CN117158664A - Shared electronic atomization system and control method thereof - Google Patents

Abstract

The invention discloses a shared electronic atomization system and a control method thereof, wherein the method comprises the steps of acquiring position information and atomization matrix information transmitted by a plurality of electronic atomization devices; selecting a target electronic atomization device according to the position information and the atomization matrix information; connecting the suction nozzle sleeve with the target electronic atomization device and generating connection information; according to the connection information, sending sucking habit data of a user in a suction nozzle sleeve to the target electronic atomization device; acquiring a sucking start signal according to the sucking habit data; and controlling the first atomization assembly or the second atomization assembly to work according to the sucking start signal and the sucking habit data. The invention can improve the adjusting efficiency and the using efficiency, is convenient for users to use, and avoids the problems that the carrying of various electronic atomizing devices is inconvenient, and atomized matrixes are easy to leak so as to be stained with clothes.

Description

Shared electronic atomization system and control method thereof

Technical Field

The invention relates to the technical field of electronic atomization, in particular to a shared electronic atomization system and a control method thereof.

Background

The electronic atomizing device is an electronic product which can atomize atomized liquid to generate aerosol for users to inhale, and the atomized substrate can be water, essence, spice or liquid medicine. It can be used for stopping addiction or treating diseases, etc., and has wide application range. The existing electronic atomization devices are basically private articles which are exclusive to individuals and cannot be obtained and used at will in public places, so that users have to carry about, and the electronic atomization devices are very inconvenient to use.

To solve the above technical problems, for example, chinese patent with patent application No. CN202022034695.9 discloses a sharable electronic atomization device, which includes: a storage base, an electronic cigarette array and a charging column; a plurality of first accommodating cavities matched with the electronic cigarette array are arranged on the thickened side wall of the storage base; the electronic cigarette array is arranged in the first accommodating cavity; one end of the charging column is arranged at the bottom of the first accommodating cavity, and the other end of the charging column is movably connected with the electronic cigarette array; and the cigarette holder of electron cigarette array is removable cigarette holder, and everyone can change the cigarette holder when using electron cigarette array again, has solved the unable problem that many people shared the use of electron cigarette array in the current design.

However, each user has different preference for the atomized substrate and has different inhalation amounts without aerosol, so that each time the user wants to use, the user needs to find the storage place of the electronic atomization device everywhere, then carefully select the atomized substrate according to the needs, and then perform long-term adjustment on the atomization power to achieve the required effect. Thus, the adjustment efficiency is low and the use is inconvenient for the user.

The above disadvantages are to be improved.

Disclosure of Invention

In order to solve or alleviate the problem of low atomization adjustment efficiency of the existing shared electronic atomization system, the invention provides a shared electronic atomization system and a control method thereof.

The technical scheme of the invention is as follows:

the shared electronic atomization system comprises an electronic atomization device, a suction nozzle sleeve, a remote server and a mobile terminal, wherein the electronic atomization device comprises an atomization substrate, a first atomization component, a second atomization component, a positioning module, a controller and a first wireless communication module, and the atomization substrate comprises a first atomization substrate and a second atomization substrate; the first atomization assembly is used for atomizing the first atomization substrate, and the second atomization assembly is used for atomizing the second atomization substrate; the positioning module is used for providing position information; the controller is used for controlling the first atomization assembly and the second atomization assembly to work; the first wireless communication module is used for communicating with the remote server and the suction nozzle sleeve; the electronic atomization device is used for being placed at a public place to atomize the atomized substrate;

The suction nozzle sleeve comprises a sleeve body, a memory, a microprocessor and a second wireless communication module, wherein the sleeve body is used for being detachably connected with the electronic atomization device; the memory is used for storing sucking habit data of a user; the microprocessor is used for sending the sucking habit data to the first wireless communication module through the second wireless communication module; in a first state, the suction nozzle sleeve is spaced from the electronic atomization device and is used for being placed at a user; in a second state, the suction nozzle sleeve is connected with the electronic atomization device so that the electronic atomization device can atomize the atomized substrate; the remote server is used for sending the information of the electronic atomization device to the mobile terminal; the mobile terminal is used for presenting the information sent by the remote server to a user and carrying out information interaction with the suction nozzle sleeve.

The suction nozzle sleeve further comprises a one-way valve, an air outlet hole used for being communicated with the first atomization component and the second atomization component is formed in the sleeve body, and the one-way valve is installed in the air outlet hole and used for preventing liquid from flowing into the electronic atomization device from the air outlet hole.

According to the sharing electronic atomization system, the suction nozzle sleeve further comprises a plurality of layers of protective films which are detachably coated on the sleeve body.

The electronic atomization device further comprises a shell, a first compression assembly and an airflow sensor, wherein an isolation tube, a first liquid suction tube and a second liquid suction tube are accommodated in the shell, the isolation tube comprises an upper accommodating section, a first liquid inlet hole is formed in the upper end of the upper accommodating section, the first liquid suction tube is located in the upper accommodating section, and capillary force at the upper end of the first liquid suction tube is larger than that at the lower end of the first liquid suction tube; the second liquid suction pipe is sleeved outside the upper containing section;

the first atomization assembly is positioned in the lower end of the first liquid suction pipe, and the height of the position of the first liquid inlet hole is higher than that of the position of the first atomization assembly; the first compression assembly comprises a first compression ring and a first driver connected with the first compression ring, and the first compression ring is positioned at the bottom of the second liquid suction pipe and used for upwards extruding the second liquid suction pipe so as to enable atomized matrix in the second liquid suction pipe to flow into the first liquid suction pipe from the first liquid inlet hole; the controller is further configured to disable operation of the first atomizing assembly when a margin of atomizing substrate in the first pipette is less than a first preset value.

Further, the capillary force of the first pipette is greater than the capillary force of the second pipette;

the first atomization matrix comprises first atomization liquid and second atomization liquid, the first atomization liquid is adsorbed in the first liquid suction pipe, the second atomization liquid is adsorbed in the second liquid suction pipe, the first atomization liquid and the second atomization liquid all contain propylene glycol, glycerol and essence and spice, and the mass fraction of the glycerol in the second atomization liquid is greater than that of the glycerol in the first atomization liquid.

A control method of a shared electronic atomization system is suitable for the shared electronic atomization system, and comprises the following steps:

s1, acquiring position information and atomized substrate information transmitted by a plurality of electronic atomization devices;

s2, selecting a target electronic atomization device according to the position information and the atomization matrix information;

s3, connecting the suction nozzle sleeve with the target electronic atomization device and generating connection information;

s4, according to the connection information, sending sucking habit data of a user in the suction nozzle sleeve to the target electronic atomization device;

s5, acquiring a sucking start signal according to the sucking habit data;

S6, controlling the first atomization assembly or the second atomization assembly to work according to the sucking start signal and the sucking habit data.

The control method of the shared electronic atomization system further comprises the following steps:

s7, acquiring health information of a user;

and S71, updating the sucking habit data according to the health information.

The control method of the shared electronic atomization system further comprises the following steps:

s8, acquiring atomization matrix replacement completion information;

s81, updating information of the atomized substrate according to the atomized substrate replacement completion information;

s82, the updated atomization matrix information and the position information of the electronic atomization device containing the atomization matrix information are sent to a remote server;

and S83, the remote server updates according to the updated atomizing matrix information and the updated position information.

Further, S83 includes:

s831, comparing the updated atomizing matrix information with preset atomizing matrix information, if the updated atomizing matrix information is matched with the preset atomizing matrix information, updating according to the updated atomizing matrix information and the position information, otherwise, sending an alarm signal.

The above-mentioned control method of the shared electronic atomization system, before S6, further includes:

s51, detecting whether a suction nozzle sleeve is sleeved at the suction nozzle of the electronic atomization device or not according to a suction start signal, and controlling the first atomization component and the second atomization component to prohibit working when detecting that the suction nozzle sleeve is not sleeved at the suction nozzle

According to the scheme, the electronic atomizing device can be placed at a market, a station or a bus station, and the like, a user only needs to carry the suction nozzle sleeve with him, when he/she wants to suck outdoors, he/she can select the electronic atomizing device at the optimal place by checking the position of the surrounding electronic atomizing device and the information of the electronic atomizing device through the mobile terminal, and after the electronic atomizing device reaches the corresponding place, he/she can automatically transmit the sucking habit data of the user to the electronic atomizing device, and the electronic atomizing device directly atomizes according to the sucking habit data of the user without selecting or adjusting the user, so that the adjusting efficiency and the using efficiency are greatly improved, and the user experience is good; in addition, the suction nozzle sleeve is convenient to carry, has no leakage risk, is relatively sanitary, and avoids the problems that the portable electronic atomization device is inconvenient to carry, and atomized matrixes are easy to leak so as to be stained with clothes when the portable electronic atomization device is worn.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments or the description of the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic block diagram of a shared electronic atomizing system according to the present disclosure;

FIG. 2 is a schematic diagram of an electronic atomizing device in a first state of the present disclosure;

FIG. 3 is a schematic diagram of an electronic atomizing device in a second state of the present disclosure;

fig. 4 is an enlarged view of area a shown in fig. 2;

fig. 5 is an enlarged view of region B shown in fig. 3;

FIG. 6 is a perspective view of the seal cap of FIG. 2 from a perspective;

FIG. 7 is a perspective view of the seal cap of FIG. 2 from another perspective;

FIG. 8 is a functional block diagram of a nozzle sleeve of the shared electronic atomizing system of the present disclosure;

FIG. 9 is a flow chart of a control method of the present invention for sharing an electronic atomizing system.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

It will be understood that when an element is referred to as being "mounted" or "disposed" or "connected" to another element, it can be directly or indirectly on the other element. The directions or positions indicated by the terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are directions or positions based on the drawings, and are merely for convenience of description and are not to be construed as limiting the present technical solution. The terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "multiple" is two or more, unless explicitly defined otherwise. The meaning of "a number" is one or more than one, unless specifically defined otherwise.

Referring to fig. 1 to 9, the present invention discloses a shared electronic atomization system, which includes an electronic atomization device 100, a nozzle cover 200, a remote server 300 and a mobile terminal 400, wherein the electronic atomization device 100 is used for being placed at a public place to atomize an atomized substrate, wherein the public place can be a mall, a station or a bus stop. The electronic atomization device 100 comprises a shell 10, a first atomization component 11, a second atomization component 12, a first compression component 13, a second compression component 14, an airflow sensor 15, a positioning module 16, a controller 17 and a first wireless communication module 18 which are positioned in the shell 10, wherein a first cavity 101 is arranged in the shell 10, an atomization substrate is accommodated in the first cavity 101, and the atomization substrate comprises a first atomization substrate and a second atomization substrate. It will be appreciated that the atomizing substrate may comprise a plurality of atomizing substrates, the number of which is not particularly limited herein.

In this embodiment, the housing 10 includes a first sleeve 103, a second sleeve 104, and a third sleeve 105, the second sleeve 104 is detachably disposed in the first sleeve 103, a first cavity 101 is formed in the second sleeve 104, and a second cavity 102 is formed between the first sleeve 103 and the second sleeve 104. The first sleeve 103 is located within the third sleeve 105, and a tubular insulating gap is formed between the third sleeve 105 and the first sleeve 103, so that in use, overheating of the outside of the third sleeve 105 is avoided. One end of the third sleeve 105 is connected to a bottom cap 106, and the bottom cap 106 is provided with an air inlet hole 1061 communicating with the second atomizing assembly 12. One end of the casing 10 is connected with a suction nozzle 107, the suction nozzle 107 is connected with the first sleeve 103, the second sleeve 104 and the third sleeve 105, and the bottom cover 106 and the suction nozzle 107 are respectively positioned at two opposite ends of the third sleeve 105. The suction nozzle 107 is provided with a mist outlet 1071, and the mist outlet 1071 communicates with the first atomizing assembly 11 and the second atomizing assembly 12.

The first chamber 101 accommodates therein a spacer tube 191, a first liquid suction tube 192, a second liquid suction tube 193, a third liquid suction tube 194, and a fourth liquid suction tube 195, the spacer tube 191 includes an upper accommodation section and a lower accommodation section, and the first liquid suction tube 192 is located in the upper accommodation section and communicates with the mist outlet 1071. The isolation tube 191 is used for preventing external force from being conducted into the first liquid suction tube 192, so that the first liquid suction tube 192 is prevented from being deformed due to the external force, and liquid supply is unstable. In addition, if the external force is conducted to the first atomizing assembly 11 through the first pipette 192, the first atomizing assembly 11 may be deformed so as to affect the resistance value of the first atomizing assembly 11, thereby affecting the stability of the aerosol output. That is, the isolation tube 191 protects the first and second atomizing assemblies 11 and 12 from external force, thereby ensuring the stability of the resistance thereof and the stability of the aerosol output.

The second liquid suction pipe 193 is located in the first cavity 101 and is sleeved outside the upper storage section, so that when the atomized liquid in the first liquid suction pipe 192 is insufficient, the atomized liquid is supplemented to the first liquid suction pipe 192. The first pipette 192 and the second pipette 193 are used to adsorb the first atomized substrate. The upper end of the upper storage section is provided with a first liquid inlet 1911. Preferably, in order to avoid spraying the atomized liquid in the second liquid suction pipe 193 into the first liquid suction pipe 192 when the liquid is discharged, the cross-sectional area of the liquid inlet of the first liquid inlet hole 1911 is smaller than the cross-sectional area of the liquid outlet of the first liquid inlet hole 1911. More preferably, the centerline of first feed hole 1911 forms an angle greater than 45 ° with the cross section of spacer tube 191. Thus, the impact force of the atomized liquid flowing in is applied to the first liquid suction pipe 192 when the liquid is discharged is well reduced.

It is understood that the isolation tube 191 may be made of a plastic tube or a metal tube or the like. In the present embodiment, the isolation tube 191 is a stainless steel tube, and the first to fourth pipettes 192 to 195 are all cotton tubes. It will be appreciated that in other embodiments, the first through fourth pipettes 192 through 195 may be made of other porous materials, the materials of which are not specifically limited herein.

The porosity of the upper end of the first liquid suction pipe 192 is smaller than the porosity of the lower end of the first liquid suction pipe 192, and the capillary force of the upper end of the first liquid suction pipe 192 is larger than the capillary force of the lower end of the first liquid suction pipe 192, so that when the atomized matrixes in the first liquid suction pipe 192 are fewer, even under the influence of gravity, the atomized matrixes are respectively uniform or little in difference in the whole up-down direction, so that the liquid supply of the first atomization assembly 11 is uniform and stable up-down, the stable output of the aerosol is realized, and the problem that the user easily cough when sucking the aerosol is avoided. Preferably, the porosity of the first pipette 192 gradually increases from top to bottom, and the capillary force of the first pipette 192 gradually decreases from top to bottom.

In a preferred embodiment of the present invention, the first pipette 192 has a porosity smaller than that of the second pipette 193, and the capillary force of the first pipette 192 is greater than that of the second pipette 193. Thus, not only the liquid storage amount in the region of the second liquid suction pipe 193 can be increased, but also the stability of the supply of the atomized substrate can be ensured. The third liquid suction pipe 194 is located in the lower containing section, a first liquid separation ring 196 is arranged between the first liquid suction pipe 192 and the third liquid suction pipe 194, the first liquid separation ring 196 is used for preventing atomized matrix at the first liquid suction pipe 192 from flowing towards the third liquid suction pipe 194, and the problem that atomized liquid in the first liquid suction pipe 192 flows into the third liquid suction pipe 194 due to the action of gravity so that the supply of the atomized liquid in the first liquid suction pipe 192 is insufficient is avoided. Preferably, the capillary force of the third pipette 194 is greater than the capillary force of the first pipette 192, and the third pipette 194 is disposed coaxially with the first pipette 192. Therefore, the atomized matrix can be well latched, and leakage of the atomized matrix is avoided.

The first atomization assembly 11 is located inside the lower end of the first liquid suction pipe 192, and the height of the position of the first liquid inlet 1911 is higher than that of the position of the first atomization assembly 11. Because the height of the position of the first liquid inlet hole 1911 is higher than the height of the position of the first atomization assembly 11, when the supply of the atomized liquid in the first liquid suction pipe 192 is insufficient, the atomized liquid in the second liquid suction pipe 193 flows into the upper end of the first liquid suction pipe 192 from the first liquid inlet hole 1911 through the first compression assembly 13, so that the atomized substrate conveyed from the upper end of the second liquid suction pipe 193 can be supplied in time and slowly flows to the direction of the first atomization assembly 11 under the action of gravity, and the uniform or small difference of the amount of the atomized liquid at the upper end and the lower end of the first liquid suction pipe 192 is well ensured.

In this embodiment, the first atomizing assembly 11 includes a first liquid absorbing cotton column 111 and a first heat generating member 112, and the first liquid absorbing cotton column 111 is located in the first liquid absorbing pipe 192 and contacts with the first liquid absorbing pipe 192. The first heating element 112 is located in the first liquid-absorbing cotton column 111 and is in contact with the first liquid-absorbing cotton column 111, and is used for atomizing an atomized matrix in the first liquid-absorbing cotton column 111. The first heat generating member 112 may be a heat generating wire wound in a tubular shape, a heat generating sheet wound in a tubular shape, or the like, and the structure thereof is not particularly limited herein. More specifically, in the present embodiment, the first heating element 112 is a heating wire wound in a tubular shape, and the heating wire is coaxially disposed with the first liquid suction cotton column 111 and the first liquid suction pipe 192.

The second atomizing assembly 12 is located in the third liquid suction pipe 194, the second atomizing assembly 12 comprises a second liquid suction cotton column 121 and a second heating element 122, and the second liquid suction cotton column 121 is located in the third liquid suction pipe 194 and is in contact with the third liquid suction pipe 194. The second heating element 122 is located in the second liquid-absorbing cotton column 121 and is in contact with the second liquid-absorbing cotton column 121, and is used for atomizing the atomized matrix in the second liquid-absorbing cotton column 121. The second heat generating member 122 may be a heat generating wire wound in a tubular shape, a heat generating sheet wound in a tubular shape, or the like, and the structure thereof is not particularly limited herein. More specifically, in the present embodiment, the second heating element 122 is a heating wire wound into a tubular shape, and the heating wire is coaxially disposed with the second liquid absorbing cotton column 121 and the third liquid absorbing pipe 194. The fourth pipette 195 is disposed on the outer peripheral surface of the lower receiving section, and a second liquid inlet 1912 is disposed at the upper end of the lower receiving section, and the second liquid inlet 1912 is used for introducing the atomized matrix at the fourth pipette 195 into the third pipette 194.

In a preferred embodiment of the present invention, the first atomized substrate includes a first atomized liquid and a second atomized liquid, the first atomized liquid is absorbed in the first liquid absorbing pipe 192, the second atomized liquid is absorbed in the second liquid absorbing pipe 193, and the first atomized liquid and the second atomized liquid each contain propylene glycol, glycerol and essence, wherein the mass fraction of glycerol in the second atomized liquid is greater than that of glycerol in the first atomized liquid, so that the stability of the aerosol discharge amount can be better ensured. Preferably, the saturation of the first atomized liquid in the first pipette 192 is less than the saturation of the second atomized liquid in the second pipette 193, so that oversaturation of the first absorbent cotton column 111 can be avoided, so that the aerosol particle size is greatly different from front to back, thereby causing a problem of user discomfort.

It will be appreciated that propylene glycol acts as a solvent to dissolve the flavour and fragrance to provide the user with the desired taste and that glycerol is used to produce a nebulised aerosol in a ratio which substantially determines the size of the aerosol quantity. Because the atomized liquid is discharged from the first liquid inlet hole 1911, part of the glycerin can be contacted with the high-temperature aerosol in the process of being conveyed to the first atomization assembly 11 from the upper end of the first liquid suction pipe 192, so that the aerosol is formed by vaporization, and the lost glycerin can be supplemented through the arrangement, so that the discharge amount of the aerosol is relatively stable after a period of use and when the use is started. In this embodiment, the third and fourth pipettes 194 and 195 are adsorbed with a second atomized matrix containing propylene glycol, glycerin, and nicotine, and no perfume or flavor.

In a preferred embodiment of the present invention, the electronic atomizing device 100 further comprises a second liquid-separating ring 197, the second liquid-separating ring 197 being located between the second liquid-sucking pipe 193 and the fourth liquid-sucking pipe 195 for blocking the atomized liquid at the second liquid-sucking pipe 193 from flowing into the fourth liquid-sucking pipe 195. Preferably, the second liquid-proof ring 197 and the liquid-proof pipe are integrally formed.

The first compression assembly 13 comprises a first compression ring 131 and a first driver 132 connected with the first compression ring 131, wherein the first compression ring 131 is positioned at the bottom of the second liquid suction pipe 193 and is used for upwards extruding the second liquid suction pipe 193 so that atomized liquid in the second liquid suction pipe 193 flows into the first liquid suction pipe 192 from the first liquid inlet 1911, atomized matrix is timely supplemented to the first liquid suction pipe 192, and the stability of the discharge amount of aerosol is ensured. The first driver 132 includes a second motor 1321 and a first screw rod 1322, the second motor 1321 is fixed at the second housing 10, a first end of the first screw rod 1322 is connected to the second motor 1321, a second end of the first screw rod 1322 is in threaded connection with the first pressure ring 131, and when the first screw rod 1322 rotates, the first pressure ring 131 can be driven to move up and down.

The second compression assembly 14 comprises a second compression ring 141 and a second driver 142 connected with the second compression ring 141, wherein the second compression ring 141 is positioned at the bottom of the fourth liquid suction pipe 195 and is used for upwards extruding the fourth liquid suction pipe 195 so that atomized liquid in the fourth liquid suction pipe 195 flows into the third liquid suction pipe 194 from the second liquid inlet 1912, and atomized matrix is timely supplemented to the third liquid suction pipe 194, so that the stability of the discharge amount of the aerosol is ensured. The second driver 142 includes a third motor 1421 and a second screw 1422, and the third motor 1421 is fixed to the second housing 10. The second screw 1422 is connected to the third motor 1421 and is in threaded connection with the second pressure ring 141, and when the second screw 1422 rotates, the second pressure ring 141 can be driven to move upwards, so as to squeeze the atomized liquid at the fourth liquid suction pipe 195, and convey the atomized liquid from the second liquid inlet 1912 into the third liquid suction pipe 194.

In one embodiment of the present invention, the electronic atomizing device 100 further includes a capacitor 5 electrically connected to the controller 17, the capacitor 5 being located within the first pipette 192 for detecting the amount of atomized liquid remaining within the first pipette 192. The capacitor 5 includes a first electrode plate 51 and a second electrode plate 52, the first electrode plate 51 and the second electrode plate 52 are disposed opposite to each other and are located in the first liquid suction pipe 192, the first electrode plate 51 and the second electrode plate 52 are electrically connected to the controller 17, and the controller 17 calculates the remaining amount of the atomized liquid in the first liquid suction pipe 192 according to the capacitance of the capacitor 5. Preferably, the height of the capacitor 5 is higher than the height of the first atomization component 11, so that interference of the first atomization component 11 can be avoided, and the detection accuracy is improved.

In one embodiment of the invention, the suction nozzle 107 houses a seal cap 6, the seal cap 6 being sealingly connected to the housing 10. The seal top cover 6 is provided with a mounting groove 61, an air outlet groove 62, a jack 63, a connection groove 64, and a fixing groove 65, and the mounting groove 61 is used for mounting the air flow sensor 15 and communicates with the air outlet groove 62. The air outlet groove 62 is used for communicating with the mist outlet 1071. Specifically, the air outlet grooves 62 are provided extending in the lateral direction of the electronic atomizing device 100. The insertion hole 63 communicates with the air outlet groove 62, and the insertion hole 63 is provided to extend in the longitudinal direction of the electronic atomizing device 100. The connecting groove 64 is located between the air outlet groove 62 and the fixing groove 65, a first end of the connecting groove 64 is communicated with the air outlet groove 62 and the insertion hole 63, and a second end of the connecting groove 64 is communicated with the fixing groove 65. The gas outlet groove 62 communicates with the mist outlet 1071 through the connecting groove 64.

The air flow sensor 15 is installed in the installation groove 61 at the seal top cover 6 and communicates with the air outlet groove 62 to communicate to the mist outlet hole 1071 through the air outlet groove 62. The height of the bottom wall of the air outlet groove 62 is higher than the height of the bottom wall of the connection groove 64, and therefore, condensate does not easily flow into the air outlet groove 62 so as to flow into the air flow sensor 15. The seal cap 6 is also provided with an air inlet channel 66 in communication with the air flow sensor 15, the air inlet channel 66 being located below the air flow sensor 15.

The positioning module 16 is electrically connected to the controller 17 for providing positional information of the electronic atomizing device 100. The positioning module 16 may be a GPS positioning module or a beidou positioning module, etc. The first wireless communication module 18 is configured to communicate with the remote server 300 and the nozzle holder 200, so as to send the position information of the electronic atomizing device 100, the information of the atomized substrate, etc. to the remote server 300, and obtain the sucking habit data from the nozzle holder 200. It is to be understood that the first wireless communication module 18 may be a bluetooth module, a WiFi module, or the like, as long as wireless communication can be achieved, and the structure thereof is not particularly limited herein.

In an embodiment of the present invention, the electronic atomizing device 100 further includes a third liquid-absorbing cotton column 71, an elastic reset member 72 and a gas path blocking component 8, the third liquid-absorbing cotton column 71 is cylindrical, a first end of the third liquid-absorbing cotton column 71 is inserted into the fixing groove 65, and a second end of the third liquid-absorbing cotton column 71 is abutted with an orifice of the mist outlet 1071, so that condensate flowing down from the mist outlet 1071 can be well absorbed, and the condensate is prevented from flowing around.

The elastic resetting piece 72 is located in the shell 10 and elastically abuts against the air passage blocking assembly 8. In the first state, the nozzle cover 200 is spaced from the electronic atomizing device 100 and is used for being placed at a user, at this time, the nozzle cover 200 is separated from the nozzle 107, the air channel blocking component 8 closes the air outlet groove 62, that is, when the present invention is not used, the nozzle cover 200 is separated from the nozzle 107, the nozzle cover 200 is placed in a pocket of the user, and under the elastic force of the elastic reset piece 72, the air channel blocking component 8 automatically closes the air outlet groove 62, so that the condensate is blocked from flowing towards the air flow sensor 15. In the second state, the nozzle sleeve 200 is sleeved at the nozzle 107, the nozzle sleeve 200 is connected with the electronic atomization device 100, and the nozzle sleeve 200 drives the air passage blocking component 8 to open the air outlet groove 62 by the air passage blocking component 8, so that the electronic atomization device 100 can atomize the atomized substrate, and a user can use the electronic atomization device normally.

In a preferred embodiment of the present invention, the air path blocking assembly 8 includes a blocking member 81 and a first magnetic member 82 connected to the blocking member 81, wherein the blocking member 81 is connected to the elastic restoring member 72 and movably connected to the sealing top cover 6, and specifically, the blocking member 81 penetrates through the insertion hole 63 and extends into the connection groove 64. The nozzle sleeve 200 comprises a sleeve body 21 and a second magnetic piece 22 connected with the sleeve body 21, wherein the sleeve body 21 is used for being detachably connected with the electronic atomization device 100, and the sleeve body 21 is provided with an air outlet 201 which is used for being communicated with the first atomization component 11 and the second atomization component 12. In the first state, the elastic restoring member 72 drives the blocking member 81 to close the air outlet groove 62. In the second state, the second magnetic member 22 magnetically repels the first magnetic member 82, so that the air passage blocking assembly 8 opens the air outlet groove 62, and the air outlet groove 62 can communicate with the mist outlet hole 1071 through the connection groove 64. It is to be understood that the elastic restoring member 72 may be a spring or a leaf spring, and the structure thereof is not particularly limited herein. In the present embodiment, the first magnetic member 82 and the second magnetic member 22 are both magnets.

As shown in fig. 8, the nozzle sleeve 200 further includes a first battery 23, a memory 24, a microprocessor 25 and a second wireless communication module 26, which are located in the sleeve body 21, and the first battery 23 is used for supplying power to the electric devices in the sleeve body 21. The memory 24 is electrically connected to the microprocessor 25 for storing the sucking habit data of the user. The microprocessor 25 is electrically connected to the second wireless communication module 26 for transmitting the eating habit data to the first wireless communication module 18 via the second wireless communication module 26. It is to be understood that the second wireless communication module 26 may be a bluetooth module, a WiFi module, or the like, as long as wireless communication can be achieved, and the structure thereof is not particularly limited herein. The microprocessor 25 may be a single-chip microcomputer or the like.

After the user has sucked, the first wireless communication module 18 sends the user sucking habit data to the second wireless communication module 26, the second wireless communication module 26 sends the user sucking habit data to the microprocessor 25, and then the microprocessor 25 writes the user sucking habit data into the memory 24. When a user needs to smoke, after the suction nozzle sleeve 200 is sleeved on the suction nozzle 107, the microprocessor 25 reads the user sucking habit data from the memory 24 and sends the user sucking habit data to the first wireless communication module 18 through the second wireless communication module 26, and then the electronic atomization device 100 atomizes the atomized substrate in the electronic atomization device 100 according to the user sucking habit data. In addition, the first wireless communication module 18 is further configured to provide information of the electronic atomizing device to the remote server 300, where the information includes location information, atomizing substrate information, and the like. It will be appreciated that the first wireless communication module 18 communicates with the remote server 300 via a communication network.

As shown in fig. 5, in a preferred embodiment of the present invention, the nozzle housing 200 further includes a third magnetic member 27, a check valve 28, and a plurality of protective films 29 detachably coated on the housing 21, wherein the third magnetic member 27 is fixed in the housing 21. A one-way valve 28 is mounted in the air outlet aperture 201 for preventing liquid from flowing from the air outlet aperture 201 into the electronic atomizing device 100. Therefore, the user can be prevented from blowing into the electronic atomizing device 100, so that the air flow sensor 15 is triggered by mistake, the suction habit data of the user is prevented from being interfered, and the accuracy of the suction habit data is improved. The protective film 29 can be torn off every time the user has sucked once, so that it can be kept clean and hygienic.

As shown in fig. 4, in a preferred embodiment of the present invention, the electronic atomizing device 100 further includes a push air plug 91, and the push air plug 91 is connected to the blocking member 81; in the first state, the plug 91 is at least partially inserted into the air intake slot 66, and in the second state, the plug 91 is spaced from the notch of the air intake slot 66. That is, when the user has sucked and removed the mouthpiece 200, the elastic restoring member 72 drives the blocking member 81 to move toward the mouthpiece 107, and the blocking member 81 drives the push plug 91 to be inserted into the air inlet slot 66. Therefore, when the user finishes sucking and then takes out the suction nozzle sleeve 200, the air flow in the air outlet groove 62 continues to flow towards the direction of the mist outlet 1071 by the driving of the air plug 91, so that the residual aerosol in the suction nozzle 107 is prevented from flowing into the air flow sensor 15, the service life of the air flow sensor 15 is prolonged, and in addition, when the blocking piece 81 moves to a preset position, the blocking piece is separated from the air flow sensor 15 and the mist outlet 1071.

In a preferred embodiment of the present invention, as shown in fig. 4, the electronic atomizing device 100 further comprises an elastic sealing piece 92, wherein the elastic sealing piece 92 is located on the side of the sealing top cover 6 facing away from the second cavity 102 and covers the notch of the air outlet groove 62 to seal the notch on the side facing away from the second cavity 102. Therefore, when the user sucks, the air flow in the area of the mounting groove 61 can quickly flow to the mist outlet 1071, so that the air flow sensor 15 can be triggered quickly, the sensitivity of the air flow sensor 15 can be improved, and the user experience is improved. In addition, the structure is convenient to manufacture, reduces the manufacturing process and improves the production efficiency. It will be appreciated that in the first state, the air path blocking assembly 8 abuts the resilient sealing sheet 92. It will be appreciated that in one embodiment, the resilient sealing tab 92 may not be provided, and the slot opening of the air outlet slot 62 facing away from the second chamber 102 may be resiliently abutted by the suction nozzle 107. In the first state, the air path blocking assembly 8 abuts against the suction nozzle 107.

As shown in fig. 5, in a preferred embodiment of the present invention, the electronic atomizing device 100 further includes a hall sensor 93 and a second battery 94, and the third magnetic member 27 is configured to cooperate with the hall sensor 93. A hall sensor 93 is mounted in the seal cap 6 and electrically connected to the controller 17 for detecting whether the nozzle housing 200 is capped at the nozzle 107. The second battery 94 is used to provide electrical power to power the electrical devices of the first atomizing assembly 11, the second atomizing assembly 12, and the like.

The controller 17 is electrically connected to the airflow sensor 15 and the second battery 94, and is configured to control the first atomization component 11 and the second atomization component 12 to operate, and prohibit the first atomization component 11 from operating when the amount of atomized liquid in the first pipette 192 is less than a first preset value. That is, when the remaining amount of the atomized liquid in the first pipette 192 is smaller than the first preset value, the first atomizing assembly 11 is permanently turned off to operate, and the discharge amount of the aerosol is kept stable during inhalation, thereby avoiding the problem that the discharge amount of the aerosol is inadvertently reduced during inhalation, so that the user easily coughs during inhalation. The controller 17 may comprise a single chip microcomputer or a programmable logic array or the like.

The remote server 300 has information of several electronic atomizing devices 100 for transmitting the information of the electronic atomizing devices 100 to the mobile terminal 400. The mobile terminal 400 includes smart mobile terminal devices such as a mobile phone, a tablet computer, a smart watch, and the like. The information of the electronic atomizing device 100 includes information such as location information of the electronic atomizing device 100 and taste of the atomized substrate, and the information may be obtained by the remote server 300 performing information interaction with the electronic atomizing device 100, or may be written into the remote server 300 by a manufacturer or an operator.

The mobile terminal 400 is used for presenting the information sent by the remote server 300 to the user and performing information interaction with the nozzle sleeve 200. Specifically, an application program (APP) is installed in the mobile terminal 400 of the user, and the APP interacts with the remote server 300, so that when the user clicks the APP in the mobile terminal 400, the user can see information such as location information of the electronic atomizing device 100 around the user and taste of the atomized substrate. It will be appreciated that the mobile terminal 400 is a portable mobile phone commonly used in the market, i.e. an intelligent mobile terminal. When the user uses the suction nozzle sleeve 200 for the first time, the mobile terminal sets the favorite atomization matrix and atomization power to be used as the sucking habit data of the user, and then the mobile terminal 400 transmits the sucking habit data of the user to the suction nozzle sleeve 200, so that the suction nozzle sleeve 200 can obtain the initial sucking habit data of the user. Of course, the user can set his own preference at any time through the mobile terminal 400.

Referring to fig. 9, the invention also discloses a control method of the shared electronic atomization system, which is applicable to the shared electronic atomization system and comprises the following steps:

s1, acquiring position information and atomized substrate information transmitted by a plurality of electronic atomization devices 100;

When the user wants to suck, the user clicks the application program on the mobile terminal 400, and the application program displays the information such as the position information of the plurality of electronic atomizing devices 100 around the user and the taste of the atomized substrate on the mobile terminal 400.

S2, selecting a target electronic atomization device 100 according to the position information and the atomization matrix information;

the favorite electronic atomizing device 100 is selected on the mobile terminal 400 as the target electronic atomizing device 100 according to the favorite, and the position information provided by the target electronic atomizing device 100 is used as the navigation information of the user.

S3, connecting the suction nozzle sleeve 200 with the target electronic atomization device 100 and generating connection information;

after the user arrives at the position of the target electronic atomization device 100 according to the navigation information, the self-carried suction nozzle sleeve 200 is connected with the target electronic atomization device 100.

S4, according to the connection information, sending sucking habit data of the user in the suction nozzle sleeve 200 to the target electronic atomization device 100;

after the nozzle sleeve 200 is in communication connection with the first wireless communication module 18 of the target electronic atomization device 100 through the second wireless communication module 26, the microprocessor 25 sends the sucking habit data to the first wireless communication module 18 through the second wireless communication module 26, so that the controller 17 of the target electronic atomization device 100 obtains the sucking habit data of the user from the first wireless communication module 18. In this embodiment, the second wireless communication module 26 and the first wireless communication module 18 are both bluetooth modules, and the connection information is handshake information between the bluetooth modules.

S5, acquiring a sucking start signal according to sucking habit data;

after the controller 17 acquires the intake habit data, the air flow sensor 15 is monitored in real time to acquire an intake start signal.

And S6, controlling the first atomization component 11 or the second atomization component 12 to work according to the sucking start signal and the sucking habit data.

When the user sucks, the airflow sensor 15 is triggered, the airflow sensor 15 sends a sucking start signal to the controller 17, and the controller 17 controls the first atomization component 11 or the second atomization component 12 to work according to the sucking start signal and sucking habit data.

For example, if the flavor of the essence and fragrance in the first pipette 192 is peppermint, the user likes peppermint and the user likes 9 watts of atomization power, the controller 17 directly controls the first atomization component 11 to perform atomization at 9 watts of atomization power without waiting adjustment when the user inhales. If the user likes nicotine and likes 10 watts of atomization power, the controller 17 directly controls the second atomization component 11 to atomize at 10 watts of atomization power without waiting adjustment when the user inhales. Therefore, the device is convenient for users to use, and the adjustment efficiency and the use efficiency are improved.

In a preferred embodiment of the present invention, the control method further includes:

S7, acquiring health information of a user;

and S71, updating the sucking habit data according to the health information.

After the user binds the mobile terminal 400 and the suction nozzle sleeve 200, the physical examination report of the user is shot through the application program on the mobile terminal 400, and the health information of the user is obtained, the mobile terminal 400 modifies the sucking habit data according to the health information, and sends the sucking habit data into the suction nozzle sleeve 200 to update the sucking habit data, so that the health of the user is facilitated. For example, according to the health information of the user, the user needs to reduce the inhalation amount of the mint-flavored aerosol, and at this time, when the user inhales, the controller 17 controls the first atomization component 11 to perform atomization with the atomization power of less than 9 watts. It may be 6 watts or 5 watts, etc. S7 may be performed at any time, S7 may be performed before, after, or simultaneously with any of steps S1-S6, i.e. S7 is relatively independent of the other steps.

In a preferred embodiment of the present invention, the control method further includes:

s8, acquiring atomization matrix replacement completion information;

s81, updating information of the atomized substrate according to the atomized substrate replacement completion information;

s82, the updated atomizing substrate information and the position information of the electronic atomizing device 100 containing the atomizing substrate information are sent to a remote server 300;

And S83, the remote server 300 updates according to the updated atomizing matrix information and the position information.

The two-dimensional code is arranged on the liquid storage bottle filled with the atomized matrix, and after a user adds the atomized matrix in the liquid storage bottle into the electronic atomization device 100, the two-dimensional code is shot by an application program on the mobile terminal 400, so that atomized matrix replacement completion information and new atomized matrix information are obtained and updated. The mobile terminal 400 transmits the updated nebulized matrix information and the location information of the electronic nebulizing device 100 containing the nebulized matrix information to the remote server 300. Therefore, when other users query the information of the electronic atomizing apparatus 100 through the mobile terminal 400, updated information can be obtained. S8 may be performed at any time, S8 may be performed before, after, or simultaneously with any of steps S1-S7, i.e. S8 is relatively independent of the other steps.

In a preferred embodiment of the present invention, the "updating by remote server 300 according to the updated atomizing base information and the updated position information" includes:

s831, comparing the updated atomizing matrix information with preset atomizing matrix information, if the updated atomizing matrix information is matched with the preset atomizing matrix information, updating according to the updated atomizing matrix information and the position information, otherwise, sending an alarm signal.

When the updated atomized matrix information is not matched with the preset atomized matrix information, the new atomized matrix may harm health, the remote server 300 sends alarm information to the user mobile terminal 400, and the user mobile terminal 400 sends an alarm signal, so that a user is reminded, and the use safety of the user is improved.

In a preferred embodiment of the present invention, before S6, the method further comprises:

s51, detecting whether the suction nozzle sleeve 200 is sleeved at the suction nozzle 107 of the electronic atomization device 100 according to the suction start signal, controlling the first atomization component 11 and the second atomization component 12 to prohibit operation when detecting that the suction nozzle sleeve 200 is not sleeved at the suction nozzle 107, and sending information of prohibiting operation to the remote server 300.

In normal cases, the controller 17 controls the first atomizing assembly 11 or the second atomizing assembly 12 to operate only when receiving the suction start signal transmitted from the air flow sensor 15 after the nozzle cover 200 is fitted to the nozzle 107 of the electronic atomizing apparatus 100. If the suction nozzle sleeve 200 is not sleeved at the suction nozzle 107 of the electronic atomizing device 100, and the suction start signal sent by the airflow sensor 15 is received, the violent suction is indicated, so that the first atomizing assembly 11 and the second atomizing assembly 12 are controlled to be forbidden to work, and the use safety of a user is improved. The operator can perform maintenance and security management according to the information provided by the remote server 300.

In a preferred embodiment of the present invention, before step S6, the method further includes:

s52, when the margin of the atomized matrix in the first pipette 192 is greater than the first preset value and less than the second preset value, the first driver 132 is controlled to drive the first pressing ring 131 to move upwards so as to squeeze the second pipette 193.

When the margin of the atomized matrix in the first liquid suction pipe 192 is greater than the first preset value and less than the second preset value, the margin is not too large, so that long-term liquid supply can not be performed, and the atomized matrix needs to be supplemented in time, at this time, the controller 17 controls the first driver 132 to drive the first pressure ring 131 to move upwards for a preset distance so as to squeeze the second liquid suction pipe 193, and thus the atomized matrix in the second liquid suction pipe 193 flows into the first liquid suction pipe 192. It is understood that the first preset value and the second preset value may be set according to the type of the atomized liquid, which is not particularly limited herein.

In a preferred embodiment of the present invention, step S6 further includes:

s61, when the allowance of the atomized matrix in the first liquid suction pipe 192 is not more than a first preset value, prohibiting the first atomization component 11 from working; alternatively, the second atomizing assembly 12 is disabled when the margin of the atomized substrate within the second pipette 193 is not greater than the first preset value.

When the remaining amount of the aerosol base material in the first or second pipettes 192 or 193 is insufficient, the corresponding atomizing assembly is disabled, thus maintaining the stability of the aerosol discharge amount.

In a preferred embodiment of the present invention, the control method further comprises the steps of:

and counting the sucking times of the user, and sending out a condensate leakage alarm signal when the sucking times are greater than the preset times and the accumulated amount of condensate at the third liquid suction cotton column 71 is smaller than a third preset value.

Because of the sucking, there is certainly the occurrence of condensation, and as the number of sucking times increases, the condensate is necessarily increased. If the preset number of times is the number of times, if the accumulated amount of the condensate after the suction is smaller than the third preset value, the third liquid-absorbing cotton column 71 is not assembled in place, and the condensate in the third liquid-absorbing cotton column 71 leaks to other areas, the controller 17 sends out a condensate leakage alarm signal, so that the health of a user is well protected, and the problem of judging whether to condense the condensate because the third liquid-absorbing cotton column 71 is not assembled in place is solved. In one embodiment, the amount of condensate at the third liquid absorbent column 71 may be detected by a humidity sensor connected to the controller 17, or the amount of condensate at the third liquid absorbent column 71 may be checked by an additional capacitor. It will be appreciated that the controller 17 may comprise a single-chip microcomputer and a loudspeaker electrically connected to the single-chip microcomputer, the loudspeaker being adapted to emit a condensate leakage alarm signal.

In summary, the electronic atomizing device 100 of the present invention can be placed at a market, a station, a bus stop, etc., and a user only needs to carry the nozzle sleeve 200 with him, when he/she wants to suck outdoors, he/she views the position of the surrounding electronic atomizing device 100 and the information of the electronic atomizing device 100 through the mobile terminal 400, and then can select the electronic atomizing device 100 in the optimal place, and after reaching the corresponding place, the nozzle sleeve 200 is sleeved on the electronic atomizing device 100, so that the sucking habit data of the user can be transmitted to the electronic atomizing device 100, and the electronic atomizing device 100 can perform atomization directly according to the sucking habit data of the user without selecting or adjusting again by the user, thereby greatly improving the adjustment efficiency and the use efficiency, and having good user experience; in addition, the nozzle sleeve 200 is relatively convenient to carry, has no risk of liquid leakage, is relatively sanitary, and avoids the problems that the nozzle sleeve is inconvenient to carry and atomized substrates are easy to leak so as to be stained with clothes when the various electronic atomization devices 100 are carried on the body.

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

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

Claims (10)

1. The shared electronic atomization system is characterized by comprising an electronic atomization device, a suction nozzle sleeve, a remote server and a mobile terminal, wherein the electronic atomization device comprises an atomization substrate, a first atomization component, a second atomization component, a positioning module, a controller and a first wireless communication module, and the atomization substrate comprises a first atomization substrate and a second atomization substrate; the first atomization assembly is used for atomizing the first atomization substrate, and the second atomization assembly is used for atomizing the second atomization substrate; the positioning module is used for providing position information; the controller is used for controlling the first atomization assembly and the second atomization assembly to work; the first wireless communication module is used for communicating with the remote server and the suction nozzle sleeve; the electronic atomization device is used for being placed at a public place to atomize the atomized substrate;

The suction nozzle sleeve comprises a sleeve body, a memory, a microprocessor and a second wireless communication module, wherein the sleeve body is used for being detachably connected with the electronic atomization device; the memory is used for storing sucking habit data of a user; the microprocessor is used for sending the sucking habit data to the first wireless communication module through the second wireless communication module; in a first state, the suction nozzle sleeve is spaced from the electronic atomization device and is used for being placed at a user; in a second state, the suction nozzle sleeve is connected with the electronic atomization device so that the electronic atomization device can atomize the atomized substrate; the remote server is used for sending the information of the electronic atomization device to the mobile terminal; the mobile terminal is used for presenting the information sent by the remote server to a user and carrying out information interaction with the suction nozzle sleeve.

2. The shared electronic atomizing system of claim 1, wherein the nozzle housing further comprises a one-way valve, and wherein the housing is provided with an air outlet for communicating with the first atomizing assembly and the second atomizing assembly, and wherein the one-way valve is mounted in the air outlet for preventing liquid from flowing from the air outlet into the electronic atomizing device.

3. A shared electronic atomizing system as set forth in claim 1 or 2, wherein said nozzle housing further comprises a plurality of protective films removably wrapped around said housing.

4. The shared electronic atomizing system according to claim 1 or 2, wherein the electronic atomizing device further comprises a housing, a first compression assembly and an air flow sensor, wherein a separation tube, a first liquid suction tube and a second liquid suction tube are accommodated in the housing, the separation tube comprises an upper accommodating section, a first liquid inlet is arranged at the upper end of the upper accommodating section, the first liquid suction tube is positioned in the upper accommodating section, and the capillary force of the upper end of the first liquid suction tube is larger than the capillary force of the lower end of the first liquid suction tube; the second liquid suction pipe is sleeved outside the upper containing section;

the first atomization assembly is positioned in the lower end of the first liquid suction pipe, and the height of the position of the first liquid inlet hole is higher than that of the position of the first atomization assembly; the first compression assembly comprises a first compression ring and a first driver connected with the first compression ring, and the first compression ring is positioned at the bottom of the second liquid suction pipe and used for upwards extruding the second liquid suction pipe so as to enable atomized matrix in the second liquid suction pipe to flow into the first liquid suction pipe from the first liquid inlet hole; the controller is further configured to disable operation of the first atomizing assembly when a margin of atomizing substrate in the first pipette is less than a first preset value.

5. A shared electronic atomizing system as set forth in claim 4, wherein said first pipette has a greater capillary force than said second pipette;

the first atomization matrix comprises first atomization liquid and second atomization liquid, the first atomization liquid is adsorbed in the first liquid suction pipe, the second atomization liquid is adsorbed in the second liquid suction pipe, the first atomization liquid and the second atomization liquid all contain propylene glycol, glycerol and essence and spice, and the mass fraction of the glycerol in the second atomization liquid is greater than that of the glycerol in the first atomization liquid.

6. A method of controlling a shared electronic atomizing system according to any one of claims 1 to 5, comprising the steps of:

s1, acquiring position information and atomized substrate information transmitted by a plurality of electronic atomization devices;

s2, selecting a target electronic atomization device according to the position information and the atomization matrix information;

s3, connecting the suction nozzle sleeve with the target electronic atomization device and generating connection information;

s4, according to the connection information, sending sucking habit data of a user in the suction nozzle sleeve to the target electronic atomization device;

S5, acquiring a sucking start signal according to the sucking habit data;

s6, controlling the first atomization assembly or the second atomization assembly to work according to the sucking start signal and the sucking habit data.

7. The method of claim 6, further comprising:

s7, acquiring health information of a user;

and S71, updating the sucking habit data according to the health information.

8. The method of claim 6, further comprising:

s8, acquiring atomization matrix replacement completion information;

s81, updating information of the atomized substrate according to the atomized substrate replacement completion information;

s82, the updated atomization matrix information and the position information of the electronic atomization device containing the atomization matrix information are sent to a remote server;

and S83, the remote server updates according to the updated atomizing matrix information and the updated position information.

9. The method for controlling a shared electronic atomizing system according to claim 8, wherein S83 includes:

S831, comparing the updated atomizing matrix information with preset atomizing matrix information, if the updated atomizing matrix information is matched with the preset atomizing matrix information, updating according to the updated atomizing matrix information and the position information, otherwise, sending an alarm signal.

10. The method for controlling a shared electronic atomizing system according to claim 6, further comprising, prior to S6:

s51, detecting whether a suction nozzle sleeve is sleeved at a suction nozzle of the electronic atomization device or not according to a suction start signal, and controlling the first atomization component and the second atomization component to prohibit operation when detecting that the suction nozzle sleeve is not sleeved at the suction nozzle.