen that electrolytic pole piece produced hydrogen mode inhales the apparatus, the gas production rate of electrolytic catalysis membrane structure 400a of the electronic atomizer of this application is higher, and positive negative pole interval is less, so make the volume of electronic atomizer's oxyhydrogen separation subassembly less, make electronic atomizer's structure compacter simultaneously.

In the electronic atomizer 10, the atomizing assembly 300 is provided with the first gas outlet channel 302 communicated with the gas outlet, the second gas outlet channel 402 of the hydrogen-oxygen separation assembly 400 is communicated with the first accommodating groove 204, and the hydrogen-oxygen separation assembly comprises the electrolytic catalytic membrane structure 400a, the electrolytic catalytic membrane structure 400a is used for respectively generating hydrogen and oxygen when conducting electricity and contacting water, and the first accommodating groove is communicated with the gas outlet, so that the first gas outlet channel and the second gas outlet channel are both communicated with the gas outlet, so that the hydrogen and oxygen generated by the hydrogen-oxygen separation assembly 400 and the atomized gas generated by the atomizing assembly 300 all flow out through the gas outlet 102, compared with the conventional electrolytic hydrogen inhalation hydrogen production tool in which the electrolytic reaction generates hydrogen, i.e. in which an electrolytic pole piece is used, the electrolytic catalytic membrane structure 400a of the electronic atomizer has a higher gas production rate and a smaller distance between the positive electrode and the negative electrode, so that the volume of the hydrogen-oxygen separation assembly of the electronic atomizer is smaller, and the structure of the electronic atomizer is more compact without additionally arranging a locking button, and the structure of the hydrogen-oxygen separation assembly 400 is simpler; because the nozzle cover 100 is located in the mounting hole 202 and detachably connected to the housing assembly 200, and the center line of the first receiving groove 204 and the center line of the mounting hole 202 are on the same straight line, the diameter of the mounting hole 202 is greater than or equal to the diameter of the atomizing assembly 300, when detaching, the nozzle cover 100 can be detached first, and then the atomizing assembly 300 can be taken out through the mounting hole 202; similarly, during installation, the atomizing assembly 300 may be first assembled in the first receiving groove 204 through the mounting hole 202, and then the nozzle cover 100 may be assembled in the mounting hole 202; so, compare in traditional electrolysis formula hydrogen inhalation apparatus, the dismouting of the atomizing subassembly 300 of the electronic atomizer of this application is convenient and fast more.

As shown in fig. 2, further, the electronic atomizer 10 further includes a water storage box 500, a liquid storage cavity 502 is formed in the water storage box 500, the electrolytic catalysis film structure 400a is disposed in the liquid storage cavity 502, the liquid storage cavity 502 is communicated with the second air outlet channel 402, the liquid storage cavity 502 is used for storing water, so that the electrolytic catalysis film structure 400a is soaked in water, and thus hydrogen and oxygen are respectively and reliably generated when the electrolytic catalysis film structure 400a is conductive and is in contact with water. Because the gas production rate of the electrolytic catalytic membrane structure 400a is high, and the distance between the anode and the cathode of the electrolytic catalytic membrane structure 400a is small, the space occupied by the electrolytic catalytic membrane structure 400a in the water storage cavity is small, so that the volume of the hydrogen-oxygen separation assembly 400 of the electronic atomizer 10 is small.

As shown in fig. 2, fig. 2a and fig. 2b, further, the electrolytic catalytic membrane structure 400a includes a catalytic membrane module 410 and two electrode guiding layers 420; catalytic membrane module 410 is used to produce hydrogen and oxygen when electrically conductive and in contact with water; two electrode guide layers 420 are respectively disposed on two sides of catalytic membrane module 410, and two electrode guide layers 420 are respectively electrically connected to catalytic membrane module 410. Furthermore, the catalytic membrane module 410 includes a first conductive enhancement layer 412, a first catalytic layer 414, an intermediate membrane layer 416, a second catalytic layer 418, and a second conductive enhancement layer 419 that are sequentially stacked, wherein one electrode layer 420 is stacked on a side of the first conductive enhancement layer 412 that faces away from the first catalytic layer 414, and the other electrode layer 420 is stacked on a side of the second conductive enhancement layer 419 that faces away from the second catalytic layer 418, so that both electrode layers 420 can be reliably electrically connected to the respective catalytic layers, and the catalytic membrane module 410 can be compactly arranged. In the present embodiment, the first conductive reinforcing layer 412 and the second conductive reinforcing layer 419 are both a titanium foam mesh layer or a nickel foam mesh layer, so that the first conductive reinforcing layer 412 and the second conductive reinforcing layer 419 have better electrical conductivity and facilitate the discharge of the generated hydrogen or oxygen. Furthermore, each electrode layer 420 is a stainless steel mesh layer, a titanium mesh layer, or a nickel mesh layer, so that each electrode layer 420 has a better electrical conductivity. Furthermore, the middle film layer 416 is a polymer film layer or a nylon layer, so that the first catalytic layer and the second catalytic layer are preferably disposed on two sides of the middle film layer 416.

As shown in fig. 2 and 3, in one embodiment, the housing assembly 200 includes a housing 210 and a fixing frame 220. The mounting hole 202 is formed in the housing 210, the housing 210 further forms an accommodating cavity 206 communicated with the mounting hole 202, and the nozzle cover 100 is located in the mounting hole 202 and detachably connected to the housing 210, so that the nozzle cover 100 and the housing 210 can be detached from each other. The fixing frame is located in the accommodating cavity and connected to the housing, the first accommodating groove 204 is formed in the fixing frame 220, the atomizing assembly 300 is located in the first accommodating groove 204 and connected to the fixing frame 220, the hydrogen-oxygen separation assembly 400 is connected to the fixing frame 220, and the mouthpiece cover 100 is detachably connected to the housing 210, so that the hydrogen-oxygen separation assembly 400 can be disassembled and assembled.

As shown in fig. 2 and 3, in one embodiment, the housing 210 includes a housing body 212 and a cover plate 214, the receiving cavity 206 is formed in the housing body 212, the housing body 212 further forms a connecting port 201, the connecting port 201 is communicated with the receiving cavity 206, and the cover plate 214 is partially located in the connecting port 201 and connected to the housing body 212, so that the housing 210 has a simple structure and is easy to manufacture. The mounting hole 202 is formed in the cover plate 214, so that the housing 210 is formed with the mounting hole 202. The nozzle cover 100 is located in the mounting hole 202 and detachably connected to the cover plate 214, so that the nozzle cover 100 is detachably connected to the housing 210.

As shown in fig. 2 and 3, in one embodiment, the cover plate 214 is detachably connected to the housing body 212, so that the cover plate 214, the housing body 212, or parts in the housing 210 can be disassembled or replaced, thereby improving the convenience of the electronic atomizer 10. In one embodiment, the cover plate 214 is snap-fit to the housing body 212, so that the cover plate 214 is detachably connected to the housing body 212, and the cover plate 214 is quickly assembled to and disassembled from the housing body 212. It is understood that in other embodiments, the cover plate 214 and the housing body 212 are not limited to a snap-fit connection. For example, the cover plate 214 is fixedly connected to the case body 212 by screws.

In one embodiment, as shown in fig. 3 and 4, the cover plate 214 abuts against the fixing frame 220, and the fixing frame 220 is formed with a vent groove 222, wherein the vent groove 222 is respectively communicated with the first receiving groove 204 and the second gas outlet channel 402 of the hydrogen-oxygen separation assembly 400. One end of the nozzle cover 100 abuts against the atomizing assembly 300, so that the atomizing assembly 300 is better fixedly mounted in the first receiving groove 204, the flow passing groove 104 is formed in the nozzle cover 100, the vent groove 222 is communicated with the air outlet 102 through the flow passing groove 104, and the first receiving groove 204 is communicated with the air outlet 102 through the vent groove 222 and the flow passing groove 104, respectively.

In one embodiment, as shown in fig. 3 and 4, the fixing frame 220 further forms a gas passing hole 208 communicated with the vent groove, and the gas passing hole 208 is further communicated with the second gas outlet channel 402 of the hydrogen-oxygen separation assembly 400, so that the first receiving groove 204 is reliably communicated with the second gas outlet channel 402.

As shown in fig. 3 and 4, in one embodiment, the fixing frame 220 further forms a second receiving groove 224 communicating with the air passing hole 208, the first receiving groove 204 communicates with the second receiving groove 224 through the air passing hole 208, and the hydrogen-oxygen separation assembly 400 is located in the second receiving groove 224 and connected to the fixing frame 220, so that the hydrogen-oxygen separation assembly 400 is reliably connected to the fixing frame 220, and the electronic atomizer 10 is compact.

As shown in fig. 3 and 4, in one embodiment, the nozzle cover 100 is detachably connected to the housing assembly 200, so that the nozzle cover 100 is detachably connected to the housing assembly 200, and the nozzle cover 100 and the housing assembly 200 are quickly disassembled. In this embodiment, the nozzle cover 100 includes a nozzle cover main body 110 and a sealing connector (not shown), the peripheral wall of the nozzle cover main body 110 is formed with a connection ring groove 112, the sealing connector is located in the connection ring groove 112 and connected to the nozzle cover main body 110, and the sealing connector elastically abuts against the inner peripheral wall of the mounting hole 202, so that the nozzle cover 100 is tightly connected to the housing assembly 200, and the nozzle cover 100 is connected to the housing assembly 200 in a detachable manner.

Compared with the prior art, the utility model discloses at least, following advantage has:

in the electronic atomizer 10, the atomizing assembly 300 is provided with the first gas outlet channel 302 communicated with the gas outlet, the second gas outlet channel 402 of the hydrogen-oxygen separation assembly 400 is communicated with the first accommodating groove 204, and the hydrogen-oxygen separation assembly comprises the electrolytic catalytic membrane structure 400a, the electrolytic catalytic membrane structure 400a is used for respectively generating hydrogen and oxygen when conducting electricity and contacting water, and the first accommodating groove is communicated with the gas outlet, so that the first gas outlet channel and the second gas outlet channel are both communicated with the gas outlet, so that the hydrogen and oxygen generated by the hydrogen-oxygen separation assembly 400 and the atomized gas generated by the atomizing assembly 300 all flow out through the gas outlet 102, compared with the conventional electrolytic hydrogen inhalation hydrogen production tool in which the electrolytic reaction generates hydrogen, i.e. in which an electrolytic pole piece is used, the electrolytic catalytic membrane structure 400a of the electronic atomizer has a higher gas production rate and a smaller distance between the positive electrode and the negative electrode, so that the volume of the hydrogen-oxygen separation assembly of the electronic atomizer is smaller, and the structure of the electronic atomizer is more compact without additionally arranging a locking button, and the structure of the hydrogen-oxygen separation assembly 400 is simpler; because the nozzle cover 100 is located in the mounting hole 202 and detachably connected to the housing assembly 200, and the center line of the first receiving groove 204 and the center line of the mounting hole 202 are on the same straight line, the diameter of the mounting hole 202 is greater than or equal to the diameter of the atomizing assembly 300, when detaching, the nozzle cover 100 can be detached first, and then the atomizing assembly 300 can be taken out through the mounting hole 202; similarly, when the nozzle cover is installed, the atomizing assembly 300 may be first assembled in the first receiving groove 204 through the mounting hole 202, and then the nozzle cover 100 may be assembled in the mounting hole 202; so, compare in traditional electrolysis formula hydrogen inhalation apparatus, the dismouting of the atomizing subassembly 300 of the electronic atomizer of this application is convenient and fast more.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, which all fall within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. An electronic atomizer, comprising:

a nozzle cover formed with an air outlet hole;

the suction nozzle cover is positioned in the mounting hole and is detachably connected with the shell assembly; the first accommodating groove is also communicated with the air outlet hole, and the center line of the first accommodating groove and the center line of the mounting hole are on the same straight line;

the atomizing assembly is positioned in the first accommodating groove and connected with the shell assembly, the diameter of the mounting hole is larger than or equal to that of the atomizing assembly, a first air outlet channel communicated with the air outlet hole is formed in the atomizing assembly, and the atomizing assembly is used for generating atomizing gas;

and the hydrogen-oxygen separation component is connected with the shell component, a second gas outlet channel of the hydrogen-oxygen separation component is communicated with the first accommodating groove, and the hydrogen-oxygen separation component comprises an electrolytic catalytic membrane structure which is used for respectively generating hydrogen and oxygen when conducting electricity and contacting water.

2. The electronic atomizer of claim 1, wherein said housing assembly comprises a housing and a mount; the mounting hole is formed in the shell, the shell is also provided with an accommodating cavity communicated with the mounting hole, and the suction nozzle cover is positioned in the mounting hole and is detachably connected with the shell;

the fixing frame is located hold the intracavity and with the casing is connected, first accepting groove form in the fixing frame, atomizing component is located in first accepting groove and with the fixing frame is connected, oxyhydrogen separating element with the fixing frame is connected.

3. The electronic atomizer of claim 2, wherein said housing includes a housing body and a cover plate, said receiving cavity being formed in said housing body, said housing body further defining a connection port communicating with said receiving cavity, said cover plate being partially located in said connection port and connected to said housing body, said mounting hole being formed in said cover plate; the suction nozzle cover is positioned in the mounting hole and is detachably connected with the cover plate.

4. The electronic atomizer of claim 3, wherein said cover plate is removably attached to said housing body.

5. The electronic atomizer of claim 4, wherein said cover plate is snap-fit to said housing body.

6. The electronic atomizer according to claim 3, wherein said cover plate abuts against said fixing frame, and said fixing frame is formed with a vent groove, and said vent groove is respectively communicated with said first receiving groove and said second gas outlet channel of said hydrogen-oxygen separation assembly; one end of the nozzle cover is abutted to the atomizing assembly, a flow passing groove is formed in the nozzle cover, and the vent groove is communicated with the air outlet through the flow passing groove.

7. The electronic atomizer according to claim 2, wherein said fixing frame further defines a gas passing hole communicating with said first receiving chamber, said gas passing hole further communicating with said second gas outlet channel of said hydrogen-oxygen separation assembly.

8. The electronic atomizer according to claim 7, wherein said fixing frame further defines a second receiving chamber communicating with said air passing hole, said first receiving chamber communicates with said second receiving chamber through said air passing hole, and said hydrogen-oxygen separation element is located in said second receiving chamber and connected to said fixing frame.

9. The electronic atomizer of claim 1, wherein said nozzle cap is removably attached to said housing assembly.

10. The electronic atomizer according to claim 9, wherein said nozzle cover includes a main body and a sealing connector, the outer peripheral wall of said main body is formed with a connecting ring groove, said sealing connector is located in said connecting ring groove and connected to said main body, and said sealing connector is elastically abutted against the inner peripheral wall of said mounting hole.

Images