A shared electronic atomization system and a control method thereof
By designing a shared electronic atomization system, the mouthpiece sleeve stores vaping habit data and communicates with the electronic atomization device, enabling automatic adjustment of the atomization matrix. This solves the problem of low atomization adjustment efficiency in existing shared electronic atomization devices, improving user experience and ease of use.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SHENZHEN KANGVAPE TECHNOLOGY CO LTD
- Filing Date
- 2023-07-27
- Publication Date
- 2026-07-07
AI Technical Summary
Existing shared electronic atomizing devices have low atomization adjustment efficiency, requiring users to search for and carefully select atomizing substrates, resulting in low adjustment efficiency and inconvenience.
Design a shared electronic atomization system, including an electronic atomizing device, a mouthpiece sleeve, a remote server, and a mobile terminal. The system achieves automatic adjustment of the atomization matrix through a positioning module and a wireless communication module. The mouthpiece sleeve stores user vaping habit data and communicates with the electronic atomizing device. The controller automatically atomizes according to the habit data. A one-way valve inside the mouthpiece sleeve prevents liquid backflow, and a compression component ensures a stable supply of atomization matrix.
Users do not need to manually select or adjust; the atomizing device automatically atomizes according to the user's vaping habits, improving adjustment efficiency and ease of use. The mouthpiece cover is easy to carry, prevents leakage, and is hygienic.
Smart Images

Figure CN117158664B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of electronic atomization technology, and more specifically, to a shared electronic atomization system and its control method. Background Technology
[0002] Electronic atomizing devices are electronic products that atomize a liquid to produce an aerosol for users to inhale. The atomizing base can be water, flavorings, or medicinal liquids, among other things. They have a wide range of applications, including addiction treatment and disease therapy. Currently, most electronic atomizing devices are personal, privately owned products that cannot be easily obtained and used in public places. Therefore, users must carry them with them, making them very inconvenient to use.
[0003] To address the aforementioned technical problems, for example, Chinese patent application number CN202022034695.9 discloses a shareable electronic atomizing device, which includes: a storage base, an electronic cigarette array, and a charging post; a plurality of first receiving cavities matching the electronic cigarette array are provided on a thickened side wall of the storage base; the electronic cigarette array is placed in the first receiving cavity; one end of the charging post is installed at the bottom of the first receiving cavity, and the other end is movably connected to the electronic cigarette array; and the mouthpiece of the electronic cigarette array is a replaceable mouthpiece, which can be replaced when each person reuses the electronic cigarette array, thus solving the problem that electronic cigarette arrays in existing designs cannot be shared by multiple people.
[0004] However, each user has different preferences for atomizing substrates and different inhalation volumes without aerosols. Therefore, every time a user wants to use it, they need to search for the location of their electronic atomizing device, carefully select the atomizing substrate according to their needs, and then spend a long time adjusting the atomization power to achieve the desired effect. As a result, the adjustment efficiency is low and it is inconvenient for users.
[0005] The above shortcomings need to be improved. Summary of the Invention
[0006] To address or alleviate the problem of low atomization adjustment efficiency in existing shared electronic atomization systems, this invention provides a shared electronic atomization system and its control method.
[0007] The technical solution of this invention is as follows:
[0008] A shared electronic atomization system includes an electronic atomizing device, a mouthpiece, a remote server, and a mobile terminal. The electronic atomizing device includes an atomizing matrix, a first atomizing component, a second atomizing component, a positioning module, a controller, and a first wireless communication module. The atomizing matrix includes a first atomizing matrix and a second atomizing matrix. The first atomizing component atomizes the first atomizing matrix, and the second atomizing component atomizes the second atomizing matrix. The positioning module provides location information. The controller controls the operation of the first atomizing component and the second atomizing component. The first wireless communication module communicates with the remote server and the mouthpiece. The electronic atomizing device is placed in a public place to atomize the atomizing matrix.
[0009] The mouthpiece cover includes a cover body, a memory, a microprocessor, and a second wireless communication module. The cover body is detachably connected to the electronic atomizing device. The memory stores the user's vaping habit data. The microprocessor transmits the vaping habit data to the first wireless communication module via the second wireless communication module. In a first state, the mouthpiece cover is spaced apart from the electronic atomizing device and placed at the user's location. In a second state, the mouthpiece cover is connected to the electronic atomizing device, enabling the electronic atomizing device to atomize the atomizing matrix. The remote server transmits information from the electronic atomizing device to the mobile terminal. The mobile terminal presents the information sent from the remote server to the user and interacts with the mouthpiece cover.
[0010] In the aforementioned shared electronic atomization system, the mouthpiece sleeve further includes a one-way valve. The sleeve body is provided with an air outlet for communicating with the first atomization component and the second atomization component. The one-way valve is installed in the air outlet to prevent liquid from flowing into the electronic atomization device from the air outlet.
[0011] In the aforementioned shared electronic atomization system, the mouthpiece sleeve further includes several layers of protective film that can be detachably covered on the sleeve body.
[0012] The aforementioned shared electronic atomization system further includes a housing, a first compression component, and an airflow sensor. The housing houses an isolation tube, a first suction tube, and a second suction tube. The isolation tube includes an upper receiving section with a first liquid inlet at its upper end. The first suction tube is located within the upper receiving section, and the capillary force at the upper end of the first suction tube is greater than the capillary force at its lower end. The second suction tube is sleeved outside the upper receiving section.
[0013] The first atomizing component is located inside the lower end of the first suction tube, and the height of the first inlet hole is higher than the height of the first atomizing component. The first compression component includes a first pressure ring and a first driver connected to the first pressure ring. The first pressure ring is located at the bottom of the second suction tube and is used to squeeze the second suction tube upward so that the atomized matrix in the second suction tube flows into the first suction tube from the first inlet hole. The controller is also used to disable the first atomizing component when the remaining amount of atomized matrix in the first suction tube is less than a first preset value.
[0014] Furthermore, the capillary force of the first suction tube is greater than that of the second suction tube;
[0015] The first atomizing matrix includes a first atomizing liquid and a second atomizing liquid. The first atomizing liquid is adsorbed in the first suction tube, and the second atomizing liquid is adsorbed in the second suction tube. Both the first atomizing liquid and the second atomizing liquid contain propylene glycol, glycerol, and fragrance. The mass fraction of glycerol in the second atomizing liquid is greater than the mass fraction of glycerol in the first atomizing liquid.
[0016] A control method for a shared electronic atomization system, applicable to the aforementioned shared electronic atomization system, includes the following steps:
[0017] S1. Obtain the location information and atomization matrix information transmitted from several of the electronic atomizing devices;
[0018] S2. Select the target electronic atomizing device based on the location information and atomizing matrix information;
[0019] S3. Connect the mouthpiece sleeve to the target electronic atomizing device and generate connection information;
[0020] S4. Based on the connection information, send the user's inhalation habit data inside the mouthpiece sleeve to the target electronic atomizing device;
[0021] S5. Obtain a smoking start signal based on the smoking habit data;
[0022] S6. Based on the inhalation start signal and the inhalation habit data, control the first atomizing component or the second atomizing component to operate.
[0023] The aforementioned control method for a shared electronic atomization system further includes:
[0024] S7. Obtain the user's health information;
[0025] S71. Update the smoking habit data based on the health information.
[0026] The aforementioned control method for a shared electronic atomization system further includes:
[0027] S8. Obtain information indicating that the atomizing matrix replacement is complete;
[0028] S81. Update the information of the atomizing matrix according to the information that the atomizing matrix replacement is completed;
[0029] S82. Send the updated atomizing matrix information and the location information of the electronic atomizing device containing the atomizing matrix information to the remote server;
[0030] S83. The remote server updates according to the updated atomization matrix information and the location information.
[0031] Furthermore, S83 includes:
[0032] S831. Compare the updated atomizing matrix information with the preset atomizing matrix information. If the updated atomizing matrix information matches the preset atomizing matrix information, then update the information according to the updated atomizing matrix information and the position information; otherwise, issue an alarm signal.
[0033] The aforementioned shared electronic atomization system control method further includes, prior to S6:
[0034] S51. Based on the inhalation start signal, detect whether the mouthpiece cover is fitted onto the mouthpiece of the electronic atomizing device. When it is detected that the mouthpiece cover is not fitted onto the mouthpiece, control the first atomizing component and the second atomizing component to disable operation.
[0035] According to the above-described solution, the beneficial effects of this invention are as follows: the electronic atomizing device can be placed in locations such as shopping malls, train stations, or bus stops. Users only need to carry a mouthpiece cover. When a user wants to vape outdoors, they can use a mobile terminal to view the location and information of surrounding electronic atomizing devices and select the optimal device. After arriving at the location, the user puts the mouthpiece cover on the device, and the user's vaping habit data is automatically transmitted to the device. When vaping, the device directly atomizes according to the user's vaping habit data, eliminating the need for further selection or adjustment by the user. This greatly improves adjustment and usage efficiency, resulting in a better user experience. Furthermore, the mouthpiece cover is easy to carry, eliminates the risk of leakage, and is hygienic. It avoids the inconvenience of carrying multiple electronic atomizing devices, which can lead to leakage of the atomizing matrix and staining of clothing. Attached Figure Description
[0036] To more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0037] Figure 1 This is a schematic diagram of the shared electronic atomization system of the present invention;
[0038] Figure 2 This is a schematic diagram of the electronic atomization device of the shared electronic atomization system of the present invention in its first state;
[0039] Figure 3 This is a schematic diagram of the electronic atomization device of the shared electronic atomization system of the present invention in the second state;
[0040] Figure 4 for Figure 2 An enlarged view of region A shown below;
[0041] Figure 5 for Figure 3 An enlarged view of region B shown;
[0042] Figure 6 for Figure 2 A perspective view of the sealed top cover shown;
[0043] Figure 7 for Figure 2 A perspective view of the sealed top cover from another angle;
[0044] Figure 8 This is a schematic diagram of the mouthpiece sleeve of the shared electronic atomization system of the present invention;
[0045] Figure 9 This is a flowchart of one embodiment of the control method for the shared electronic atomization system of the present invention. Detailed Implementation
[0046] To make the technical problems to be solved, the technical solutions, and the beneficial effects of the present invention clearer, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention and are not intended to limit the present invention.
[0047] It should be noted that when a component is referred to as "fixed," "set," or "connected" to another component, it may be located directly or indirectly on that other component. The terms "upper," "lower," "left," "right," "front," "rear," "vertical," "horizontal," "top," "bottom," "inner," and "outer," etc., indicate the orientation or position based on the accompanying drawings, and are for ease of description only, and should not be construed as limiting the technical solution. The terms "first," "second," etc., are used for ease of description only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features. "Many" means two or more, unless otherwise explicitly specified. "Several" means one or more, unless otherwise explicitly specified.
[0048] Please see Figures 1 to 9 This invention discloses a shared electronic atomization system, comprising an electronic atomizing device 100, a mouthpiece cover 200, a remote server 300, and a mobile terminal 400. The electronic atomizing device 100 is used to place in public places to atomize an atomizing matrix, wherein the public place can be a shopping mall, station, or bus stop, etc. The electronic atomizing device 100 includes a housing 10 and a first atomizing component 11, a second atomizing 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 located within the housing 10. A first cavity 101 is provided within the housing 10, and the first cavity 101 contains an atomizing matrix, which includes a first atomizing matrix and a second atomizing matrix. It is understood that the atomizing matrix can include multiple atomizing matrices, and their quantity is not specifically limited herein.
[0049] 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 within the first sleeve 103, and a first cavity 101 is formed within the second sleeve 104. 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 heat-insulating gap is formed between the third sleeve 105 and the first sleeve 103, thus preventing overheating of the third sleeve 105 during use. One end of the third sleeve 105 is connected to a bottom cover 106, and the bottom cover 106 is provided with an air inlet 1061 communicating with the second atomizing component 12. One end of the housing 10 is connected to a nozzle 107, which is connected to the first sleeve 103, the second sleeve 104, and the third sleeve 105. The bottom cover 106 and the nozzle 107 are located at opposite ends of the third sleeve 105. The nozzle 107 is provided with a mist outlet 1071, which is connected to the first atomizing component 11 and the second atomizing component 12.
[0050] The first cavity 101 houses an isolation tube 191, a first suction tube 192, a second suction tube 193, a third suction tube 194, and a fourth suction tube 195. The isolation tube 191 includes an upper receiving section and a lower receiving section. The first suction tube 192 is located in the upper receiving section and communicates with the mist outlet 1071. The isolation tube 191 is used to prevent external forces from being transmitted to the first suction tube 192, thus preventing the first suction tube 192 from being deformed by external forces, which could lead to unstable liquid supply. In addition, if external forces are transmitted to the first atomizing component 11 through the first suction tube 192, it may cause the first atomizing component 11 to deform, thereby affecting the resistance value of the first atomizing component 11 and thus affecting the stability of the aerosol output. In other words, the isolation tube 191 protects against external forces acting on the first atomizing component 11 and the second atomizing component 12, thereby ensuring the stability of their resistance values and ensuring the stability of the aerosol output.
[0051] The second suction tube 193 is located inside the first cavity 101 and sleeved outside the upper receiving section to replenish the atomized liquid in the first suction tube 192 when the atomized liquid in the first suction tube 192 is insufficient. The first suction tube 192 and the second suction tube 193 are used to adsorb the first atomized matrix. A first inlet hole 1911 is provided at the upper end of the upper receiving section. Preferably, to prevent the atomized liquid in the second suction tube 193 from spraying into the first suction tube 192 during liquid discharge, the cross-sectional area of the inlet of the first inlet hole 1911 is smaller than the cross-sectional area of the outlet of the first inlet hole 1911. More preferably, the angle formed by the centerline of the first inlet hole 1911 and the cross-section of the isolation tube 191 is greater than 45°. Therefore, the impact force of the flowing atomized liquid on the first suction tube 192 during liquid discharge is effectively reduced.
[0052] It is understood that the isolation tube 191 can be made of materials such as plastic or metal. In this embodiment, the isolation tube 191 is a stainless steel tube, and the first suction tube 192 to the fourth suction tube 195 are all cotton tubes. It is understood that in other embodiments, the first suction tube 192 to the fourth suction tube 195 can be made of other porous materials, and the material is not specifically limited here.
[0053] The porosity of the upper end of the first suction tube 192 is less than that of the lower end, and the capillary force at the upper end of the first suction tube 192 is greater than that at the lower end. Therefore, when the atomizing matrix in the first suction tube 192 is relatively small, even under the influence of gravity, the atomizing matrix is uniform or has little difference between the upper and lower ends, thus ensuring a uniform and stable liquid supply to the first atomizing component 11. This achieves a stable aerosol output and avoids the problem of unstable aerosol output, which can easily cause coughing when the user inhales. Preferably, the porosity of the first suction tube 192 gradually increases from top to bottom, and the capillary force of the first suction tube 192 gradually decreases from top to bottom.
[0054] In a preferred embodiment of the present invention, the porosity of the first suction tube 192 is less than that of the second suction tube 193, and the capillary force of the first suction tube 192 is greater than that of the second suction tube 193. Therefore, not only can the liquid storage capacity in the region of the second suction tube 193 be increased, but the stability of the atomized matrix supply is also ensured. The third suction tube 194 is located in the lower receiving section, and a first liquid-separating ring 196 is provided between the first suction tube 192 and the third suction tube 194. The first liquid-separating ring 196 is used to prevent the atomized matrix at the first suction tube 192 from flowing into the third suction tube 194, thus avoiding the problem of insufficient atomized liquid supply in the first suction tube 192 due to insufficient atomized liquid supply caused by gravity flowing into the third suction tube 194. Preferably, the capillary force of the third suction tube 194 is greater than that of the first suction tube 192, and the third suction tube 194 and the first suction tube 192 are coaxially arranged. Therefore, it can effectively lock in the atomizing matrix and prevent the atomizing matrix from leaking.
[0055] The first atomizing component 11 is located inside the lower end of the first suction tube 192, and the height of the first inlet hole 1911 is higher than the height of the first atomizing component 11. Since the height of the first inlet hole 1911 is higher than the height of the first atomizing component 11, when the supply of atomizing liquid in the first suction tube 192 is insufficient, the atomizing liquid in the second suction tube 193 is drawn from the first inlet hole 1911 into the upper end of the first suction tube 192 through the first compression component 13. Therefore, not only can the liquid be supplied in a timely manner, but the atomizing matrix transported from the upper end of the second suction tube 193 also flows slowly towards the direction of the first atomizing component 11 under the action of gravity, which well ensures that the amount of atomizing liquid at the upper and lower ends of the first suction tube 192 is uniform or has little difference.
[0056] In this embodiment, the first atomizing component 11 includes a first absorbent cotton column 111 and a first heating element 112. The first absorbent cotton column 111 is located inside and in contact with the first absorbent tube 192. The first heating element 112 is located inside and in contact with the first absorbent cotton column 111, and is used to atomize the atomized matrix inside the first absorbent cotton column 111. The first heating element 112 can be a heating wire wound into a tubular shape or a tubular heating plate, etc., and its structure is not specifically limited here. More specifically, in this embodiment, the first heating element 112 is a heating wire wound into a tubular shape, and the heating wire is coaxially arranged with the first absorbent cotton column 111 and the first absorbent tube 192.
[0057] The second atomizing component 12 is located within the third suction tube 194. The second atomizing component 12 includes a second absorbent cotton column 121 and a second heating element 122. The second absorbent cotton column 121 is located within and in contact with the third suction tube 194. The second heating element 122 is located within and in contact with the second absorbent cotton column 121, and is used to atomize the atomized matrix within the second absorbent cotton column 121. The second heating element 122 can be a heating wire wound into a tubular shape or a tubular heating plate, etc., and its structure is not specifically limited here. More specifically, in this embodiment, the second heating element 122 is a heating wire wound into a tubular shape, and the heating wire is coaxially arranged with the second absorbent cotton column 121 and the third suction tube 194. The fourth suction tube 195 is sleeved on the outer periphery of the lower receiving section. The upper end of the lower receiving section is provided with a second liquid inlet 1912, which is used to introduce the atomized matrix at the fourth suction tube 195 into the third suction tube 194.
[0058] In a preferred embodiment of the present invention, the first atomizing matrix includes a first atomizing liquid and a second atomizing liquid. The first atomizing liquid is adsorbed in the first suction tube 192, and the second atomizing liquid is adsorbed in the second suction tube 193. Both the first and second atomizing liquids contain propylene glycol, glycerol, and fragrance. The mass fraction of glycerol in the second atomizing liquid is greater than that in the first atomizing liquid, thus better ensuring the stability of the aerosol discharge. Preferably, the saturation of the first atomizing liquid in the first suction tube 192 is less than the saturation of the second atomizing liquid in the second suction tube 193, thereby avoiding oversaturation of the first suction cotton column 111, which could lead to significant differences in aerosol particle size and cause user discomfort.
[0059] It is understandable that propylene glycol, as a solvent, is used to dissolve fragrances and flavorings to provide users with the desired taste, while glycerol is used to generate atomized aerosols, and its proportion basically determines the amount of aerosol. Since some glycerol comes into contact with the high-temperature aerosol during the process of being transported from the upper end of the first suction tube 192 to the first atomizing component 11 after the atomizing liquid is discharged from the first inlet 1911, it vaporizes to form aerosol. Therefore, through the above-mentioned arrangement, the lost glycerol can be replenished, thereby better ensuring that the aerosol discharge volume is relatively stable after a period of use compared to the initial use. In this embodiment, the third suction tube 194 and the fourth suction tube 195 adsorb the second atomizing matrix, which contains propylene glycol, glycerol, and nicotine, but does not contain fragrances or flavorings.
[0060] In a preferred embodiment of the present invention, the electronic atomizing device 100 further includes a second liquid-separating ring 197, which is located between the second liquid-suction tube 193 and the fourth liquid-suction tube 195, and is used to prevent the atomized liquid at the second liquid-suction tube 193 from flowing into the fourth liquid-suction tube 195. Preferably, the second liquid-separating ring 197 and the liquid-separating tube are integrally formed.
[0061] The first compression assembly 13 includes a first pressure ring 131 and a first driver 132 connected to the first pressure ring 131. The first pressure ring 131 is located at the bottom of the second suction tube 193 and is used to squeeze the second suction tube 193 upward so that the atomized liquid in the second suction tube 193 flows into the first suction tube 192 from the first inlet hole 1911, thereby timely replenishing the atomized matrix to the first suction tube 192 and ensuring the stability of the aerosol discharge. The first driver 132 includes a second motor 1321 and a first screw 1322. The second motor 1321 is fixed at the second housing 10. The first end of the first screw 1322 is connected to the second motor 1321, and the second end of the first screw 1322 is threadedly connected to the first pressure ring 131. When the first screw 1322 rotates, it can drive the first pressure ring 131 to move up and down.
[0062] The second compression assembly 14 includes a second pressure ring 141 and a second driver 142 connected to the second pressure ring 141. The second pressure ring 141 is located at the bottom of the fourth suction tube 195 and is used to squeeze the fourth suction tube 195 upward so that the atomized liquid in the fourth suction tube 195 flows into the third suction tube 194 from the second inlet hole 1912, thereby timely replenishing the atomized matrix to the third suction tube 194 and ensuring the stability of the aerosol discharge. The second driver 142 includes a third motor 1421 and a second screw 1422. The third motor 1421 is fixed at the second housing 10. The second screw 1422 is connected to the third motor 1421 and threadedly connected to the second pressure ring 141. When the second screw 1422 rotates, it can drive the second pressure ring 141 to move upward to squeeze the atomized liquid at the fourth suction tube 195 and deliver the atomized liquid from the second inlet hole 1912 into the third suction tube 194.
[0063] In one embodiment of the present invention, the electronic atomizing device 100 further includes a capacitor 5 electrically connected to a controller 17. The capacitor 5 is located inside a first suction tube 192 and is used to detect the remaining amount of atomized liquid in the first suction tube 192. The capacitor 5 includes a first electrode 51 and a second electrode 52, which are positioned opposite each other and located inside the first suction tube 192. Both the first electrode 51 and the second electrode 52 are electrically connected to the controller 17. The controller 17 calculates the remaining amount of atomized liquid in the first suction tube 192 based on the capacitance of the capacitor 5. Preferably, the height of the capacitor 5 is higher than the height of the first atomizing component 11, thus avoiding interference from the first atomizing component 11 and improving the accuracy of the detection.
[0064] In one embodiment of the present invention, a sealing top cover 6 is housed within the nozzle 107, and the sealing top cover 6 is sealed to the housing 10. The sealing top cover 6 is provided with a mounting groove 61, an air outlet groove 62, an insertion hole 63, a connecting groove 64, and a fixing groove 65. The mounting groove 61 is used to install the airflow sensor 15 and communicates with the air outlet groove 62. The air outlet groove 62 is used to communicate with the mist outlet 1071. Specifically, the air outlet groove 62 extends in the lateral direction of the electronic atomizing device 100. The insertion hole 63 communicates with the air outlet groove 62 and extends 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. The first end of the connecting groove 64 communicates with the air outlet groove 62 and the insertion hole 63, and the second end of the connecting groove 64 communicates with the fixing groove 65. The air outlet groove 62 communicates with the mist outlet 1071 through the connecting groove 64.
[0065] The airflow sensor 15 is installed in the mounting groove 61 at the sealing top cover 6 and communicates with the air outlet groove 62, so as to connect to the mist outlet 1071 through the air outlet groove 62. The bottom wall of the air outlet groove 62 is higher than the bottom wall of the connecting groove 64, so condensate is not easily allowed to flow into the air outlet groove 62 and thus into the airflow sensor 15. The sealing top cover 6 is also provided with an air inlet groove 66 communicating with the airflow sensor 15, and the air inlet groove 66 is located below the airflow sensor 15.
[0066] The positioning module 16 is electrically connected to the controller 17 and is used to provide the location information of the electronic atomizing device 100. The positioning module 16 can be a GPS positioning module or a Beidou positioning module, etc. The first wireless communication module 18 is used to communicate with the remote server 300 and the mouthpiece cover 200 to send the location information of the electronic atomizing device 100 and the information of the atomizing matrix to the remote server 300, and to obtain vaping habit data from the mouthpiece cover 200. It is understood that the first wireless communication module 18 can be a Bluetooth module, a WiFi module, etc., as long as it can realize wireless communication, and its structure is not specifically limited here.
[0067] In one embodiment of the present invention, the electronic atomizing device 100 further includes a third absorbent cotton column 71, an elastic reset member 72, and an air passage barrier assembly 8. The third absorbent cotton column 71 is cylindrical, with its first end inserted into the fixing groove 65 and its second end abutting against the opening of the mist outlet 1071. Thus, it can effectively absorb the condensate flowing down from the mist outlet 1071, preventing the condensate from spreading everywhere.
[0068] The elastic reset member 72 is located inside the housing 10 and elastically abuts against the airflow blocking assembly 8. In the first state, the mouthpiece sleeve 200 is spaced apart from the electronic atomizing device 100 and placed at the user's location. At this time, the mouthpiece sleeve 200 is separated from the mouthpiece 107, and the airflow blocking assembly 8 closes the air outlet groove 62. That is, when the invention is not in use, the mouthpiece sleeve 200 is separated from the mouthpiece 107, and the mouthpiece sleeve 200 is placed in the user's pocket. Under the elastic force of the elastic reset member 72, the airflow blocking assembly 8 automatically closes the air outlet groove 62, thereby preventing the condensate from flowing towards the airflow sensor 15. In the second state, the mouthpiece sleeve 200 is fitted onto the mouthpiece 107 and connected to the electronic atomizing device 100. The mouthpiece sleeve 200 drives the airflow blocking assembly 8, causing the airflow blocking assembly 8 to open the air outlet groove 62, so that the electronic atomizing device 100 can atomize the atomized matrix, and thus the user can use the invention normally.
[0069] 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. The blocking member 81 is connected to an elastic reset member 72 and movably connected to a sealing top cover 6. Specifically, the blocking member 81 passes through the insertion hole 63 and extends into the connecting groove 64. The nozzle sleeve 200 includes a sleeve body 21 and a second magnetic member 22 connected to the sleeve body 21. The sleeve body 21 is detachably connected to the electronic atomizing device 100. The sleeve body 21 is provided with an air outlet 201 for communicating with the first atomizing assembly 11 and the second atomizing assembly 12. In the first state, the elastic reset member 72 drives the blocking member 81, causing the blocking member 81 to close the air outlet groove 62. In the second state, the second magnetic member 22 and the first magnetic member 82 are magnetically repelled, causing the air path blocking assembly 8 to open the air outlet groove 62, so that the air outlet groove 62 can communicate with the mist outlet 1071 through the connecting groove 64. It is understood that the elastic reset element 72 can be a spring or a sheet, etc., and its structure is not specifically limited here. In this embodiment, both the first magnetic element 82 and the second magnetic element 22 are magnets.
[0070] like Figure 8As shown, the mouthpiece sleeve 200 also includes a first battery 23, a memory 24, a microprocessor 25, and a second wireless communication module 26 located within the sleeve body 21. The first battery 23 supplies power to the electrical components within the sleeve body 21. The memory 24 is electrically connected to the microprocessor 25 and is used to store the user's smoking habit data. The microprocessor 25 is electrically connected to the second wireless communication module 26 and is used to transmit the smoking habit data to the first wireless communication module 18 via the second wireless communication module 26. It is understood that the second wireless communication module 26 can be a Bluetooth module, a WiFi module, etc., as long as it enables wireless communication; its structure is not specifically limited here. The microprocessor 25 can be a microcontroller, etc.
[0071] After the user finishes inhaling, the first wireless communication module 18 sends the user's inhalation habit data to the second wireless communication module 26. The second wireless communication module 26 then sends this data to the microprocessor 25, which writes it into the memory 24. When the user needs to smoke, they place the mouthpiece cover 200 onto the mouthpiece 107. The microprocessor 25 then reads the user's inhalation habit data from the memory 24 and sends it to the first wireless communication module 18 via the second wireless communication module 26. The electronic atomizing device 100 then atomizes the atomizing matrix within itself based on this data. Furthermore, the first wireless communication module 18 also provides information about the electronic atomizing device, including location information and atomizing matrix information, to the remote server 300. It is understood that the first wireless communication module 18 communicates with the remote server 300 via a communication network.
[0072] like Figure 5 As shown, in a preferred embodiment of the present invention, the mouthpiece sleeve 200 further includes a third magnetic component 27, a one-way valve 28, and several protective films 29 detachably covering the sleeve body 21. The third magnetic component 27 is fixed inside the sleeve body 21. The one-way valve 28 is installed inside the air outlet 201 to prevent liquid from flowing into the electronic atomizing device 100 from the air outlet 201. Therefore, it can prevent the user from blowing air into the electronic atomizing device 100, causing the airflow sensor 15 to be falsely triggered, avoiding interference with the user's vaping habit data, and improving the accuracy of the vaping habit data. Each time the user finishes vaping, a protective film 29 can be peeled off, thus keeping it clean and hygienic.
[0073] like Figure 4As shown, in a preferred embodiment of the present invention, the electronic atomizing device 100 further includes a push plug 91, which is connected to the blocking member 81. In a first state, the push plug 91 is at least partially inserted into the air inlet groove 66, and in a second state, the push plug 91 is spaced apart from the opening of the air inlet groove 66. That is, when the user finishes inhaling and removes the mouthpiece sleeve 200, the elastic reset member 72 drives the blocking member 81 to move towards the mouthpiece 107, and at the same time, the blocking member 81 drives the push plug 91 to insert into the air inlet groove 66. Therefore, during the process of the user finishing inhaling and removing the mouthpiece sleeve 200, the airflow in the air outlet groove 62 continues to flow towards the mist outlet 1071 through the drive of the air plug 91, preventing the aerosol remaining in the mouthpiece 107 from flowing into the airflow sensor 15, thus improving the service life of the airflow sensor 15. In addition, when the blocking member 81 moves to the preset position, it will separate the airflow sensor 15 from the mist outlet 1071. This structure is ingenious, low in cost, easy to use, easy to implement, and effective.
[0074] like Figure 4 As shown, in a preferred embodiment of the present invention, the electronic atomizing device 100 further includes an elastic sealing sheet 92. The elastic sealing sheet 92 is located on the side of the sealing top cover 6 facing away from the second cavity 102 and covers the opening of the air outlet groove 62 to seal the opening on the side facing away from the second cavity 102. Therefore, when the user inhales, the airflow in the area of the mounting groove 61 can quickly flow to the mist outlet 1071, thereby quickly triggering the airflow sensor 15, thus improving the sensitivity of the airflow sensor 15 and improving the user experience. In addition, this structure is easy to manufacture, reduces the manufacturing process, and improves production efficiency. It is understood that in the first state, the air path blocking component 8 abuts against the elastic sealing sheet 92. It is understood that in one embodiment, the elastic sealing sheet 92 may not be required, and the opening of the air outlet groove 62 facing away from the second cavity 102 elastically abuts against the mouthpiece 107. In the first state, the air path blocking component 8 abuts against the mouthpiece 107.
[0075] like Figure 5 As shown, 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 a third magnetic component 27 for cooperating with the Hall sensor 93. The Hall sensor 93 is installed inside the sealed top cover 6 and electrically connected to the controller 17, for detecting whether the mouthpiece sleeve 200 is covering the mouthpiece 107. The second battery 94 is used to provide electrical energy to power the first atomizing component 11, the second atomizing component 12, and other electrical components.
[0076] The controller 17 is electrically connected to the airflow sensor 15 and the second battery 94, and is used to control the operation of the first atomizing component 11 and the second atomizing component 12. When the remaining amount of atomized liquid in the first suction tube 192 is less than a first preset value, the first atomizing component 11 is disabled. In other words, when the remaining amount of atomized liquid in the first suction tube 192 is less than the first preset value, the first atomizing component 11 is permanently shut off, maintaining a stable aerosol output during inhalation and avoiding fluctuations in aerosol output that could cause coughing during inhalation. The controller 17 may include a microcontroller or a programmable logic array, etc.
[0077] The remote server 300 contains information about several electronic atomizing devices 100 and is used to send this information to a mobile terminal 400. The mobile terminal 400 includes smart mobile devices such as mobile phones, tablets, and smartwatches. The information about the electronic atomizing devices 100 includes their location information and the flavor of the atomizing medium. This information can be obtained through information exchange between the remote server 300 and the electronic atomizing devices 100, or it can be written into the remote server 300 by the manufacturer or operator.
[0078] The mobile terminal 400 is used to present information sent from the remote server 300 to the user and to interact with the mouthpiece cover 200. Specifically, the user's mobile terminal 400 has an application (APP) installed. The application interacts with the remote server 300. When the user clicks on the application on the mobile terminal 400, they can see the location information of the electronic atomizing device 100 around them and information such as the flavor of the atomizing medium. It can be understood that the mobile terminal 400 is a common portable mobile phone, i.e., a smart mobile terminal. When the user uses the mouthpiece cover 200 for the first time, they set their preferred atomizing medium and atomization power through the mobile terminal, which serves as the user's vaping habit data. The mobile terminal 400 then transmits this user's vaping habit data to the mouthpiece cover 200, allowing the mouthpiece cover 200 to obtain the initial user's vaping habit data. Of course, the user can also set their preferences at any time through the mobile terminal 400.
[0079] Please see Figure 9 The present invention also discloses a control method for a shared electronic atomization system, applicable to the aforementioned shared electronic atomization system, comprising the following steps:
[0080] S1. Obtain the location information and atomization matrix information transmitted from several electronic atomizing devices 100;
[0081] When a user wants to inhale, they click on the application on the mobile terminal 400. The application then displays the location information of several electronic atomizing devices 100 around the user and information such as the flavor of the atomizing matrix on the mobile terminal 400.
[0082] S2. Select the target electronic atomizing device 100 based on the location information and atomizing matrix information;
[0083] Users can select their preferred electronic atomizing device 100 on the mobile terminal 400 as the target electronic atomizing device 100, and use the location information provided by the target electronic atomizing device 100 as the user's navigation information.
[0084] S3. Connect the mouthpiece sleeve 200 to the target electronic atomizing device 100 and generate connection information;
[0085] After arriving at the location of the target electronic atomizing device 100 according to the navigation information, the user connects the mouthpiece 200 they carry with the target electronic atomizing device 100.
[0086] S4. Based on the connection information, send the user's inhalation habit data inside the mouthpiece sleeve 200 to the target electronic atomizing device 100;
[0087] After the mouthpiece 200 establishes a communication connection with the first wireless communication module 18 of the target electronic atomizing device 100 via the second wireless communication module 26, the microprocessor 25 sends the vaping habit data to the first wireless communication module 18 via the second wireless communication module 26, thereby enabling the controller 17 of the target electronic atomizing device 100 to obtain the user's vaping habit data from the first wireless communication module 18. In this embodiment, both the second wireless communication module 26 and the first wireless communication module 18 are Bluetooth modules, and the connection information is the handshake information between Bluetooth modules.
[0088] S5. Obtain the signal of initiation of drug use based on drug use habit data;
[0089] After the controller 17 acquires the smoking habit data, it monitors the airflow sensor 15 in real time to obtain the smoking start signal.
[0090] S6. Based on the inhalation start signal and inhalation habit data, control the first atomizing component 11 or the second atomizing component 12 to work.
[0091] When a user inhales, the airflow sensor 15 is triggered, and the airflow sensor 15 sends an inhalation start signal to the controller 17. The controller 17 controls the first atomizing component 11 or the second atomizing component 12 to work based on the inhalation start signal and inhalation habit data.
[0092] For example, if the flavoring in the first suction tube 192 is minty, and the user prefers mint and a 9-watt atomization power, then when the user inhales, the controller 17 directly controls the first atomizing component 11 to atomize at a 9-watt power, without needing to adjust or wait. If the user prefers nicotine and a 10-watt atomization power, then when the user inhales, the controller 17 directly controls the second atomizing component 11 to atomize at a 10-watt power, without needing to adjust or wait. Therefore, this design is user-friendly and improves adjustment and usage efficiency.
[0093] In a preferred embodiment of the present invention, the control method further includes:
[0094] S7. Obtain the user's health information;
[0095] S71. Update smoking habit data based on health information.
[0096] After the user binds the mobile terminal 400 to the mouthpiece cover 200, the user's medical examination report is photographed and health information is obtained through the application on the mobile terminal 400. Based on this health information, the mobile terminal 400 modifies the user's inhalation habit data and sends it to the mouthpiece cover 200 to update the data, thus benefiting the user's health. For example, if the user's health information indicates that the user needs to reduce the amount of menthol-flavored aerosol inhaled, then when the user inhales, the controller 17 controls the first atomizing component 11 to atomize at a power of less than 9 watts. This power could be 6 watts or 5 watts, etc. S7 can be performed at any time; it can be performed before, after, or simultaneously with any of the steps S1-S6, meaning S7 is relatively independent of the other steps.
[0097] In a preferred embodiment of the present invention, the control method further includes:
[0098] S8. Obtain information indicating that the atomizing matrix replacement is complete;
[0099] S81. Update the information of the atomizing substrate based on the completion information of the atomizing substrate replacement;
[0100] S82. Send the updated atomizing matrix information and the location information of the electronic atomizing device 100 containing the atomizing matrix information to the remote server 300.
[0101] S83 and remote server 300 update according to the updated atomization matrix information and location information.
[0102] A QR code is affixed to the reservoir containing the atomizing matrix. After adding the atomizing matrix from the reservoir to the electronic atomizing device 100, the user scans the QR code using an application on a mobile terminal 400 to obtain information about the completed atomizing matrix replacement and the new atomizing matrix, and then updates the information. The mobile terminal 400 sends the updated atomizing matrix information and the location information of the electronic atomizing device 100 containing this information to a remote server 300. Therefore, other users can obtain the updated information when querying the electronic atomizing device 100 through their mobile terminals 400. Step S8 can be performed at any time; it can be performed before, after, or simultaneously with any of steps S1-S7, meaning S8 is relatively independent of the other steps.
[0103] In a preferred embodiment of the present invention, "the remote server 300 updates the information based on the updated atomization matrix information and location information" includes:
[0104] S831. Compare the updated atomizing matrix information with the preset atomizing matrix information. If the updated atomizing matrix information matches the preset atomizing matrix information, then update the information according to the updated atomizing matrix information and the location information; otherwise, issue an alarm signal.
[0105] When the updated atomizing matrix information does not match the preset atomizing matrix information, the new atomizing matrix may be harmful to health. In this case, the remote server 300 will send an alarm message to the user's mobile terminal 400, and the user's mobile terminal 400 will issue an alarm signal to remind the user and improve the safety of the user.
[0106] In a preferred embodiment of the present invention, the method further includes the following step before S6:
[0107] S51. Based on the inhalation start signal, detect whether the mouthpiece cover 200 is fitted onto the mouthpiece 107 of the electronic atomizing device 100. When it is detected that the mouthpiece cover 200 is not fitted onto the mouthpiece 107, control the first atomizing component 11 and the second atomizing component 12 to stop working, and send the information of stopping working to the remote server 300.
[0108] Under normal circumstances, the controller 17 only controls the first atomizing component 11 or the second atomizing component 12 to operate after the mouthpiece cover 200 is placed on the mouthpiece 107 of the electronic atomizing device 100 and a sucking start signal is received from the airflow sensor 15. If the mouthpiece cover 200 is not placed on the mouthpiece 107 of the electronic atomizing device 100, but a sucking start signal is received from the airflow sensor 15, it indicates that a violent sucking has occurred. Therefore, the controller prevents the first atomizing component 11 and the second atomizing component 12 from operating, thereby improving user safety. The operator can perform maintenance and safety management based on the information provided by the remote server 300.
[0109] In a preferred embodiment of the present invention, before step S6, the method further includes:
[0110] S52. When the remaining amount of atomized matrix in the first suction tube 192 is greater than the first preset value but less than the second preset value, the first driver 132 is controlled to drive the first pressure ring 131 to move upward to squeeze the second suction tube 193.
[0111] When the remaining amount of atomized matrix in the first suction tube 192 is greater than a first preset value but less than a second preset value, it indicates that the remaining amount is insufficient for long-term liquid supply and the atomized matrix needs to be replenished promptly. At this time, the controller 17 controls the first driver 132 to drive the first pressure ring 131 upward a preset distance to squeeze the second suction tube 193, thereby allowing the atomized matrix in the second suction tube 193 to flow into the first suction tube 192. It is understood that the magnitudes of the first and second preset values can be set according to the type of atomizing liquid and are not specifically limited here.
[0112] In a preferred embodiment of the present invention, step S6 further includes:
[0113] S61. When the remaining amount of atomizing matrix in the first suction tube 192 is not greater than the first preset value, the first atomizing component 11 is prohibited from working; or, when the remaining amount of atomizing matrix in the second suction tube 193 is not greater than the first preset value, the second atomizing component 12 is prohibited from working.
[0114] When the amount of atomizing matrix in the first suction tube 192 or the second suction tube 193 is insufficient, the corresponding atomizing component is prohibited from working, thus maintaining a stable aerosol discharge volume.
[0115] In a preferred embodiment of the present invention, the control method further includes the following steps:
[0116] The system counts the number of times a user inhales the liquid. If the number of inhalations exceeds a preset number and the cumulative amount of condensate at point 71 of the third absorbent cotton column is less than a third preset value, a condensate leakage alarm signal will be issued.
[0117] Due to the act of suction, condensation is inevitable, and the amount of condensate will inevitably increase with each suction cycle. Assuming a preset number of suction cycles, if the cumulative amount of condensate after these cycles is still less than a third preset value, it indicates that the third absorbent cotton column 71 is not properly assembled, and the condensate within the third absorbent cotton column 71 has leaked into other areas. In this case, the controller 17 will issue a condensate leakage alarm signal, thus effectively protecting the user's health and solving the problem of how to determine whether condensate leakage is due to improper assembly of the third absorbent cotton column 71. In one embodiment, the amount of condensate at the third absorbent cotton column 71 can be detected by a humidity sensor connected to the controller 17, or by a separately installed capacitor. It is understood that the controller 17 may include a microcontroller and a speaker electrically connected to the microcontroller, the speaker being used to issue a condensate leakage alarm signal.
[0118] In summary, the electronic atomizing device 100 of the present invention can be placed in locations such as shopping malls, train stations, and bus stops. Users only need to carry the mouthpiece cover 200. When a user wants to vape outdoors, they can use a mobile terminal 400 to view the location and information of the surrounding electronic atomizing devices 100 and select the optimal electronic atomizing device 100. After arriving at the appropriate location, the user puts the mouthpiece cover 200 on the electronic atomizing device 100, and the user's vaping habit data is transmitted to the electronic atomizing device 100. When vaping, the electronic atomizing device 100 directly atomizes according to the user's vaping habit data, without the need for the user to select or adjust, thus greatly improving adjustment efficiency and usage efficiency, and providing a good user experience. In addition, the mouthpiece cover 200 is easy to carry, has no risk of leakage, and is relatively hygienic. It avoids the problems of carrying multiple electronic atomizing devices 100, which are not only inconvenient to carry, but also prone to leakage of the atomizing matrix, resulting in staining of clothing.
[0119] It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered in all respects as exemplary and non-limiting, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.
[0120] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. A shared electronic atomization system, characterized in that, The system includes an electronic atomizing device, a mouthpiece, a remote server, and a mobile terminal. The electronic atomizing device includes an atomizing matrix, a first atomizing component, a second atomizing component, a positioning module, a controller, and a first wireless communication module. The atomizing matrix includes a first atomizing matrix and a second atomizing matrix. The first atomizing component atomizes the first atomizing matrix, and the second atomizing component atomizes the second atomizing matrix. The positioning module provides location information. The controller controls the operation of the first atomizing component and the second atomizing component. The first wireless communication module is used to communicate with the remote server and the mouthpiece sleeve; the electronic atomizing device is used to be placed in public places to atomize the atomizing matrix; The mouthpiece sleeve includes a sleeve body, a memory, a microprocessor, and a second wireless communication module. The sleeve body is detachably connected to the electronic atomizing device. The memory is used to store the user's vaping habit data. The microprocessor is used to send the vaping habit data to the first wireless communication module via the second wireless communication module. In a first state, the mouthpiece sleeve is spaced apart from the electronic atomizing device and is placed at the user's location. In a second state, the mouthpiece sleeve is connected to the electronic atomizing device so that the electronic atomizing device can atomize the atomizing matrix. The remote server is used to send information about the electronic atomizing device to the mobile terminal; The mobile terminal is used to present the information sent from the remote server to the user and to interact with the mouthpiece sleeve.
2. The shared electronic atomization system according to claim 1, characterized in that, The nozzle sleeve also includes a one-way valve. The sleeve body is provided with an air outlet for communicating with the first atomizing component and the second atomizing component. The one-way valve is installed in the air outlet to prevent liquid from flowing into the electronic atomizing device from the air outlet.
3. A shared electronic atomization system according to claim 1 or 2, characterized in that, The nozzle sleeve also includes several layers of protective film that can be detachably covered on the sleeve body.
4. A shared electronic atomization system according to claim 1 or 2, characterized in that, The electronic atomizing device further includes a housing, a first compression assembly, and an airflow sensor. The housing houses an isolation tube, a first liquid suction tube, and a second liquid suction tube. The isolation tube includes an upper receiving section, with a first liquid inlet at the upper end of the upper receiving section. The first liquid suction tube is located within the upper receiving section, and the capillary force at the upper end of the first liquid suction tube is greater than the capillary force at the lower end of the first liquid suction tube. The second liquid suction tube is sleeved outside the upper receiving section. The first atomizing component is located inside the lower end of the first suction tube, and the height of the first inlet hole is higher than the height of the first atomizing component. The first compression component includes a first pressure ring and a first driver connected to the first pressure ring. The first pressure ring is located at the bottom of the second suction tube and is used to squeeze the second suction tube upward so that the atomized matrix in the second suction tube flows into the first suction tube from the first inlet hole. The controller is also used to disable the first atomizing component when the remaining amount of atomized matrix in the first suction tube is less than a first preset value.
5. A shared electronic atomization system according to claim 4, characterized in that, The capillary force of the first suction tube is greater than that of the second suction tube; The first atomizing matrix includes a first atomizing liquid and a second atomizing liquid. The first atomizing liquid is adsorbed in the first suction tube, and the second atomizing liquid is adsorbed in the second suction tube. Both the first atomizing liquid and the second atomizing liquid contain propylene glycol, glycerol, and fragrance. The mass fraction of glycerol in the second atomizing liquid is greater than the mass fraction of glycerol in the first atomizing liquid.
6. A control method for a shared electronic atomization system, characterized in that, The shared electronic atomization system applicable to any one of claims 1-5 comprises the following steps: S1. Obtain the location information and atomization matrix information transmitted from several of the electronic atomizing devices; S2. Select the target electronic atomizing device based on the location information and atomizing matrix information; S3. Connect the mouthpiece sleeve to the target electronic atomizing device and generate connection information; S4. Based on the connection information, send the user's inhalation habit data inside the mouthpiece sleeve to the target electronic atomizing device; S5. Obtain a smoking start signal based on the smoking habit data; S6. Based on the inhalation start signal and the inhalation habit data, control the first atomizing component or the second atomizing component to operate.
7. The control method for a shared electronic atomization system according to claim 6, characterized in that, The control method further includes: S7. Obtain the user's health information; S71. Update the smoking habit data based on the health information.
8. The control method for a shared electronic atomization system according to claim 6, characterized in that, The control method further includes: S8. Obtain information indicating that the atomizing matrix replacement is complete; S81. Update the information of the atomizing matrix according to the information that the atomizing matrix replacement is completed; S82. Send the updated atomizing matrix information and the location information of the electronic atomizing device containing the atomizing matrix information to the remote server; S83. The remote server updates according to the updated atomization matrix information and the location information.
9. A control method for a shared electronic atomization system according to claim 8, characterized in that, S83 includes: S831. Compare the updated atomizing matrix information with the preset atomizing matrix information. If the updated atomizing matrix information matches the preset atomizing matrix information, then update the information according to the updated atomizing matrix information and the position information; otherwise, issue an alarm signal.
10. A control method for a shared electronic atomization system according to claim 6, characterized in that, Prior to S6, it also included: S51. Based on the inhalation start signal, detect whether the mouthpiece cover is on the mouthpiece of the electronic atomizing device. When it is detected that the mouthpiece cover is not on the mouthpiece, control the first atomizing component and the second atomizing component to stop working.