CN114532598A

CN114532598A - Electronic atomization device

Info

Publication number: CN114532598A
Application number: CN202210224484.2A
Authority: CN
Inventors: 彭世键
Original assignee: Shenzhen Mason Vap Technology Co ltd
Current assignee: Shenzhen Mason Vap Technology Co ltd
Priority date: 2022-03-07
Filing date: 2022-03-07
Publication date: 2022-05-27

Abstract

The application provides an electronic atomization device. The electronic atomization device comprises a shell, an atomization assembly, a hydrogen-oxygen separator, a suction nozzle piece and a battery rod assembly; the shell is provided with a containing cavity and a mounting hole which are communicated; the atomization assembly is positioned in the accommodating cavity and connected with the shell, the atomization assembly is used for generating atomization gas, and a first gas outlet channel is formed in the atomization assembly; the hydrogen-oxygen separator is positioned in the accommodating cavity and connected with the shell, the hydrogen-oxygen separator is used for generating hydrogen and oxygen, and a second gas outlet channel is formed in the hydrogen-oxygen separator; the suction nozzle piece penetrates through the mounting hole and is connected with the shell, and an air outlet hole is formed in the suction nozzle piece. The hydrogen and the oxygen that the oxyhydrogen separator produced all flow to the venthole through second air outlet channel, make atomizing gas, hydrogen and oxygen all flow through the venthole and form atomizing mist, and then make the atomizing mist that electron atomizing device produced have a quantitative oxygen, have improved electron atomizing device's suitability.

Description

Electronic atomization device

Technical Field

The invention relates to the technical field of electronic atomization, in particular to an electronic atomization device.

Background

An electronic atomizer is a device for atomizing a liquid (e.g., tobacco tar) into smoke, and is widely used in various fields, such as medical treatment, electronic cigarettes, and the like. The traditional medical electronic atomization device 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.

However, the content of oxygen contained in the atomizing gas led out by the conventional electronic atomizing device is low, and the use requirement cannot be met, so that the applicability of the electronic atomizing device is poor.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide the electronic atomization device capable of effectively improving the oxygen content.

The purpose of the invention is realized by the following technical scheme:

an electronic atomization device comprising:

the shell is provided with a containing cavity and a mounting hole which are communicated;

the atomization assembly is positioned in the accommodating cavity and connected with the shell, the atomization assembly is used for generating atomization gas, and a first gas outlet channel is formed in the atomization assembly;

the hydrogen-oxygen separator is positioned in the accommodating cavity and connected with the shell, the hydrogen-oxygen separator is used for generating hydrogen and oxygen, and a second gas outlet channel is formed in the hydrogen-oxygen separator;

the suction nozzle piece penetrates through the mounting hole and is connected with the shell, an air outlet hole is formed in the suction nozzle piece, and the air outlet hole is communicated with the first air outlet channel and the second air outlet channel respectively;

and the battery rod assembly is positioned in the accommodating cavity and connected with the shell, and the battery rod assembly is electrically connected with the atomizing assembly and the hydrogen-oxygen separator respectively.

In one embodiment, the accommodating cavities include a first accommodating cavity, a second accommodating cavity and a third accommodating cavity, the first accommodating cavity, the second accommodating cavity and the third accommodating cavity are communicated with each other in pairs, the first accommodating cavity is communicated with the gas outlet hole, the atomizing assembly is located in the first accommodating cavity and connected with the housing, the battery rod assembly is located in the second accommodating cavity and connected with the housing, the hydrogen-oxygen separator is located in the third accommodating cavity and connected with the housing, and the second gas outlet channel and the gas outlet hole are communicated with the first accommodating cavity.

In one embodiment, the electronic atomizer further includes a partition located between the second receiving cavity and the third receiving cavity.

In one embodiment, the mouthpiece is disposed opposite the atomizing assembly.

In one embodiment, the mouthpiece abuts against the atomizing assembly.

In one embodiment, the suction nozzle part is formed with an air passing groove, and the air outlet hole is communicated with the first accommodating cavity through the air passing groove.

In one embodiment, the number of the air passing grooves is multiple, and the air passing grooves are distributed at intervals along the circumferential direction of the mouthpiece.

In one embodiment, the air passing groove is opened at the end of the mouthpiece adjacent to the atomizing assembly.

In one embodiment, the oxyhydrogen separator comprises an oxyhydrogen separating element and a gas passing bin which are connected, the oxyhydrogen separating element is provided with a decomposition cavity, the second gas outlet channel comprises a first passage arranged on the oxyhydrogen separating element and a second passage arranged on the gas passing bin, the first passage is respectively communicated with the second passage and the decomposition cavity, the oxyhydrogen separating element comprises an electrolytic catalysis membrane assembly, and the electrolytic catalysis membrane assembly is arranged in the decomposition cavity; the electrolytic catalytic membrane module is electrically connected to the cell rod assembly and is configured to generate hydrogen and oxygen upon contact with water.

In one embodiment, the gas passing bin is sleeved on the hydrogen-oxygen separation piece.

Compared with the prior art, the invention has at least the following advantages:

foretell electronic atomization device, because the venthole communicates with first air outlet channel and second air outlet channel respectively, the atomizing gas that makes atomization component produce flows to the venthole through first air outlet channel, hydrogen and oxygen that the oxyhydrogen separator produced all flow to the venthole through second air outlet channel, make atomizing gas, hydrogen and oxygen all flow through the venthole and form atomizing mist, and then the atomizing mist that makes electronic atomization device produce has a certain amount of oxygen, electronic atomization device's suitability has been improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed 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 atomization device according to an embodiment;

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

FIG. 3 is an enlarged view of a portion of the electronic atomizer shown in FIG. 2;

FIG. 4 is a schematic structural diagram of another view angle of the electrolytic module of the hydrogen-oxygen separation device of the hydrogen-oxygen separator of the electronic atomization device shown in FIG. 2;

FIG. 5 is an exploded view of the electrospray device of FIG. 4;

FIG. 6 is a schematic view of a partial structure of the electronic atomizer shown in FIG. 5;

FIG. 7 is an exploded view of the electronic atomizer of FIG. 6;

FIG. 8 is a schematic structural view of a hydrogen-oxygen separator of the electronic atomization device shown in FIG. 6;

FIG. 9 is a cross-sectional view of the hydrogen-oxygen separator shown in FIG. 8;

FIG. 10 is a schematic view showing the configuration of the hydrogen-oxygen separating member of the hydrogen-oxygen separator shown in FIG. 8.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This 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 invention relates to an electronic atomization device which comprises a shell, an atomization assembly, a hydrogen-oxygen separator, a suction nozzle piece and a battery rod assembly, wherein the atomization assembly is arranged in the shell; the shell is provided with a containing cavity and a mounting hole which are communicated; the atomization assembly is positioned in the accommodating cavity and connected with the shell, the atomization assembly is used for generating atomization gas, and a first gas outlet channel is formed in the atomization assembly; the hydrogen-oxygen separator is positioned in the accommodating cavity and connected with the shell, the hydrogen-oxygen separator is used for generating hydrogen and oxygen, and a second gas outlet channel is formed in the hydrogen-oxygen separator; the suction nozzle piece is arranged in the mounting hole in a penetrating manner and connected with the shell, an air outlet hole is formed in the suction nozzle piece, and the air outlet hole is respectively communicated with the first air outlet channel and the second air outlet channel; and the battery rod assembly is positioned in the accommodating cavity and connected with the shell, and the battery rod assembly is electrically connected with the atomizing assembly and the hydrogen-oxygen separator respectively.

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 to fig. 2 to 3 together, the electronic atomizer 10 according to one embodiment includes a housing 100, an atomizer assembly 200, a hydrogen-oxygen separator 300, a mouthpiece 400, and a battery rod assembly 500. The housing 100 is formed with a receiving cavity 101 and a mounting hole 102 which are communicated with each other, and the atomizing assembly 200 is located in the receiving cavity 101 and connected to the housing 100. The atomizing assembly 200 is used for generating atomizing gas, the atomizing assembly 200 is formed with a first gas outlet channel 202, and the first gas outlet channel 202 is used for outputting atomizing gas. In one embodiment, a hydrogen-oxygen separator 300 is located in the accommodating chamber 101 and connected to the housing 100, and the hydrogen-oxygen separator 300 is used for generating hydrogen and oxygen. The hydrogen-oxygen separator 300 is formed with a second gas outlet channel 302, and the second gas outlet channel 302 is used for outputting hydrogen and oxygen.

Referring to fig. 2 to 3, in one embodiment, a mouthpiece 400 is inserted into the mounting hole 102 and connected to the housing 100, and the mouthpiece 400 is formed with air outlet holes 402, and the air outlet holes 402 are respectively communicated with the first air outlet channel 202 and the second air outlet channel 302, so that the atomizing gas, the hydrogen gas and the oxygen gas can all flow out through the air outlet holes 402. A battery rod assembly 500 is located in the accommodating chamber 101 and connected to the housing 100, and the battery rod assembly 500 is electrically connected to the atomizing assembly 200 and the hydrogen-oxygen separator 300, respectively. Wherein the atomization assembly 200 heats and atomizes the atomized liquid to generate the atomized gas when conducting electricity, and the hydrogen-oxygen separator 300 electrolyzes water to simultaneously generate hydrogen and oxygen when conducting electricity. In this embodiment, the atomized liquid may be tobacco tar or liquid medicine or other atomized liquid.

According to the electronic atomization device 10, the air outlet 402 is respectively communicated with the first air outlet channel 202 and the second air outlet channel 302, so that the atomization gas generated by the atomization assembly 200 flows out to the air outlet 402 through the first air outlet channel 202, the hydrogen and the oxygen generated by the oxyhydrogen separator 300 all flow out to the air outlet 402 through the second air outlet channel 302, the atomization gas, the hydrogen and the oxygen all flow out through the air outlet 402 to form atomization mixed gas, and further the atomization mixed gas generated by the electronic atomization device 10 has a certain amount of oxygen, so that the applicability of the electronic atomization device 10 is improved.

As shown in fig. 2 and 4, in one embodiment, the hydrogen-oxygen separator 300 is provided with an electrolytic catalytic membrane module 305, and the electrolytic catalytic membrane module 305 is used for generating hydrogen and oxygen when conducting electricity and contacting water, so that the hydrogen-oxygen separator 300 electrolyzes water to generate hydrogen and oxygen simultaneously when conducting electricity. In this embodiment, the electrolytic catalytic membrane module 305 includes a first catalytic layer, a second catalytic layer, and an intermediate membrane layer, where the first catalytic layer is disposed on one side of the intermediate membrane layer, and the second catalytic layer is disposed on the other side of the intermediate membrane layer, that is, the first catalytic layer, the intermediate membrane layer, and the second catalytic layer are stacked in sequence, and both the first catalytic layer and the second catalytic layer may be a phosphide layer or an oxide layer, so that the electrolytic catalytic membrane module 305 can generate hydrogen and oxygen when conducting electricity and contacting water. It is to be understood that each of the first catalytic layer and the second catalytic layer has a catalytic layer structure that catalytically generates hydrogen gas and oxygen gas, such as a phosphide layer or an oxide layer.

As shown in fig. 2, in one embodiment, the receiving cavity 101 includes a first receiving cavity 101a, a second receiving cavity 101b and a third receiving cavity 101c, the first receiving cavity 101a, the second receiving cavity 101b and the third receiving cavity 101c are communicated with each other two by two, the first receiving cavity 101a is communicated with the air outlet 402, the atomizing assembly 200 is located in the first receiving cavity 101a and is connected to the housing 100, the battery rod assembly 500 is positioned in the second receiving cavity 101b and is connected with the housing 100, the hydrogen-oxygen separator 300 is positioned in the third receiving chamber 101c and is coupled to the housing 100, the second air outlet channel 302 and the air outlet 402 are both communicated with the first accommodating cavity 101a, so that the atomizing assembly 200, the cell bar assembly 500 and the hydrogen-oxygen separator 300 can be better accommodated in the housing 100.

As shown in fig. 2, the housing 100 further includes a housing body 110, a fixing frame 120 and a cover plate 130, the housing body 110 forms a cavity 103 and an opening 104 which are communicated with each other, the fixing frame 120 is located in the cavity 103 and connected to the housing body 110, and the cover plate 130 is located in the opening to close the cavity 103. Referring to fig. 5 and fig. 6, in the present embodiment, the fixing frame 120 includes a first fixing frame 120a and a second fixing frame 120b, the first fixing frame 120a is connected to the second fixing frame 120b, a first receiving cavity 101a is formed in the first fixing frame 120a, and the atomizing assembly 200 is located in the first receiving cavity 101a and connected to the first fixing frame 120 a. The second receiving cavity 101b is formed in the second fixing frame 120b, and the battery rod assembly 500 is located in the second receiving cavity 101b and connected to the second fixing frame 120 b. The third receiving cavity 101c is formed in the first fixing frame 120a and the second fixing frame 120b, respectively, the hydrogen-oxygen separator 300 is located in the third receiving cavity 101c, and the hydrogen-oxygen separator 300 is connected to the first fixing frame 120a and the second fixing frame 120b, respectively. In the present embodiment, the first holder 120a further has a communication groove 125, which is respectively communicated with the first receiving cavity 101a and the third receiving cavity 101c to communicate the first receiving cavity 101a with the third receiving cavity 101 c. The second air outlet passage 302 communicates with the communicating groove, and the first air outlet passage 202 communicates with the first housing chamber 101a, so that the second air outlet passage 302 communicates with the first housing chamber 101 a. The mounting hole 102 is formed in the cover plate 130.

As shown in fig. 2 and fig. 6, in one embodiment, the first fixing frame 120a and the second fixing frame 120b abut against each other, the cover plate 130 abuts against the first fixing frame 120a, and the cover plate 130 is detachably connected to the housing body 110, so that the first fixing frame 120a and the second fixing frame 120b are reliably installed in the cavity 103, and the first fixing frame 120a and the second fixing frame 120b are quickly disassembled and assembled. In order to prevent the fixing frame 120 from shaking relative to the housing body 110 during use, further, the peripheral wall of the first fixing frame 120a and the peripheral wall of the second fixing frame 120b are both adapted to the cavity 103, so that the gap formed by assembling the first fixing frame 120a and the second fixing frame 120b in the housing body 110 is reduced, and the problem that the fixing frame 120 shakes relative to the housing body 110 during use is avoided. In this embodiment, the third receiving cavity 101c includes a receiving cavity main body 1012 opened on the second fixing frame 120b and a socket 1014 opened on the first fixing frame 120a, the receiving cavity main body 1012 is communicated with the socket 1014, the oxyhydrogen separator 300 is located on the receiving cavity main body 1012 and connected to the second fixing frame 120b, the oxyhydrogen separator 300 is located in the socket 1014 and connected to the first fixing frame 120a, so that the oxyhydrogen separator 300 is connected to the first fixing frame 120a and the second fixing frame 120b, and the first fixing frame 120a and the second fixing frame 120b are connected to each other in a relatively positioned manner. In order to reduce the connection swing between the first fixing frame 120a and the second fixing frame 120b and simultaneously reliably connect the first fixing frame 120a and the oxyhydrogen separator 300, further, an elastic adhesive layer is arranged on the inner wall of the sleeve hole 1014, and the oxyhydrogen separator 300 is positioned in the sleeve hole 1014 and elastically abuts against the elastic adhesive layer, so that the oxyhydrogen separator 300 is tightly connected with the first fixing frame 120a and simultaneously the connection swing between the first fixing frame 120a and the second fixing frame 120b is reduced. Furthermore, the first fixing frame 120a is provided with a guiding sliding groove, the outer wall of the second fixing frame 120b is convexly provided with a sliding guide block, and the sliding guide block is located in the guiding sliding groove and is in sliding connection with the first fixing frame 120a, so that connection shaking between the first fixing frame 120a and the second fixing frame 120b is further reduced, and the first fixing frame 120a and the second fixing frame 120b are more reliably connected and fixed.

In one embodiment, as shown in fig. 2, the mouthpiece 400 is disposed opposite to the atomizing assembly 200, so that the first air outlet channel 202 is better communicated with the air outlet 402.

In order to facilitate the rapid assembly and disassembly of the atomizing assembly 200 in the housing 100, as shown in fig. 2, further, the mouthpiece 400 is located in the mounting hole 102 and detachably connected to the cover plate 130, a center line of the first receiving cavity 101a and a center line of the mounting hole 102 are on the same straight line, so that the first receiving cavity 101a and the air outlet 402 are in direct communication, a diameter of the mounting hole 102 is greater than or equal to a diameter of the atomizing assembly 200, when disassembling, the mouthpiece 400 can be disassembled first, and then the atomizing assembly 200 can be taken out through the mounting hole 102; similarly, when the nozzle assembly 400 is installed, the atomizing assembly 200 may be first assembled in the first receiving cavity 101a through the installation hole 102, and then the nozzle assembly 400 may be assembled in the installation hole 102; thus, the atomizing assembly 200 can be easily and quickly assembled and disassembled, even if the atomizing assembly 200 is quickly assembled and disassembled in the housing 100. In this embodiment, the nozzle 400 is detachably connected to the cover plate 130, so that the nozzle 400 is detachably connected to the cover plate 130, and the nozzle 400 is quickly detached from the cover plate 130. In this embodiment, the nozzle part 400 includes a nozzle part main body and a sealing connection member, the outer peripheral wall of the nozzle part main body is formed with a connection ring groove, the sealing connection member is located in the connection ring groove and connected with the nozzle part main body, and the sealing connection member elastically abuts against the inner peripheral wall of the mounting hole 102, so that the nozzle part 400 is tightly connected with the cover plate 130, and the nozzle part 400 is connected with the cover plate 130 in a detachable manner.

As shown in fig. 2 and 3, the nozzle part 400 is further formed with an air passing groove 404, and the air outlet 402 is communicated with the first receiving cavity 101a through the air passing groove, so that the air outlet 402 is communicated with the first receiving cavity 101 a. In order to avoid the situation that the atomizing element 200 shakes in the first receiving cavity 101a, in one embodiment, the nozzle 400 abuts against the atomizing element 200, so that the atomizing element 200 is reliably fixed in the first receiving cavity 101a, and the situation that the atomizing element 200 shakes in the first receiving cavity 101a is avoided. In the embodiment, the nozzle 400 is partially located in the first receiving cavity 101a and abuts against the atomizing element 200, so that the atomizing element 200 is reliably fixed in the first receiving cavity 101a, thereby preventing the atomizing element 200 from shaking in the first receiving cavity 101a, and the nozzle 400 is formed with an air passing groove, so that the air outlet 402 is reliably communicated with the first receiving cavity 101 a. To reliably communicate the communication groove with the first housing chamber 101a, further, the third housing chamber 101c communicates with the gas outlet hole 402 through the communication groove and the gas passing groove, and reliably communicates the third housing chamber 101c with the gas outlet hole 402. The first receiving cavity 101a communicates with the air outlet hole 402 through the air passing groove, so that the first receiving cavity 101a communicates with the air outlet hole 402 reliably. In one embodiment, the number of the air passing grooves is multiple, and the air passing grooves are distributed at intervals along the circumferential direction of the mouthpiece 400, so that the air outlet 402 is better communicated with the first receiving cavity 101 a. To facilitate the processing of the air passing groove 404, in one embodiment, the air passing groove is opened at the end of the mouthpiece 400 adjacent to the atomizing assembly 200, so that the air passing groove 404 is processed with low difficulty, so as to facilitate the processing of the air passing groove 404.

As shown in fig. 2 and 3, further, the second fixing frame 120b is provided with a gas passing hole 106, the housing body 110 is provided with a gas inlet hole 112 communicated with the cavity 103, the gas inlet hole 112 and the gas passing hole 106 are both communicated with the third receiving cavity 101c, the atomizing assembly 200 is provided with a communicating hole 203 and an atomizing cavity 205, the atomizing cavity is respectively communicated with the communicating hole and the first gas outlet channel 202, the gas passing hole 106 is further communicated with the communicating hole, so that the air current around the housing body 110 flows into the atomizing cavity through the gas inlet hole 112, the third receiving cavity 101c, the gas passing hole 106 and the communicating hole to be heated and atomized to form the atomized gas, and the atomizing assembly 200 can reliably form the atomized gas. In this embodiment, the atomizing assembly 200 includes an atomizing assembly main body 210, an atomizing core 220 and an atomizing base 230, the atomizing assembly main body 210 is formed with an atomizing channel 212, a liquid storage cavity 214 and a liquid inlet hole 216 that are communicated, the atomizing channel is communicated with the liquid inlet hole, the atomizing core is located in the atomizing channel and is connected with the atomizing assembly main body 210, the atomizing cavity is formed in the atomizing core, the communication hole is formed in the atomizing base, a first air outlet channel 202 is formed in the atomizing assembly main body 210 and is communicated with the atomizing channel, so that the atomized liquid in the liquid storage cavity flows into the atomizing channel through the liquid inlet hole, the atomizing core heats the atomized liquid to generate atomized vapor, the air flow enters the atomizing cavity through the communication hole and mixes with the atomized vapor to form atomized gas, the atomized gas flows out through the atomizing channel and the first air outlet channel 202, so that the atomizing assembly 200 reliably generates atomized gas.

In order to better electrically connect the battery rod assembly 500 to the atomizing assembly 200, the second fixing frame 120b is further provided with a first fixing hole 122 and a second fixing hole 124, the electronic atomizing device 10 further includes a first elastic needle 900 and a second elastic needle 1100, the first elastic needle is inserted into the first fixing hole and connected to the second fixing frame 120b, and the second elastic needle is inserted into the second fixing hole and connected to the second fixing frame 120 b. The first elastic needle and the second elastic needle are respectively electrically connected with the anode and the cathode of the atomization core, and the first elastic needle and the second elastic needle are also respectively electrically connected with the anode and the cathode of the battery rod assembly 500, so that the battery rod assembly 500 is better electrically connected with the atomization assembly 200.

As shown in fig. 5 and 6, in one embodiment, the electronic atomization device 10 further includes a partition member 600, which is located between the second receiving cavity 101b and the third receiving cavity 101c, and separates the battery rod assembly 500 and the hydrogen-oxygen separator 300 from each other. In this embodiment, the partition member is disposed on the second fixing frame 120b to form a second receiving cavity 101b and the third receiving cavity 101 c. To facilitate electrical connection of the hydrogen-oxygen separator 300 to the battery rod assembly 500, further, the partition member is formed with wire passing ports that communicate with the second receiving chamber 101b and the third receiving chamber 101c, respectively, so that the hydrogen-oxygen separator 300 is electrically connected to the battery rod assembly 500.

As shown in fig. 5, 6 and 7, the electronic atomization device 10 further includes a control assembly 700, the housing body 110 is opened with an exposed hole 115, and a portion of the control assembly 700 is exposed on the surface of the housing body 110 through the exposed hole, so that the control assembly 700 controls the operation of the hydrogen-oxygen separator 300 during use. The control assembly 700 is electrically connected to control terminals of the cell bar assembly 500 and the hydrogen-oxygen separator 300, respectively. In this embodiment, the control assembly 700 includes a touch button 710 and a control board 720, the touch button is movably disposed on the control board, and the touch button is exposed on the surface of the housing body 110 through an exposed hole, so that the control assembly 700 controls the operation of the hydrogen-oxygen separator 300 during use. The control board is electrically connected to the control terminals of the cell bar assembly 500 and the hydrogen-oxygen separator 300, respectively. In one embodiment, the control board is disposed in the housing body 110 and connected to the second fixing frame 120 b.

As shown in fig. 2, further, a charging interface 113 is arranged on the housing body 110, the air inlet 112 is opened on the charging interface, the charging interface is arranged on the control board and is electrically connected with the control board, and the control board is electrically connected with the battery rod assembly 500, so that the charging interface is electrically connected with the battery rod assembly 500. When the electronic atomization device is used, the battery rod assembly 500 can be charged through the charging interface, and the use convenience of the electronic atomization device 10 is improved. In this embodiment, the charging interface may be a USB charging interface.

As shown in fig. 7 to 9, in one embodiment, the oxyhydrogen separator 300 includes an oxyhydrogen separator 310 and a gas passing bin 320 connected with each other, the oxyhydrogen separator 310 is formed with a decomposition cavity 301, the second gas outlet channel 302 includes a first passageway 302a opened to the oxyhydrogen separator 310 and a second passageway 302b opened to the gas passing bin 320, and the first passageway 302a is respectively communicated with the second passageway 302b and the decomposition cavity 301. The hydrogen-oxygen separation member 310 is provided with an electrolysis catalytic membrane assembly, and the electrolysis catalytic membrane assembly is arranged in the decomposition cavity 301. The electrolytic catalytic membrane module is electrically connected to the cell rod assembly 500 and serves to generate hydrogen and oxygen when in contact with water, so that the hydrogen-oxygen separator 300 can simultaneously generate hydrogen and oxygen.

As shown in fig. 8 and 9, in one embodiment, the gas passing bin 320 is sleeved on the hydrogen-oxygen separator 310, so that the gas passing bin 320 is better connected to the hydrogen-oxygen separator 310. Further, the hydrogen-oxygen separator 310 comprises a hydrogen-oxygen separator 312 and a first waterproof and air-permeable assembly 314, and the gas passing bin 320 comprises a gas passing device 322 and a second waterproof and air-permeable assembly 324. The first passageway 302a is opened to the hydrogen-oxygen separation device 312, and the second passageway 302b is opened to the gas passing device. The hydrogen-oxygen separation device 312 is further formed with a first airflow hole 3122 communicating with the first passageway 302a, the first waterproof and breathable assembly 314 being provided at the first airflow hole 3122. In this embodiment, the hydrogen-oxygen separation device 312 is provided with an electrolytic catalytic membrane module, and the decomposition chamber 301 is communicated with the first channel 302 a. The gas passing device 322 is connected to the oxyhydrogen separation device 312, and the gas passing device 322 is formed with a second gas flow hole 3222 communicated with the second passageway 302b, so that the first gas flow hole 3122 and the second gas flow hole 3222 are communicated with the second passageway 302 b. A second waterproof and breathable assembly 324 is disposed at the second airflow aperture 3222.

Because the oxyhydrogen separation device 312 is provided with the first air flow hole 3122, the first waterproof air-permeable assembly 314 is disposed at the first air flow hole 3122, the gas passing device 322 is connected to the oxyhydrogen separation device 312, and the gas passing device 322 is provided with the second air flow hole 3222 and the second passage 302b, the second passage 302b is respectively communicated with the first air flow hole 3122 and the second air flow hole 3222, and because the second waterproof air-permeable assembly 324 is disposed at the second air flow hole 3222, hydrogen and oxygen generated by the oxyhydrogen separation device 312 both flow out through the first air flow hole 3122 and the second air flow hole 3222, during the flowing out of the hydrogen and oxygen, the hydrogen and oxygen are sequentially filtered through the first waterproof air-permeable assembly 314 and the second waterproof air-permeable assembly 324, so that moisture contained in the hydrogen and oxygen generated by the oxyhydrogen separation device 310 can be better removed through the water removal effect of the first waterproof air-permeable assembly 314 and the second waterproof air-permeable assembly 324 twice, the water removing effect of the hydrogen and oxygen generated from the hydrogen-oxygen separating member 310 is improved.

As shown in fig. 9, in one embodiment, the hydrogen-oxygen separation device 312 comprises an electrolysis shell 312a and an electrolysis module 312b, wherein the electrolysis shell 312a is formed with a decomposition cavity 301, and the electrolysis module 312b is positioned in the decomposition cavity 301 and connected with the electrolysis shell 312 a. In the present embodiment, the electrolysis module 312b generates hydrogen and oxygen when it is electrically conductive and in contact with water. The first air flow hole 3122 is opened in the electrolytic case 312a and communicates with the decomposition chamber 301, so that hydrogen and oxygen generated from the electrolysis module 312b flow out through the first air flow hole 3122. The gas passing device 322 is sleeved on the electrolytic shell 312a, so that the gas passing device 322 is connected with the hydrogen-oxygen separation device 312. In this embodiment, the electrolysis module 312b is provided with an electrolysis catalytic membrane assembly 305, and the gas passing bin 320 is sleeved on the electrolysis shell, so that the gas passing bin 320 is sleeved on the hydrogen-oxygen separation device 312. The water can be direct drinking water, mineral water, purified water or the like, and compared with the traditional mode of adopting alkaline electrolyte to carry out chemical reaction to generate hydrogen and oxygen, the use convenience of the electronic atomization device 10 is greatly improved; in addition, the electrolysis module 312b has better oxygen generation efficiency.

In one embodiment, the electrolytic case 312a is formed with a first coupling flange on the inner circumferential wall of the first airflow hole 3122, and the first waterproof and breathable member 314 is coupled to the first coupling flange, so that the first waterproof and breathable member 314 is better disposed at the first airflow hole 3122. In one embodiment, the first waterproof and breathable assembly 314 is glued to the first connecting flange, so that the first waterproof and breathable assembly 314 is firmly connected to the first connecting flange, and the hydrogen-oxygen separator 310 is compact. In one embodiment, the first waterproof and breathable assembly 314 includes a first mounting seat, a first fixing seat and a first waterproof and breathable film layer, wherein the first mounting seat is mounted on the inner peripheral wall of the first airflow hole 3122. The first fixing seat is connected to the first mounting seat, the first waterproof breathable film layer is clamped between the first fixing seat and the first mounting seat, and the first waterproof breathable film layer and the first airflow hole 3122 are correspondingly arranged, so that the first waterproof breathable assembly 314 can better remove moisture in hydrogen and oxygen.

In one embodiment, the air passing device 322 has a second connecting flange formed on the inner peripheral wall of the second air flow hole 3222, and the second waterproof and air-permeable member 324 is connected to the second connecting flange, so that the second waterproof and air-permeable member 324 is better disposed in the second air flow hole 3222. In one embodiment, the second waterproof and breathable assembly 324 is glued to the second connecting flange, so that the second waterproof and breathable assembly 324 is firmly connected to the second connecting flange, and the hydrogen-oxygen separator 310 is compact. In one embodiment, the second waterproof and breathable assembly 324 includes a second mounting seat, a second fixing seat and a second waterproof and breathable film layer, the second mounting seat is mounted on the inner peripheral wall of the second airflow hole 3222, the second fixing seat is connected to the second mounting seat, the second waterproof and breathable film layer is clamped between the second fixing seat and the second mounting seat, and the second waterproof and breathable film layer is disposed corresponding to the second airflow hole 3222, so that the second waterproof and breathable assembly 324 can better remove moisture in hydrogen and oxygen.

As shown in fig. 8 and 9, in one embodiment, the extending direction of the first air flow hole 3122 and the extending direction of the second air flow hole 3222 are inclined, so that the first air flow hole 3122 and the second air flow hole 3222 are not arranged in an opposite direction, and further, the path for the hydrogen gas and the oxygen gas to flow out through the first air flow hole 3122, the second passageway 302b and the second air flow hole 3222 is longer, so that the moisture contained in the hydrogen gas and the oxygen gas generated by the hydrogen-oxygen separator 310 can be better removed, and the water removal effect of the hydrogen gas and the oxygen gas generated by the hydrogen-oxygen separator 310 is further improved. In this embodiment, the extending direction of the first air flow hole 3122 and the extending direction of the second air flow hole 3222 are perpendicular to each other, that is, the angle between the extending direction of the first air flow hole 3122 and the extending direction of the second air flow hole 3222 is 90 °. It is understood that in other embodiments, the angle between the extending direction of the first air flow hole 3122 and the extending direction of the second air flow hole 3222 is not limited to 90 °, but may be 60 ° or 150 °, etc.

As shown in fig. 9, further, the electrolytic cell 312a includes an electrolytic cell main body 3123 and an air outlet boss 3125 connected, and referring to fig. 10, a liquid collection groove 3127 is formed on the outer surface of the electrolytic cell main body 3123, and a first air flow hole 3122 is formed on the air outlet boss 3125. The gas passing device is respectively sleeved on the electrolysis shell main body 3123 and the gas outlet boss 3125, and the gas passing device 322 is formed with a second gas flow hole 3222, a second passageway 302b and a liquid pouring port 3223. The second passage is respectively communicated with the liquid collecting groove 3127, the liquid pouring port 3223 and the second airflow hole 3222. The first airflow aperture 3122 is above the bottom of the sump 3127 in communication with the second aisle, and the second airflow apertures 3222 is above the bottom of the sump 3127 in communication with the second aisle; in this embodiment, the decomposition chamber 301 is opened to the electrolytic cell body 3123, and the first passage 302a is opened to the gas outlet boss 3125 and communicates with the first gas flow hole 3122.

As shown in fig. 5, 6 and 9, the electronic atomization device 10 further includes a sealing plug 1200, the cover plate 130 is provided with a connection hole 132, the sealing plug is inserted into the connection hole, and the sealing plug is detachably connected to the liquid pouring port 3223. Because the liquid pouring port 3223 is detachably connected with the sealing plug, the water in the liquid collecting groove 3127 can be cleaned by dismounting the sealing plug, the problem that the water in the air outlet channel of the traditional oxyhydrogen separator 300 is not easy to clean is solved, and the use convenience of the oxyhydrogen separator 300 is improved. In one embodiment, the sealing plug 1200 is connected to the liquid pouring port 3223 in a plugging manner, so that the sealing plug is quickly detached from the liquid pouring port 3223. And/or, in one embodiment, the sealing plug includes a sealing plug body and an elastic ring, the sealing plug body is inserted into the connecting hole, the elastic ring is sleeved on the sealing plug body, and the elastic ring elastically abuts against the inner peripheral wall of the liquid pouring port 3223, so that the sealing plug is reliably inserted into and connected to the liquid pouring port 3223. In this embodiment, the elastic ring is a rubber ring or a silicone ring.

Because the electrolytic shell comprises the electrolytic shell main body 3123 and the air outlet boss 3125 which are connected, the liquid collecting groove 3127 is formed on the outer surface of the electrolytic shell main body 3123, the gas passing device is respectively sleeved on the electrolytic shell main body 3123 and the air outlet boss 3125, the second passage is communicated with the liquid collecting groove 3127, the hydrogen and the oxygen generated by the hydrogen-oxygen separation device 312 enter the second passage through the first gas flow hole 3122 and flow out of the second gas flow hole 3222 through the second passage, so that the moisture in the hydrogen and the oxygen generated by the hydrogen-oxygen separation device 312 is formed on the inner wall of the second passage, and the communication position of the first gas flow hole 3122 and the second passage is located above the bottom of the liquid collecting groove 3127, the communication position of the second gas flow hole 3222 and the second passage is located above the bottom of the liquid collecting groove 3127, so that the moisture on the inner wall of the second passage is collected at the bottom of the liquid collecting groove 3127, and the buffer function is achieved; because the liquid pouring port 3223 is detachably connected with the sealing plug, the water in the liquid collecting groove 3127 can be cleaned by dismounting the sealing plug, the problem that the water in the air outlet channel of the traditional oxyhydrogen separator 300 is not easy to clean is solved, and the use convenience of the oxyhydrogen separator 300 is improved.

In one embodiment, as shown in fig. 9, the communication between the first airflow hole 3122 and the second passageway is located at the end of the air outlet boss 3125 far from the electrolysis shell main body 3123, so that the moisture in the liquid collection tank 3127 is not easy to flow back from the first airflow hole 3122, and the moisture is better buffered in the liquid collection tank 3127.

In order to firmly connect the electrolysis shell main body 3123 with the air outlet boss 3125 and to make the structure of the hydrogen-oxygen separation device 312 more compact, as shown in fig. 9 and 10, in one embodiment, the electrolysis shell main body 3123 is integrally formed with the air outlet boss 3125, so that the electrolysis shell main body 3123 is firmly connected with the air outlet boss 3125 and the structure of the hydrogen-oxygen separation device 312 is made more compact. It is understood that in other embodiments, the electrolytic cell body 3123 and the air outlet boss 3125 are not limited to being integrally formed. For example, the electrolytic cell case body 3123 and the air outlet boss 3125 may be separately formed and fixedly coupled by adhesive bonding.

In one embodiment, as shown in fig. 10, the outer surface of the electrolytic shell main body 3123 is convexly provided with a baffle 3126, the baffle 3126 is connected to the air outlet boss 3125 to enclose the liquid collecting groove 3127, so that the outer surface of the electrolytic shell main body 3123 is formed with the liquid collecting groove 3127. In one embodiment, the baffle 3126 includes a first baffle 3126a, a second baffle 3126b and a third baffle 3126c, which are connected in sequence, an end of the first baffle 3126a far away from the second baffle 3126b is connected to the gas outlet boss 3125, and an end of the third baffle 3126c far away from the second baffle 3126b is connected to the gas outlet boss 3125, so as to enclose the liquid collecting tank 3127.

In one embodiment, the oxyhydrogen separation device 312 further includes a sealing fixture, the enclosure member 3126 defines a first open-loop groove 3126d, the exhaust boss 3125 defines a second open-loop groove 3125a, and the first open-loop groove and the second open-loop groove are correspondingly communicated. The sealing fixing piece is respectively positioned in the first open-loop groove and the second open-loop groove, and the sealing fixing piece is elastically abutted against the gas passing device, so that the gas passing device is respectively better sleeved on the electrolytic shell main body 3123 and the gas outlet boss 3125. In this embodiment, the sealing fixing member may be a silicone sealing ring or a rubber sealing ring.

Referring again to fig. 9, in one embodiment, the electrolytic catalytic membrane module 305 is located within the decomposition chamber 301 and is connected to the electrolytic housing body 3123 such that the electrolytic catalytic membrane module 305 generates hydrogen and oxygen when in contact with water within the decomposition chamber 301. In one embodiment, the inner wall of the decomposition chamber 301 is provided with a fixing portion 301 a. The electrolytic module 200 is positioned in the decomposition chamber 301 and is mounted to the fixing portion 301a such that the electrolytic module 200 is mounted in the decomposition chamber 301 and can be brought into contact with water in the decomposition chamber 301.

Referring to fig. 4 and 9 again, the electrolysis module 312b further includes a first conductive electrode layer 3131 and a second conductive electrode layer 3132, the first conductive electrode layer 3131, the electrolysis catalysis membrane assembly 305 and the second conductive electrode layer 3132 are stacked, and the first conductive electrode layer 3131 and the second conductive electrode layer 3132 are electrically connected to the electrolysis catalysis membrane assembly respectively. In this embodiment, the first conductive electrode layer 3131, the first catalytic layer, the middle film layer, the second catalytic layer, and the second conductive electrode layer 3132 are stacked. Further, the electrolysis module 312b further includes a first conductive enhancement layer 3128 and a second conductive enhancement layer 3129, the first conductive enhancement layer 3128 is disposed between the first conductive electrode layer 3131 and the first catalytic layer, and the second conductive enhancement layer 3129 is disposed between the second conductive electrode layer 3132 and the second catalytic layer, which increases the electrical conductivity between the first conductive electrode layer 3131 and the first catalytic layer, and increases the electrical conductivity between the second conductive electrode layer 3132 and the second catalytic layer.

As shown in fig. 2 and 4, in one embodiment, the first conductive electrode layer 3131, the first conductive enhancement layer 3128, the first catalytic layer, the middle film layer, the second catalytic layer, the second conductive enhancement layer 3129, and the second conductive electrode layer 3132 are stacked, so that the overall structure of the electrolysis module 312b is compact, and the first conductive electrode layer 3131, the first conductive enhancement layer 3128, the first catalytic layer, the middle film layer, the second catalytic layer, the second conductive enhancement layer 3129, and the second conductive electrode layer 3132 are better fixed and assembled together, thereby making the structure of the electrolysis module 312b more compact.

In one embodiment, the first conductive enhancement layer 3128 is a titanium foam mesh layer or a nickel foam mesh layer, which provides the first conductive enhancement layer 3128 with better electrical conductivity and facilitates the discharge of generated hydrogen or oxygen. In this embodiment, the first conductive reinforcement layer 3128 is a titanium foam mesh layer. And/or, in one embodiment, the second conductive enhancement layer 3129 is a titanium foam mesh layer or a nickel foam mesh layer, so that the second conductive enhancement layer 3129 has better electrical conductivity and facilitates the discharge of generated hydrogen or oxygen. In this embodiment, the second conductive reinforcement layer 3129 is a titanium foam mesh layer.

As shown in fig. 2 and fig. 4, in one embodiment, the electrolysis module 312b further includes a first pressing member 3133 and a second pressing member 3134, the first pressing member 3133 abuts against a side of the first conductive electrode layer 3131 facing away from the electrolytic catalytic membrane assembly 305, and the second pressing member 3134 abuts against a side of the second conductive electrode layer 3132 facing away from the electrolytic catalytic membrane assembly 305, so that the first conductive electrode layer 3131, the electrolytic catalytic membrane assembly 305, and the second conductive electrode layer 3132 are pressed between the first pressing member 3133 and the second pressing member 3134.

In one embodiment, the first pressing member 3133 includes a first pressing member body and a first insulating layer, the first insulating layer abuts against a side of the first conductive electrode layer 3131 facing away from the electrolytic catalytic membrane assembly 305, the first pressing member body abuts against a side of the first insulating layer facing away from the first conductive electrode layer 3131, so that the first pressing member body and the first conductive electrode layer 3131 are insulated from each other, and the first pressing member body fixes the first insulating layer to the side of the electrolytic catalytic membrane assembly 305. In one embodiment, the second pressing element 3134 includes a second pressing element body and a second insulating layer, the second insulating layer abuts against a side of the second conductive electrode layer 3132 away from the electrolytic catalytic membrane assembly 305, the second pressing element body abuts against a side of the second insulating layer away from the second conductive electrode layer 3132, so that the second pressing element body and the second conductive electrode layer 3132 are insulated from each other, and the second pressing element body fixes the second insulating layer to the other side of the electrolytic catalytic membrane assembly 305. In this embodiment, the first pressing member body and the second pressing member body are both metal members, so that the first pressing member body and the second pressing member body both have better compressive strength. It is understood that, in other embodiments, the first pressing member body and the second pressing member body are not limited to metal members, for example, the first pressing member body and the second pressing member body may also be ceramic members or other materials.

As shown in fig. 4 and 9, in one embodiment, the electrolytic module 312b further includes a fixing element 3135, the first pressing element body defines a first mounting hole 3133a, the second pressing element body defines a second mounting hole (not shown), the first insulating layer defines a first via hole communicating with the first mounting hole, the second insulating layer defines a second via hole communicating with the second mounting hole, the first conductive electrode layer 3131 defines a third via hole communicating with the first via hole, the second conductive electrode layer 3132 defines a fourth via hole communicating with the second via hole, the electrolytic catalytic membrane assembly 305 defines a connecting hole, the fixing element 3135 is respectively disposed through the first mounting hole, the first via hole, the third via hole, the connecting hole, the fourth via hole, the second via hole and the second mounting hole, the first pressing member body, the first insulating layer, the first conductive electrode layer 3131, the electrolytic catalytic membrane module 305, the second conductive electrode layer 3132, the second insulating layer, and the first pressing member body are fixedly connected. And/or the presence of a catalyst in the reaction mixture,

in one embodiment, the first pressing member body defines a first opening, and the first insulating layer defines a second opening communicating with the first opening, such that the first conductive electrode layer 3131 is exposed through the second opening and the first opening, so as to discharge the generated hydrogen and oxygen. The second pressing piece body is provided with a third naked hole, the second insulating layer is provided with a fourth naked hole communicated with the third naked hole, and the second conductive electrode layer 3132 is exposed outside through the fourth naked hole and the third naked hole so as to discharge generated hydrogen and oxygen. In one embodiment, the first conductive electrode layer 3131 is formed with a fifth bare hole communicating with the second bare hole, and the second conductive electrode layer 3132 is formed with a sixth bare hole communicating with the fourth bare hole, to further facilitate the discharge of oxygen and hydrogen, while increasing the contact area of the electrolytic catalytic membrane assembly with water. In the present embodiment, the first and second

conductive electrode layers

3131 and 3132 may each be a mesh laminate structure. And/or, in one embodiment, the first conductive electrode layer 3131 is a stainless steel mesh layer, a titanium metal mesh layer, or a nickel mesh layer, so that the first conductive electrode layer 3131 has a better conductive performance. And/or, in one embodiment, the second conductive electrode layer 3132 is a stainless steel mesh layer, a titanium metal mesh layer, or a nickel mesh layer, so that the second conductive electrode layer 3132 has a better conductive performance. And/or, in one embodiment, the middle membrane layer is a high polymer membrane layer or a nylon layer, so that the catalyst layer structures are better arranged on two sides of the middle membrane layer. In this embodiment, the first catalytic layer and the second catalytic layer are respectively disposed on two sides of the middle film layer.

In one embodiment, the fixing portions 301a are at least two fixing ribs, two adjacent fixing ribs are arranged in parallel, and the electrolytic module 200 is installed between two adjacent fixing ribs, so that the installation difficulty of the electrolytic module 200 is low, and meanwhile, the structure of the fixing portions 301a is simple, and further, the structure of the hydrogen-oxygen separation device 10 is simple. In this embodiment, the electrolytic module 200 is clamped between two adjacent fixed ribs, so that the electrolytic module 200 is quickly mounted between two adjacent fixed ribs. It is understood that in other embodiments, the electrolysis module 200 is fixed between two adjacent fixing ribs by clamping. For example, the electrolysis module 200 is fixed between two adjacent fixing ribs by a screw fixing method.

As shown in fig. 2 and 9, in one embodiment, the electrolytic case 312a further comprises a blocking cover 3136, the decomposition chamber 301 and the first airflow hole 3122 are both opened to the electrolytic case main body 3123, and the blocking cover 3136 is covered on the electrolytic case main body 3123 to block the decomposition chamber 301. The plugging cover 3136 is provided with a first conductive pillar and a second conductive pillar, which are both electrically connected to the electrolytic catalytic membrane assembly 305, so that the electrolytic catalytic membrane assembly 305 is externally connected to conduct electricity through the first conductive pillar and the second conductive pillar, respectively. In the present embodiment, at least one of the positive conductive terminal and the negative conductive terminal of the electrolytic catalytic membrane assembly 305 protrudes from the electrolytic shell main body and is electrically connected to the corresponding conductive column. Specifically, the positive conductive end is electrically connected to the first conductive pillar, and the negative conductive end is electrically connected to the second conductive pillar.

As shown in fig. 2 and 9, in one embodiment, the blocking cover 3136 is detachably connected to the main body 3123 of the electrolytic case to add water or clean the inside of the main body 3123 of the electrolytic case, so as to improve the convenience of the hydrogen-oxygen separation device 10. In one embodiment, the sealing lid 3136 includes a sealing lid body and a sealing ring, the sealing lid body has a connection ring groove formed on a peripheral wall thereof, the sealing ring is protruded from the connection ring groove, the sealing ring elastically abuts against an inner wall of the main cell 3123, so that the main cell 3123 and the sealing lid body are tightly connected, and the connection structure between the main cell 3123 and the sealing lid body is simple. In this embodiment, the sealing ring can be a silica gel ring or a rubber ring, so that the structure of the sealing ring is simpler.

As shown in fig. 2 and 9, in one embodiment, the sealing cap 3136 is provided with a water filling hole 3137 communicating with the decomposition chamber 301 so as to fill the water storage tank 100 through the water filling hole 3137, so that the sealing cap 3136 does not need to be opened during filling, thereby improving the convenience of the hydrogen-oxygen separation device 10. In this embodiment, the electronic atomization device 10 further includes a water injection plug 800, the housing body 110 is formed with a water filling hole 115 correspondingly communicated with the water injection hole, the water injection plug is connected to the housing body 110, and the water injection plug is used for plugging the water filling hole, so as to regularly add water.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is specific and detailed, but not to be understood as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. An electronic atomization device, comprising:

2. The electronic atomizing device according to claim 1, wherein the accommodating chamber includes a first accommodating chamber, a second accommodating chamber, and a third accommodating chamber, two of the first accommodating chamber, the second accommodating chamber, and the third accommodating chamber are communicated with each other, the first accommodating chamber is communicated with the air outlet, the atomizing element is located in the first accommodating chamber and connected to the housing, the battery rod assembly is located in the second accommodating chamber and connected to the housing, the hydrogen-oxygen separator is located in the third accommodating chamber and connected to the housing, and the second air outlet channel and the air outlet are communicated with the first accommodating chamber.

3. The electronic atomization device of claim 2 further comprising a divider member positioned between the second receiving cavity and the third receiving cavity.

4. The electronic atomizing device of claim 1, wherein the mouthpiece is disposed directly opposite the atomizing assembly.

5. The electronic atomization device of claim 4 wherein the mouthpiece abuts the atomization assembly.

6. The electronic atomizer according to claim 5, wherein said mouthpiece is formed with an air passing groove, and said air outlet is communicated with said first receiving chamber through said air passing groove.

7. The electronic atomizer of claim 6, wherein said air passing grooves are plural in number, and said air passing grooves are spaced circumferentially along said mouthpiece.

8. The electronic atomizer device of claim 6, wherein said air passing groove opens at an end of said mouthpiece adjacent to said atomizing assembly.

9. The electronic atomization device of claim 1, wherein the oxyhydrogen separator comprises an oxyhydrogen separator and a gas passing bin which are connected, the oxyhydrogen separator is provided with a decomposition cavity, the second gas outlet channel comprises a first passage and a second passage, the first passage is arranged on the oxyhydrogen separator, the second passage is arranged on the gas passing bin, the first passage is communicated with the second passage and the decomposition cavity, the oxyhydrogen separator comprises an electrolysis catalytic membrane assembly, and the electrolysis catalytic membrane assembly is arranged in the decomposition cavity; the electrolytic catalytic membrane module is electrically connected to the cell rod assembly and is configured to generate hydrogen and oxygen upon contact with water.

10. The electronic atomization device of claim 9, wherein the gas passing bin is sleeved on the hydrogen-oxygen separation piece.