WO2024001408A1

WO2024001408A1 - Airflow sensor protection structure, atomizing medium carrier, and electronic atomizer

Info

Publication number: WO2024001408A1
Application number: PCT/CN2023/087418
Authority: WO
Inventors: 徐文凯
Original assignee: 爱奇迹(香港)有限公司
Priority date: 2022-06-30
Filing date: 2023-04-10
Publication date: 2024-01-04
Also published as: CN116035276A

Abstract

An airflow sensor protection structure (131), an atomizing medium carrier and an electronic atomizer. The airflow sensor protection structure (131) is made of an elastic material. The airflow sensor protection structure (131) comprises a protection structure body (1310) and a first protrusion (1312) extending downward from one end of the protection structure body (1310), wherein an accommodation cavity (1320) is provided in the protection structure body (1310), and the accommodation cavity (1320) is configured to accommodate an airflow sensor (130). The airflow sensor protection structure (131) can protect the airflow sensor (130) to allow the electronic atomizer to operate normally.

Description

Microphone protective structure, atomization medium carrier and electronic atomizer

【Technical field】

This application relates to the technical field applied to atomizers, especially microphone protection structures, atomization medium carriers and electronic atomizers.

【Background technique】

There are many reasons for the existing atomizer to cause abnormal function or failure of the microphone. The microphone is used to detect and sense changes in the suction airflow to decide whether to start the atomizer. Abnormal function or failure of the microphone will cause electronic vapor. If the vaporizer does not work properly, it may cause great safety risks.

[Content of the invention]

This application provides a microphone protection structure, an atomization medium carrier and an electronic atomizer to solve the problem of the electronic atomizer not working properly.

In order to solve the above technical problems, the first aspect of this application proposes a microphone protection structure. The microphone protection structure is made of elastic material. The microphone protection structure includes a protection structure main body and one end of the protection structure body. A first protruding portion extends downward, and a receiving cavity is provided in the main body of the protective structure, and the receiving cavity is used to accommodate the microphone.

In order to solve the above technical problems, the second aspect of this application proposes an electronic atomizer. The electronic atomizer includes: a housing; a suction nozzle, the suction nozzle is provided at one end of the housing; an atomization medium A carrier, the atomized medium carrier is installed on a side of the housing close to the suction nozzle; an electronic control component, the electronic control component is installed on a side of the housing away from the suction nozzle, the electric control component The control assembly includes a microphone and a microphone protective structure. The microphone protective structure is made of elastic material. The microphone protective structure includes a protective structure main body and a protective structure body extending from one end of the protective structure main body to the bottom of the housing. The first protruding part has an accommodating cavity in the main body of the protective structure, and the microphone is arranged in the accommodating cavity.

In order to solve the above technical problems, the third aspect of this application proposes an atomization medium carrier. The atomization medium carrier includes: an atomization medium carrier shell; a top air-sealing silica gel and a bottom oil-sealing silica gel. The top air-sealing silica gel Silica gel is provided at one end of the atomized medium carrier housing, and the bottom oil-sealing silica gel is provided at the other end of the atomized medium carrier housing. The top air-sealing silica gel, the bottom oil-sealing silica gel and the An oil storage tank is formed between the atomization medium carrier shells; an atomization core assembly is arranged in the atomization medium carrier shell; the atomization core assembly includes an atomization bracket and a heating device; the atomization bracket An atomization chamber is formed in the middle, and an oil guide groove is provided on the side of the atomization bracket. The atomization chamber is connected to the oil storage bin through the oil guide groove, and the heating device is arranged in the atomization chamber. ; Wherein, the heating device includes a heating wire pin, the heating wire pin passes through the bottom oil sealing silicone, and the heating wire pin is an interference fit with the bottom oil sealing silicone.

In order to solve the above technical problems, the fourth aspect of this application proposes an electronic atomizer. The electronic atomizer includes: an electronic atomizer housing; and a suction nozzle, the suction nozzle is provided on the electronic atomizer. One end of the housing; an atomization medium carrier and an electronic control assembly. The atomization medium carrier is installed on the side of the electronic atomizer housing close to the suction nozzle. The electronic control assembly is installed on the electronic atomizer. The side of the carburetor housing away from the suction nozzle; wherein the atomization medium carrier is the atomization medium carrier of the third aspect, the top air-sealing silica gel is located on the side close to the suction nozzle, and the bottom The oil-sealing silicone is located on the side close to the electronic control component, and the heating wire pin passes through the bottom oil-sealing silicone to the side of the electronic control component to be electrically connected to the electronic control component.

In order to solve the above technical problems, the fifth aspect of this application proposes an electronic atomizer. The electronic atomizer includes: a housing; a suction nozzle, the suction nozzle is provided at one end of the housing; an atomization medium A carrier, the atomized medium carrier is installed on a side of the housing close to the suction nozzle; an electronic control component, the electronic control component is installed on a side of the housing away from the suction nozzle, the electric control component The control component includes a microphone, the surface of which is covered with a nano waterproof and breathable coating.

In order to solve the above technical problems, the sixth aspect of the present application proposes an oil-leakage-proof electronic atomizer. The oil-leakage-proof electronic atomizer includes: a housing; and a suction nozzle, the suction nozzle is arranged on the One end of the housing; an atomization medium carrier and an electronic control component. The atomization medium carrier is installed on the side of the housing close to the suction nozzle. The electronic control component is installed in the housing away from the suction nozzle. One side of the mouth; wherein, oil-absorbing cotton is provided between the atomized medium carrier and the electronic control component.

The beneficial effects of this application are: different from the prior art, this application uses elastic materials to make the microphone protection structure. The microphone protection structure includes a protective structure main body with an accommodation cavity, so the microphone can be placed in the accommodation cavity. Inside the cavity, the microphone can be protected so that the electronic atomizer can work normally.

[Picture description]

Figure 1 is a schematic structural diagram of an embodiment of the microphone protection structure of the present application;

Figure 2 is a schematic cross-sectional view of the microphone protection structure of Figure 1;

Figure 3 is a schematic cross-sectional view of the microphone protection structure of Figure 2 from another perspective;

Figure 4 is a schematic cross-sectional structural diagram of the first embodiment of the electronic atomizer of the present application;

Figure 5 is a detailed schematic partial structural view of an embodiment of the electronic atomizer in Figure 4;

Figure 6 is a schematic detailed view of the partial structure of Figure 5 from another perspective;

Figure 7 is a schematic detailed view of the partial structure of Figure 5 from another perspective;

Figure 8 is a schematic cross-sectional structural diagram of an embodiment of the atomized medium carrier of the present application;

Figures 9a and 9b are schematic assembly structural diagrams of the process of installing the atomization core assembly on the bottom oil-sealing silicone in the atomization medium carrier of the present application;

Figure 10 is a schematic cross-sectional structural diagram of the second embodiment of the electronic atomizer of the present application;

Figure 11 is a schematic cross-sectional structural diagram of the third embodiment of the electronic atomizer of the present application;

Figure 12 is a schematic detailed view of the partial structure of the electronic atomizer in Figure 11;

Figure 13 is a schematic cross-sectional view of A-A in Figure 12;

Figure 14 is a schematic cross-sectional structural diagram of the fourth embodiment of the electronic atomizer of the present application;

Figure 15 is a schematic detailed view of the partial structure of the electronic atomizer in Figure 14;

Figure 16 is a schematic assembly diagram of the fifth embodiment of the electronic atomizer of the present application;

Figure 17 is a schematic cross-sectional structural diagram of the fifth embodiment of the electronic atomizer of the present application.

【Detailed ways】

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. Obviously, the described embodiments are only some of the embodiments of the present application, rather than all of the embodiments. Based on the embodiments in this application, all other embodiments obtained by those of ordinary skill in the art without creative efforts shall fall within the scope of protection of this application.

It should be noted that if there are directional instructions (such as up, down, left, right, front, back...) in the embodiments of the present application, the directional instructions are only used to explain the position of a certain posture (as shown in the accompanying drawings). The relative positional relationship, movement conditions, etc. between the components under the display). If the specific posture changes, the directional indication will also change accordingly.

In addition, if there are descriptions involving “first”, “second”, etc. in the embodiments of this application, the descriptions of “first”, “second”, etc. are only for descriptive purposes and shall not be understood as indications or implications. Its relative importance or implicit indication of the number of technical features indicated. Therefore, features defined as "first" and "second" may explicitly or implicitly include at least one of these features. In addition, the technical solutions in various embodiments can be combined with each other, but it must be based on the realization by those of ordinary skill in the art. When the combination of technical solutions is contradictory or cannot be realized, it should be considered that such a combination of technical solutions does not exist. , nor is it within the scope of protection required by this application.

This application provides a microphone protection structure. Please refer to FIGS. 1 to 3 , wherein FIG. 1 is a schematic structural diagram of an embodiment of the microphone protection structure of the present application, FIG. 2 is a schematic cross-sectional structural diagram of the microphone protection structure of FIG. 1 , and FIG. 3 is a schematic diagram of the microphone protection structure of FIG. 2 A schematic cross-sectional view of the protective structure from another perspective. In this embodiment, the microphone protection structure 131 is made of elastic material. The microphone protection structure 131 includes a protection structure main body 1310 and a self-protection structure main body. A first protruding portion 1312 extends downward from one end of the body 1310. A receiving cavity 1320 is provided in the main body 1310 of the protective structure. The receiving cavity 1320 is used to accommodate the microphone. Preferably, the microphone protective structure 131 may be specifically made of microphone silicone or other elastic materials.

In the microphone protection structure 131 of the embodiment of the present application, the microphone protection structure 131 is made of elastic material. The microphone protection structure 131 includes a protection structure main body 1310 with an accommodation cavity 1320. Therefore, in practical applications, the microphone can be It is arranged in the accommodation cavity 1320 to protect the microphone; during the process of assembling the electronic atomizer, the microphone is first installed in the accommodation cavity 1320 in the microphone protection structure 131, and then the microphone protection structure is 131 and the microphone are installed in the electronic atomizer as a whole, which can not only fix the microphone, but also avoid the squeezing of the microphone by the force generated when the microphone is directly installed without setting the microphone protection structure 131. It will damage the microphone, prevent the microphone from malfunctioning or malfunctioning, and ensure that the electronic atomizer can be used normally and safely. In addition, the microphone protection structure 131 also includes a first protrusion 1312 extending downward from one end of the protection structure main body 1310. Therefore, during the process of installing the microphone protection structure 131 and the microphone as a whole on the electronic atomizer, The first protrusion 1312 can be disposed toward the bottom side of the electronic atomizer, so that there is a certain distance between the bottom of the electronic atomizer and the microphone in the receiving cavity 1320 of the protective structure main body 1310, so that when the electronic atomizer When there is a leakage of atomizing medium (e-liquid and/or condensate) in the atomizer, the atomizing medium will accumulate between the bottom of the electronic atomizer and the main body of the protective structure 1310 without soaking the accommodation cavity 1320 This prevents the atomized medium from soaking the microphone, causing malfunction or malfunction.

Further, the first raised portion 1312 is provided with a first airflow channel 1313. An end of the first raised portion 1312 away from the protective structure main body 1310 has a first channel opening 1314. The first airflow channel 1313 is connected to the accommodation cavity 1320 and the first airflow channel 1313 respectively. A passage opening 1314 is connected. Therefore, the airflow can enter from the first channel opening 1314, and the airflow passing through the first airflow channel 1313 can reach the accommodating cavity 1320, so the microphone in the accommodating cavity 1320 can start the circuit through the movement of the airflow inhaled by the user when suctioning. Thus the circuit controls the operation of the electronic atomizer.

Further, the microphone protective structure 131 also includes a second protruding portion 1315 extending from the protective structure main body 1310 to an end away from the first protruding portion 1312. The second protruding portion 1315 is provided with a second airflow channel 1316. The end of the rising portion 1315 away from the protective structure main body 1310 has a second channel opening 1317, and the second airflow channel 1316 is connected to the accommodation cavity 1320 and the second channel opening 1317 respectively. It can be understood that when the user inhales the electronic atomizer, the airflow flows through the first airflow channel 1313 to the microphone in the accommodating cavity 1320. The microphone starts the circuit through the movement of the airflow, and the airflow passing through the accommodating cavity 1320 Continue to flow along the second airflow channel 1316. Moreover, when the first protruding portion 1312 is provided toward the bottom side of the electronic atomizer, the second protruding portion 1315 is provided toward the top side of the electronic atomizer, and the second protruding portion 1315 is provided such that when the electronic atomizer When the atomization medium in the atomizer leaks and flows to the surface of the microphone protection structure 131 facing away from the bottom of the electronic atomizer, it is difficult to cross the height of the second protruding portion 1315 and cannot enter the second airflow from the second channel opening 1317. The channel 1316 prevents the atomized medium from intruding into the microphone in the accommodating cavity 1320, thereby preventing the atomized medium from soaking the microphone and causing malfunction or malfunction.

This application also provides an electronic atomizer with a microphone protection structure. The electronic atomizer of this application has the microphone protection structure 131 in any of the above embodiments. Please refer to FIG. 4 , which is a schematic cross-sectional structural diagram of an embodiment of the electronic atomizer of the present application. In this embodiment, an electronic atomizer with a microphone protection structure includes an electronic atomizer housing 10, a suction nozzle 11, an atomizing medium carrier 12 and an electronic control assembly 13. The suction nozzle 11 is provided in the electronic atomizer housing. At one end of the body 10, the atomization medium carrier 12 is installed on the side of the electronic atomizer housing 10 close to the suction nozzle 11, and the electronic control component 13 is installed on the side of the electronic atomizer housing 10 away from the suction nozzle 11. The electronic control assembly 13 includes a microphone 130 and a microphone protection structure 131. The microphone protection structure 131 is made of elastic material. The microphone protection structure 131 includes a protection structure main body 1310. The protection structure main body 1310 has an accommodation cavity 1320. The microphone 130 Disposed in the accommodation cavity 1320.

In the electronic atomizer with a microphone protection structure in the embodiment of the present application, by adding a microphone protection structure 131 inside the electronic atomizer, the microphone protection structure 131 includes a protection structure main body 1310 with an accommodation cavity 1320, so that it can By placing the microphone 130 in the accommodation cavity 1320, the protection of the microphone 130 can be achieved; during the process of assembling the electronic atomizer, the microphone 130 is first installed in the accommodation cavity 1320 in the microphone protection structure 131. , and then set the microphone The head protection structure 131 and the microphone 130 are installed in the electronic atomizer as a whole, which can not only fix the microphone 130, but also avoid the force generated when the microphone 130 is directly installed without the microphone protection structure 131. The squeezing of the head 130 will not damage the microphone 130, prevent the microphone 130 from malfunctioning or malfunctioning, and ensure that the electronic atomizer can be used normally and safely.

Further, the electronic atomizer housing 10 includes a top cover 100, a main body tube 101 and a bottom cover 102. The top cover 100 is disposed at the top opening of the main body tube 101 and is fixedly connected to the main body tube 101. The bottom cover 102 is disposed on the main body tube 101. The bottom opening is open and fixedly connected to the main tube 101. The suction nozzle 11 is set on the top cover 100; the microphone protection structure 131 is arranged in the main tube 101 near the bottom cover 102, and the microphone protection structure 131 is fixedly connected to the bottom cover 102. . The main pipe 101 can be a steel pipe or made of other materials. It can be understood that by arranging the microphone 130 in the accommodating cavity 1320, and then fixing the microphone protection structure 131 with the bottom cover 102 to install the microphone 130, the installation of the microphone 130 with the bottom cover is avoided. 102 directly contacts and damages the microphone 130.

Further, the electronic control assembly 13 also includes an electric core 132, which is disposed between the atomization medium carrier 12 and the microphone protection structure 131. The electric core 132 is used to supply power to the atomization medium carrier 12 and the microphone 130. Specifically, the battery core may be an ordinary battery or a rechargeable battery.

Please refer to FIGS. 5 to 7 , wherein FIG. 5 is a detailed schematic view of the partial structure of an embodiment of the electronic atomizer in FIG. 4 , and FIG. 6 is a detailed schematic view of the partial structure of FIG. 5 from another perspective. FIG. 7 is a schematic detailed view of the partial structure of Figure 5 from another perspective. Further, the microphone protection structure 131 includes a first protrusion 1312 extending from one end of the protection structure main body 1310 toward the bottom cover 102 . Specifically, since the microphone protection structure 131 is formed with a first protrusion 1312 extending from one end of the protection structure main body 1310 to the bottom cover 102, the first protrusion 1312 connects the bottom cover 102 with the accommodation cavity 1320 of the protection structure main body 1310. There is a certain distance between the microphones 130 in the atomization medium carrier 12, so after the atomization medium in the atomization medium carrier 12 leaks to the side of the electronic control component 13, the atomization medium will accumulate between the bottom cover 102 and the protective structure main body 1310 , without soaking the microphone 130 in the accommodating cavity 1320, thereby preventing the atomized medium from soaking the microphone 130 and causing malfunction or malfunction.

Further, the first raised portion 1312 is provided with a first airflow channel 1313. An end of the first raised portion 1312 away from the protective structure main body 1310 has a first channel opening 1314. The first airflow channel 1313 is connected to the accommodation cavity 1320 and the first airflow channel 1313 respectively. A channel opening 1314 is connected; the bottom cover 102 is provided with an air inlet 1020, and the first airflow channel 1313 is connected with the air inlet 1020. Therefore, the airflow enters from the air inlet 1020, and the airflow passing through the first airflow channel 1313 can reach the accommodation cavity 1320, so the microphone 130 can start the circuit through the airflow movement of the suction nozzle 11 when the user suctions, thereby controlling the circuit. The atomized medium carrier 12 works.

The internal structure of the receiving cavity 1320 is designed to adapt to the shape of the microphone 130 . It can be understood that since the microphone 130 is assembled in the protective structure main body 1310 of the microphone protective structure 131, and there is a first protrusion 1312 between the protective structure main body 1310 and the bottom cover 102, the inner wall of the first airflow channel 1313 is Step-like structure, so the first protruding part 1312 is step-shaped, so the stepped first protruding part 1312 can suspend the microphone 130 at a certain height from the bottom cover 102, then even if the atomized medium carrier 12 is The atomized medium leaks down and flows to the bottom of the microphone protective structure 131. Because of the step-shaped first protrusion 1312, the atomized medium at the bottom of the microphone protective structure 131 cannot impregnate the lower surface of the microphone 130. .

Optionally, the height of the first protrusion 1312 is greater than or equal to 2 mm. Due to the first protrusion 1312, there is a certain distance between the accommodation cavity 1320 and the bottom of the bottom cover 102, so that a certain amount of atomized medium can be accumulated in the bottom cover 102 without soaking the media in the accommodation cavity 1320. The microphone 130 can prevent the atomized medium from invading the inside of the microphone 130 and prevent the microphone 130 from malfunctioning or malfunctioning. Specifically, the height of the first protruding part 1312 may be 2 mm, 3 mm, 4 mm, 5 mm, 6 mm, 7 mm, 8 mm, or 10 mm, etc.; in addition, when the first protruding part 1312 has a two-step structure, the first protruding part 1312 has a two-step structure. The height H1 of the first step of the raised portion 1312 away from the microphone 130 is greater than the height H2 of the second step of the first raised portion 1312 close to the microphone 130. For example, the height H2 of the second step can be 2 mm, while the height of the first step H1 can be 5mm. Of course, this embodiment does not limit the height of the first protruding portion 1312, which can be determined according to the specifications and dimensions of the actual product, and try to ensure that there is a certain distance between the accommodation cavity 1320 and the bottom of the bottom cover 102. The structure of the atomizer is compact and reasonable.

In one embodiment, the microphone protective structure 131 includes a second protruding portion 1315 extending from the protective structure main body 1310 toward the top cover 100. The second protruding portion 1315 is provided with a second airflow channel 1316. The second protruding portion 1315 One end away from the protective structure main body 1310 has a second channel opening 1317, and the second air flow channel 1316 is connected with the accommodation cavity 1320 and the second channel opening 1317 respectively; the suction nozzle 11 has an air outlet 110, and the atomized medium carrier 12 includes sequentially connected The air inlet pipe 1211, the atomization chamber 1232 and the air outlet pipe 1200. The air outlet pipe 1200 is connected with the air outlet 110, and the air inlet pipe 1211 is connected with the second air flow channel 1316. It can be understood that when the user inhales the electronic atomizer, the airflow enters from the air inlet 1020 of the bottom cover 102, flows through the first airflow channel 1313 to the microphone 130 in the accommodation cavity 1320, and the microphone 130 passes through the airflow. The movement causes the circuit to start, so that the circuit controls the atomization medium carrier 12 to work. The atomization medium in the atomization medium carrier 12 evaporates and vaporizes in the atomization chamber 1232 to form an aerosol; and the airflow passing from the accommodation chamber 1320 continues to flow to the second The air flow channel 1316 then enters the atomization chamber 1232 from the air inlet pipe 1211 of the atomization medium carrier 12 . The aerosol in the atomization chamber 1232 flows along the air outlet tube 1200 to the suction nozzle 11 , and is inhaled by the user from the air outlet 110 of the suction nozzle 11 ; and, the second protrusion 1315 is provided such that when the atomization medium carrier 12 When the atomized medium leaks out and flows to the upper surface of the microphone protection structure 131, it is difficult to cross the height of the second protruding portion 1315 and cannot enter the second airflow channel 1316 from the second channel opening 1317 to avoid the intrusion of the atomized medium. The upper surface of the microphone 130.

Optionally, the second protruding portion 1315 can be configured as a step-like structure. The step-like structure of the second protruding portion 1315 prevents the atomized medium from flowing into the microphone 130 from the top of the microphone protection structure 131 into the accommodation cavity 1320 . the upper surface of the microphone, or into other parts of the microphone. Therefore, by providing the stepped first protrusion 1312 and the second protrusion 1315, it is possible to prevent the atomized medium from intruding into the upper surface of the microphone 130 in the accommodation cavity 1320 from above the microphone protection structure 131, and to avoid The atomized medium invades the lower surface of the microphone 130 from the bottom of the microphone protection structure 131, thereby preventing the atomized medium from eroding the microphone 130 in all directions.

Furthermore, the microphone protection structure 131 is also provided with an overflow hole 1318. In some embodiments, the overflow hole 1318 penetrates the upper surface of the protective structure body 1310 on the side facing the top cover 100 and the lower surface of the side facing the bottom cover 102 . It can be understood that since the microphone 130 is disposed in the accommodation cavity 1320 of the protective structure main body 1310, a second protruding portion 1315 extends from the protective structural main body 1310 toward the top cover 100, and the second protruding portion 1315 is provided with a second The air flow channel 1316 and the second protruding portion 1315 have a second channel opening 1317 at one end away from the protective structure main body 1310. The second air flow channel 1316 is connected to the accommodation cavity 1320 and the second channel opening 1317 respectively. Therefore, when the atomized medium carrier After the atomized medium in 12 leaks to the side of the electronic control component 13, it may flow to the upper surface of the microphone protection structure 131. When the atomized medium accumulates to a certain volume or height, there is a possibility of crossing the second protruding part 1315. height and the possibility of further entering the second airflow channel 1316 from the second channel opening 1317 and flowing along the second airflow channel 1316 to infect the upper surface of the microphone 130; therefore, in order to avoid excessive accumulation on the upper surface of the protective structure main body 1310 If more atomized medium enters the second airflow channel 1316, an overflow hole 1318 can be opened on the protective structure main body 1310. The overflow hole 1318 can directly guide the atomized medium accumulated on the upper surface of the protective structure main body 1310 to the bottom cover. 102 side.

In one embodiment, the microphone protection structure 131 further includes a third protrusion 1319 extending from the main body 1310 of the protection structure toward the top cover 100 . Specifically, the third protruding portion 1319 is located around the periphery of the second protruding portion 1315 . Further, the height of the third protruding portion 1319 is greater than the height of the second protruding portion 1315 . Specifically, since the microphone protective structure 131 has the second protruding portion 1315 and the third protruding portion 1319 extending from the protective structure main body 1310 to the top cover 100, the third protruding portion 1319 can be supported on the battery core 132 toward the direction. One side of the bottom cover 102, and the height difference between the third protrusion 1319 and the second protrusion 1315 causes a certain gap between the second channel opening 1317 and the surface of the battery core 132 on the side facing the bottom cover 102. The distance is convenient for the airflow flowing out of the second airflow channel 1316 to pass.

In one embodiment, as shown in FIG. 6 , the bottom cover 102 includes a cover bottom 1021 opposite to the top cover 100 and a cover side portion 1022 extending from the outer edge of the cover bottom 1021 toward the top cover 100 side. The cover side portion 1022 is snap-fitted with the bottom opening of the main tube 101; the microphone protection structure 131 is provided with at least one support structure on the side close to the cover side 1022. Specifically, at least one support rib 1311 is provided on the side of the protective structure main body 1310 close to the cover side 1022. The support rib 1311 is provided along the circumferential direction of the protective structure main body 1310. The microphone protection structure 131 passes through at least one A support rib 1311 is engaged with the cover side 1022. It can be understood that when the microphone protection structure 131 is installed on the bottom cover 102 as a whole, the support ribs 1311 interfere with the cover side 1022, and the microphone protection structure 131 is engaged with the cover side 1022. At this time, the protection structure The side of the main body 1310 close to the cover side 1022 is not completely in contact with the inner wall of the cover side 1022. That is to say, a gap is formed next to the support rib 1311 to facilitate the removal of the microphone protection structure 131 from the bottom cover 102. The overall installation and disassembly of the microphone protection structure 131 is convenient.

This application provides an atomized medium carrier that prevents oil leakage. Please refer to FIG. 8 , which is a schematic cross-sectional structural diagram of an embodiment of the atomized medium carrier of the present application. In this embodiment, the atomization medium carrier 12 includes an atomization medium carrier shell 125, a top air-sealing silica gel 120, a bottom oil-sealing silica gel 121 and an atomization core assembly 123; the top air-sealing silica gel 120 is provided in the atomization medium carrier shell One end of the body 125, the bottom oil sealing silica gel 121 is arranged at the other end of the atomization medium carrier shell 125, and an oil storage tank 122 is formed between the top air sealing silica gel 120, the bottom oil sealing silica gel 121 and the atomization medium carrier shell 125 ; The atomization core assembly 123 is arranged in the atomization medium carrier shell 125. The atomization core assembly 123 includes an atomization bracket 1230 and a heating device 1231. An atomization chamber 1232 is formed in the middle of the atomization bracket 1230. There is an oil guide groove 1233 on the side. The atomization chamber 1232 is connected with the oil storage bin 122 through the oil guide groove 1233. The heating device 1231 is arranged in the atomization chamber 1232; among them, the heating device 1231 includes a heating wire pin 1234. The heating wire pin 1234 passes through the bottom oil sealing silicone 121, and the heating wire pin 1234 has an interference fit with the bottom oil sealing silicone 121.

In the atomized medium carrier 12 of the embodiment of the present application, by passing the heating wire pin 1234 through the bottom oil sealing silicone 121, the heating wire pin 1234 interferes with the bottom oil sealing silicone 121, so that the heating wire pin 1234 is in contact with the bottom oil sealing silicone 121. There is no gap in the position where the heating wire pin 1234 passes through on the oil sealing silicone 121, so the e-liquid in the atomization medium carrier 12 will not leak out along the position where the heating wire pin 1234 passes through on the bottom oil sealing silicone 121. This prevents smoke oil from leaking to the side of the electronic control component in the electronic atomizer composed of the atomizing medium carrier 12 and the electronic control component, prevents the electronic control component from malfunctioning or malfunctioning, and provides technical support for the normal use of the electronic atomizer. .

Further, please combine Figure 9a and Figure 9b. Figure 9a and Figure 9b are schematic assembly structure diagrams of the process of installing the atomization core assembly on the bottom oil sealing silica gel in the atomization medium carrier of the present application. The bottom oil sealing silica gel 121 is provided with a blind Hole 1210, during the process of installing the atomizer core assembly 123 on the bottom oil sealing silicone 121, insert the heating wire pin 1234 into and pass through the bottom 12100 of the blind hole 1210. It can be understood that before installation, the bottom oil sealing silica gel 121 is provided with a blind hole 1210. The blind hole 1210 is a non-penetrating hole. Then during the process of installing the atomizing core assembly 123 on the bottom oil sealing silica gel 121, By inserting the heating wire pin 1234 into and passing through the bottom 12100 of the blind hole 1210, there is an interference fit between the bottom 12100 of the blind hole 1210 and the heating wire pin 1234, and there is an interference fit between the heating wire pin 1234 and the blind hole 1210. There is no gap at the contact position of the bottom 12100, so the smoke oil on the side of the atomization medium carrier 12 will not leak out along the pierced blind hole 1210, ensuring the sealing of the atomization medium carrier 12.

In one embodiment, the heating device 1231 includes a mesh heating sheet or a spring-shaped heating wire. Specifically, two blind holes 1210 are provided on the bottom oil-sealing silicone 121. The mesh heating sheet or the spring-shaped heating wire has two heating wire pins 1234. The two heating wire pins 1234 are inserted into their respective blind holes. hole 1210, and penetrates toward the side of the bottom oil-sealing silicone 121 away from the top air-sealing silicone 120, so that the closed part formed by the bottom 12100 of the blind hole 1210 will be closely connected with the periphery of the heating wire pin 1234 that passes through The close contact can effectively prevent the e-liquid from flowing out of the atomization medium carrier 12 along the heating wire pin 1234.

In a preferred embodiment, the position where the bottom oil-sealing silicone 121 contacts the heating wire pin 1234 is coated with an oil-proof coating (not shown). It can be understood that after the heating wire pin 1234 is inserted into and passed through the bottom 12100 of the blind hole 1210, an oil-proof coating is applied to the position where the bottom oil-sealing silicone 121 contacts the heating wire pin 1234. The oil-proof coating The layer can further prevent e-liquid from flowing out of the atomization medium carrier 12 along the heating wire pin 1234.

In one embodiment, the oil storage tank 122 is filled with oil storage cotton 124. The oil storage cotton 124 is used to store e-liquid. The oil storage cotton 124 is wrapped around the atomization bracket 1230. It can be understood that since the oil storage cotton 124 is wrapped around the atomization bracket 1230, the e-liquid stored in the oil storage cotton 124 can reach the atomization chamber 1232 through the oil guide groove 1233 opened on the side of the atomization bracket 1230.

Further, the atomization core assembly 123 also includes an oil-conducting cotton 1235. The oil-conducting cotton 1235 is wrapped around the heating device 1231. On the outside, the oil-conducting cotton 1235 covers the oil-conducting groove 1233, ensuring that the e-liquid reaching the heating device 1231 passes through the oil-conducting cotton 1235, resulting in a more uniform oil speed and a more delicate taste. Specifically, the smoke oil stored in the oil storage cotton 124 is transferred to the oil guide cotton 1235 through the oil guide groove 1233, and the oil guide cotton 1235 is wrapped around the outside of the heating device 1231, so the smoke oil in the oil guide cotton 1235 is in contact with the heating device. Smoke can be formed when the heating device 1231 comes into contact.

This application also provides an electronic atomizer that prevents oil leakage. Please refer to Figure 10. Figure 8 is a schematic cross-sectional structural diagram of an embodiment of the electronic atomizer of the present application. In this embodiment, the electronic atomizer includes an electronic atomizer housing 10, a nozzle 11, an atomizing medium carrier 12 and an electronic control component 13, where the atomizing medium carrier is the atomizing medium carrier in any of the above embodiments. 12. Specifically, the suction nozzle 11 is provided at one end of the electronic atomizer housing 10 , the atomizing medium carrier 12 is installed on the side of the electronic atomizer housing 10 close to the suction nozzle 11 , and the electronic control component 13 is installed on the electronic atomizer housing 10 . The side of the device housing 10 away from the suction nozzle 11; the top air-sealing silica gel 120 of the atomization medium carrier 12 is located on the side close to the suction nozzle 11, and the bottom oil-sealing silica gel 121 of the atomization medium carrier 12 is located close to the electronic control component 13. On the side, an oil storage tank 122 is formed between the top air-sealing silica gel 120 and the bottom oil-sealing silica gel 121; the atomization core assembly 123 includes an atomization bracket 1230 and a heating device 1231, and an atomization chamber 1232 is formed in the middle of the atomization bracket 1230. An oil guide groove 1233 is provided on the side of the atomization bracket 1230. The atomization chamber 1232 is connected with the oil storage bin 122 through the oil guide groove 1233. The heating device 1231 is arranged in the atomization chamber 1232; wherein the heating device 1231 includes a heating wire pin 1234. , the heating wire pin 1234 passes through the bottom oil sealing silicone 121 to the side of the electronic control component 13 to be electrically connected to the electronic control component 13. The heating wire pin 1234 has an interference fit with the bottom oil sealing silicone 121.

In the electronic atomizer of the embodiment of the present application, by passing the heating wire pin 1234 through the bottom oil sealing silicone 121 to the side of the electronic control component 13, the heating wire pin 1234 interferes with the bottom oil sealing silicone 121 to generate heat. There is no gap between the wire pin 1234 and the position on the bottom oil-sealing silicone 121 for the heating wire pin 1234 to pass through, so the oil smoke in the atomized medium carrier 12 will not pass along the heating wire pin 1234 on the bottom oil-sealing silicone 121 The passed position leaks to the side of the electronic control component 13 to avoid malfunction or malfunction of the electronic control component 13 and ensure that the electronic atomizer can be used normally and safely.

Further, the electronic atomizer housing 10 includes a top cover 100, a main body tube 101 and a bottom cover 102. The top cover 100 is disposed at the top opening of the main body tube 101 and is fixedly connected to the main body tube 101. The bottom cover 102 is disposed on the main body tube 101. The bottom is open and fixedly connected to the main body tube 101, and the suction nozzle 11 is arranged on the top cover 100. The main pipe 101 can be a steel pipe or made of other materials.

Specifically, the suction nozzle 11 has an air outlet 110, the bottom cover 102 is provided with an air inlet 1020, the top air sealing silica gel 120 is provided with a penetrating air outlet pipe 1200, the air outlet pipe 1200 is connected with the air outlet 110, and the bottom oil sealing silica gel 121 is provided with an air outlet 110. A penetrating air inlet pipe 1211 is provided. The air inlet pipe 1211 is connected to the air inlet 1020. The two ends of the atomization bracket 1230 are connected to the top air sealing silica gel 120 and the bottom oil sealing silica gel 121 respectively. The atomization chamber 1232 is connected to the air outlet pipe 1200 and 121 respectively. The intake pipe 1211 is connected. It can be understood that when the user inhales the anti-leakage electronic atomizer in the embodiment of the present application, air flow will be generated. The air flow enters from the air inlet 1020 at the bottom and passes through the air inlet pipe 1211 on the bottom oil sealing silicone 121 After entering the atomization chamber 1232, the smoke in the atomization chamber 1232 reaches the suction nozzle 11 along the air outlet tube 1200 on the top air-sealing silica gel 120, and is inhaled by the user from the air outlet 110 of the suction nozzle 11.

Furthermore, an accommodating groove 1201 is formed on the side of the top air-sealing silicone 120 facing the top cover 100, and an oil-absorbing cotton 14 is disposed in the accommodating groove 1201. By disposing the oil-absorbing cotton 14 between the top air-sealing silica gel 120 and the suction nozzle 11, the e-liquid flowing out through the air outlet pipe 1200 on the top air-sealing silica gel 120 can be absorbed by the oil-absorbing cotton 14, thereby preventing the unvaporized e-liquid from passing through the suction pipe. The mouth 11 is sucked in by the user.

Further, the electronic control component 13 includes a battery core 132 and a microphone 130. The microphone 130 is disposed on the side close to the bottom cover 102. The battery core 132 is disposed between the bottom sealing oil silicone 121 and the microphone 130. The battery core 132 is used for Supply power to the atomized medium carrier 12 and the microphone 130. It can be understood that by passing the heating wire pin 1234 through the bottom oil sealing silicone 121 to the side of the electronic control component 13, the heating wire pin 1234 interferes with the bottom oil sealing silicone 121, so that the heating wire pin 1234 is in contact with the bottom oil sealing silicone 121. There is no gap at the position where the heating wire pin 1234 passes through on the oil-sealing silicone 121, so the oil smoke in the atomized medium carrier 12 will not leak to the electricity along the position where the heating wire pin 1234 passes through on the bottom oil-sealing silicone 121. Control component 13 side, especially will not flow to the microphone 130, to avoid abnormal function or failure of the microphone 130. Ensure that the electronic atomizer can be used normally and safely.

Therefore, when the user inhales the oil-leakage-proof electronic atomizer, the airflow passes through the microphone 130 from the air inlet 1020 at the bottom. The microphone 130 starts the circuit through the movement of the airflow, so that the circuit controls the heating device 1231 to start heating and store oil. The e-liquid in the warehouse 122 is transferred from the oil storage cotton 124 to the oil-conducting cotton 1235. The heating device 1231 evaporates and gasifies the e-liquid in contact with the oil-conducting cotton 1235 in the atomization chamber 1232 to form smoke; The airflow entering from the air inlet 1020 at the bottom enters the atomization chamber 1232 through the air inlet pipe 1211 on the bottom oil sealing silica gel 121, and the smoke in the atomization chamber 1232 is along the air outlet pipe 1200 on the top air sealing silica gel 120. It is brought out to the suction nozzle 11 and inhaled by the user from the air outlet 110 of the suction nozzle 11 .

This application provides an electronic atomizer that prevents smoke oil from intruding into the microphone. Please refer to Figure 11. Figure 11 is a schematic cross-sectional structural view of an electronic atomizer that prevents e-liquid from intruding into the microphone according to an embodiment of the present application. In this embodiment, the electronic atomizer that prevents e-liquid from intruding into the microphone includes an electronic atomizer housing 10, a suction nozzle 11, an atomization medium carrier 12 and an electronic control assembly 13. The suction nozzle 11 is provided on the electronic atomizer. At one end of the housing 10, the atomization medium carrier 12 is installed on the side of the electronic atomizer housing 10 close to the suction nozzle 11, and the electronic control assembly 13 is installed on the side of the electronic atomizer housing 10 away from the suction nozzle 11. , the electronic control component 13 includes a microphone 130, and the surface of the microphone 130 is covered with a nano waterproof and breathable coating (not shown).

In the electronic atomizer that prevents e-liquid from intruding into the microphone according to the embodiment of the present application, the surface of the microphone 130 is coated with a nano waterproof and breathable coating, so that the e-liquid on the atomization medium carrier 12 side leaks to the electronic control component 13 - When used on the side, the nano waterproof and breathable coating can prevent e-liquid from invading the inside of the microphone 130, prevent the microphone 130 from malfunctioning or malfunctioning, and ensure that the electronic atomizer can be used normally and safely.

In order to facilitate understanding of the embodiments of the present application, tests were conducted on existing microphones without nano-waterproof and breathable coatings on their surfaces and the microphone 130 of the present application whose surface is covered with nano-waterproof and breathable coatings. The test results are as follows: after powering on. When immersed in tap water, existing microphones without nano-waterproof and breathable coatings on their surfaces will become ineffective after the immersion time reaches 2 to 5 minutes. However, the microphone 130 of the present application whose surface is coated with nano-waterproof and breathable coatings will After the immersion time reaches 10 to 11 hours, it can still work normally; however, when immersed in e-liquid after being powered on, the existing microphones that do not have nano-waterproof and breathable coatings on their surfaces will fail after the immersion time reaches 2 to 3 hours. However, the microphone 130 covered with a nanometer waterproof and breathable coating in this application can still work normally after the immersion time reaches 202 hours.

It can be found that the oil drop angle, water drop angle, and e-liquid infiltration on the surface of the microphone 130 coated with a nano-waterproof and breathable coating of the present application are significantly improved. By increasing the surface contact angle of the microphone 130, the e-liquid and e-liquid infiltration are effectively reduced. The penetration of water vapor and the like into the microphone 130 and the condensation on the surface can inhibit the siphon effect, thereby protecting the microphone 130 of the electronic atomizer and the internal components of the microphone 130 .

Further, the electronic control component 13 also includes an electric core 132. The microphone 130 is arranged on the side close to the bottom cover 102. The electric core 132 is arranged between the atomizing medium carrier 12 and the microphone 130. The electric core 132 is used for atomizing. Media carrier 12 and microphone 130 are powered. It can be understood that when the oil fume in the atomized medium carrier 12 leaks to the electronic control component 13 side, even if it flows onto the microphone 130, it will be blocked by the nano waterproof and breathable coating covering the surface of the microphone 130, which can be avoided. Microphone 130 is malfunctioning or malfunctioning.

Please refer to Figure 12. Figure 12 is a detailed schematic diagram of the partial structure of the electronic atomizer in Figure 11 that prevents e-liquid from intruding into the microphone. In this embodiment, the bottom cover 102 protrudes toward the top cover 100 to form a support column 2021. The support column 2021 and the inner surface of the bottom cover 102 form a liquid reservoir 2022. The microphone 130 is disposed on the support column 2021. Specifically, since the bottom cover 102 protrudes toward the top cover 100 to form a support column 2021, the support column 2021 and the inner surface of the bottom cover 102 form a liquid reservoir 2022, and the microphone 130 is disposed on the support column 2021, such as a microphone. The head 130 is specifically located at an end of the support column 2021 away from the liquid reservoir 2022, so the oil fume in the atomized medium carrier 12 leaks to the electronic control component 13 After being turned aside, the smoke will accumulate in the liquid reservoir 2022 without contacting the microphone 130 on the support column 2021, thus preventing the microphone 130 from being soaked in smoke oil and causing malfunction or malfunction.

Specifically, the bottom cover 102 is provided with an air inlet 1020, and the support column 2021 is provided with an air flow channel 1023. One end of the support column 2021 away from the bottom cover 102 has a channel opening 1024. The two ends of the air flow channel 1023 are connected to the air inlet 1020 and the channel respectively. The opening 1024 is connected, and the microphone 130 is arranged on the path of the air flow channel 1023; the suction nozzle 11 has an air outlet 110, and the atomization medium carrier 12 includes an air inlet pipe 1211, an atomization chamber 1232 and an air outlet pipe 1200 that are connected in sequence. The air outlet pipe 1200 and The air outlet 110 is connected, and the air inlet pipe 1211 is connected with the air flow channel 1023. It can be understood that when the user inhales the electronic atomizer, the airflow enters from the air inlet 1020 of the bottom cover 102 and flows to the microphone 130 through the airflow channel 1023. The microphone 130 realizes circuit activation through airflow movement, thereby controlling the circuit. When the atomization medium carrier 12 works, the smoke oil in the atomization medium carrier 12 evaporates and vaporizes in the atomization chamber 1232 to form smoke; while the airflow passing through the airflow channel 1023 continues to flow, and flows from the air inlet pipe 1211 of the atomization medium carrier 12 Entering the atomization chamber 1232, the smoke in the atomization chamber 1232 is brought out along the air outlet pipe 1200 to the suction nozzle 11, and is inhaled by the user from the air outlet 110 of the suction nozzle 11.

Please refer to Figures 11 to 13, where Figure 13 is a schematic cross-sectional view along line A-A in Figure 12. In one embodiment, the microphone 130 is disposed in the airflow channel 1023 . By installing the microphone 130 in the air flow channel 1023, the user can trigger the operation of the microphone 130 by inhaling air into the air flow channel 1023 while using the electronic atomizer. At the same time, due to the surface coating of the microphone 130 The nano waterproof and breathable coating makes it difficult for the liquid outside the electronic atomizer to enter the inside of the electronic atomizer through the air inlet 1020 and the air flow channel 1023, thereby effectively ensuring the safety and reliability of the microphone 130 and the electronic atomizer.

Furthermore, at least one support rib 1025 is provided on the inner wall side of the air flow channel 1023 , and the support rib 1025 is provided along the extension direction of the air flow channel 1023 . It can be understood that the support ribs 1025 are used to support the microphone 130 installed in the air flow channel 1023, so that the outer wall of the microphone 130 installed in the air flow channel 1023 does not completely contact the inner wall of the air flow channel 1023, that is, That is, a gap 1026 is formed next to the support rib 1025. At the gap 1026, the outer wall of the microphone 130 and the inner wall of the airflow channel 1023 will form a non-contact state, so it is convenient to install the microphone 130 in the airflow channel 1023. It is convenient to take out the microphone 130 from the air flow channel 1023, making the installation and removal of the microphone 130 easy.

Further, there are multiple support ribs 1025 , and the multiple support ribs 1025 are evenly arranged along the circumferential direction of the airflow channel 1023 . Specifically, the number of support ribs 1025 can be 3, 4, 5 or others. Therefore, a gap 1026 is formed between two adjacent support ribs 1025. When the height of the e-liquid in the liquid storage tank 2022 is higher than the support column At 2021, the e-liquid will overflow the liquid storage tank 2022 and flow from the channel opening 1024 of the air flow channel 1023 to the air inlet 1020. At this time, these gaps 1026 can also be used as overflow tanks, and the overflowing e-liquid will flow out from these gaps 1026. The microphone 130 will not be soaked, which can prevent the microphone 130 from being soaked in e-liquid and causing malfunction or malfunction.

Please refer to Figures 14 and 15. Figure 14 is a schematic cross-sectional structural diagram of another embodiment of the electronic atomizer of the present application that prevents e-liquid from intruding into the microphone. Figure 15 is a schematic diagram of the electronic atomizer that prevents e-liquid from invading the microphone in Figure 14. Detailed schematic diagram of the partial structure of the electronic atomizer. In one embodiment, the microphone 130 is disposed at the channel opening 1024 . It can be understood that by installing the microphone 130 at the channel opening 1024 of the air flow channel 1023, the installation and disassembly of the microphone 130 is facilitated; in addition, there is a maximum installation height between the microphone 130 and the bottom of the liquid reservoir 2022. Poor, so that the microphone 130 will not be easily soaked by the e-liquid in the liquid reservoir 2022.

Further, the distance between the channel opening 1024 and the bottom of the liquid reservoir 2022 is greater than 1 mm. There is a certain distance between the channel opening 1024 of the airflow channel 1023 and the bottom of the liquid storage tank 2022, so that a certain amount of e-liquid can accumulate in the liquid storage tank 2022 without soaking the microphone 130, and the e-liquid can be prevented from invading the inside of the microphone 130. , to prevent the microphone 130 from malfunctioning or malfunctioning. Optionally, the distance between the channel opening 1024 and the bottom of the liquid reservoir 2022 may be 1.5 mm, 2 mm, 2.5 mm, 3 mm, 5 mm or 8 mm, etc. Of course, this embodiment does not limit the distance between the channel opening 1024 and the liquid reservoir 2022 The height difference between the bottoms of the electronic atomizer can be determined according to the specifications and dimensions of the actual product. It is enough to ensure that the structure of the electronic atomizer is compact and reasonable while ensuring that the channel opening 1024 is higher than the bottom of the liquid storage tank 2022.

In the electronic atomizer of the present application that prevents e-liquid from intruding into the microphone, the surface of the microphone 130 is coated with a nano waterproof and breathable coating, so that the e-liquid on the atomization medium carrier 12 side leaks to the electronic control component 13 side. This prevents e-liquid from invading the inside of the microphone 130, prevents the microphone 130 from functioning abnormally or malfunctioning, and ensures that the electronic atomizer can be used normally and safely.

This application provides an electronic atomizer that prevents oil leakage. Please refer to Figures 16 and 17. Figure 16 is a schematic assembly diagram of an embodiment of the electronic atomizer of the present application, and Figure 17 is a schematic cross-sectional structural diagram of an embodiment of the electronic atomizer of the present application. In this embodiment, the electronic atomizer includes an electronic atomizer housing 10, a suction nozzle 20, an atomizing medium carrier 30 and an electronic control assembly 40. The suction nozzle 20 is provided at one end of the electronic atomizer housing 10, and the atomizer The atomizing medium carrier 30 is installed on the side of the electronic atomizer housing 10 close to the suction nozzle 20, and the electronic control assembly 40 is installed on the side of the electronic atomizer housing 10 away from the suction nozzle 20; wherein, the atomizing medium carrier Oil-absorbing cotton 50 is provided between 30 and the electronic control assembly 40.

It can be understood that the oil-absorbing cotton 50 is made of fiber material, such as polymer cotton. Polymer cotton has the characteristics of fast oil absorption and large oil absorption capacity. The oil absorption capacity is 10 times as much as that of ordinary oil-absorbing cotton. Therefore, by disposing the oil-absorbing cotton 50 between the atomization medium carrier 30 and the electronic control assembly 40 of the electronic atomizer, when the atomization medium in the atomization medium carrier 30 leaks to the side of the electronic control assembly 40, the atomization The medium will be absorbed by the oil-absorbing cotton 50 and will not leak to the electronic control component 40, thereby preventing the electronic control component 40 from malfunctioning or malfunctioning, and ensuring that the electronic atomizer can be used normally and safely.

Please refer to Figures 16, 17, and Figures 9a and 9b, wherein Figures 9a and 9b can be used as a schematic assembly structure diagram of the process of installing the atomizer core component in the bottom oil-sealing silicone of the electronic atomizer in Figure 17. Further, in the electronic atomizer, the atomization medium carrier 30 includes the atomization core assembly 123, the top air-sealing silica gel 301 on the side near the nozzle 20, and the bottom oil-sealing silica gel 121 on the side near the electronic control component 40. The top An oil storage tank 303 is formed between the air-sealing silica gel 301 and the bottom oil-sealing silica gel 121; the atomization core assembly 123 includes an atomization bracket 1230 and a heating device 1231. An atomization chamber 1232 is formed in the middle of the atomization bracket 1230. There is an oil guide groove 1233 on the side of 1230. The atomization chamber 1232 is connected with the oil storage bin 303 through the oil guide groove 1233. The heating device 1231 is arranged in the atomization chamber 1232; among them, the heating device 1231 includes a heating wire pin 1234. The pin 1234 passes through the bottom oil sealing silicone 121 to one side of the electronic control component 40 to be electrically connected to the electronic control component 40. The heating wire pin 1234 has an interference fit with the bottom oil sealing silicone 121. It can be understood that by passing the heating wire pin 1234 through the bottom oil sealing silicone 121 to the side of the electronic control component 40, the heating wire pin 1234 interferes with the bottom oil sealing silicone 121, so that the heating wire pin 1234 is in contact with the bottom oil sealing silicone 121. There is no gap at the position where the heating wire pin 1234 passes through on the oil sealing silicone 121, so the atomization medium in the atomization medium carrier 30 will not leak along the position where the heating wire pin 1234 passes through on the bottom oil sealing silicone 121. to the electronic control component 40 side to prevent the oil-absorbing cotton 50 from absorbing too much atomized medium and causing the excess atomized medium to still flow to the electronic control component 40, further ensuring that the electronic control component 40 will not malfunction or malfunction. Electronic atomizers can be used normally and safely.

Specifically, the bottom oil-sealing silicone 121 is provided with a blind hole 1210. During the installation of the atomizer core assembly 123 on the bottom oil-sealing silicone 121, the heating wire pin 1234 is inserted into and passed through the bottom of the blind hole 1210. 12100 to the electronic control component 40 side. It can be understood that before installation, the bottom oil sealing silica gel 121 is provided with a blind hole 1210. The blind hole 1210 is a non-penetrating hole. Then during the process of installing the atomizing core assembly 123 on the bottom oil sealing silica gel 121, By inserting and passing the heating wire pin 1234 through the bottom 12100 of the blind hole 1210 to the side of the electronic control component 40, there is an interference fit between the bottom 12100 of the blind hole 1210 and the heating wire pin 1234. There is no gap at the contact position between the foot 1234 and the bottom 12100 of the blind hole 1210, so the atomization medium on the side of the atomization medium carrier 30 will not leak to the electronic control component 40 along the pierced blind hole 1210, ensuring atomization. The sealing property of the media carrier 30.

In one embodiment, the heating device 1231 includes a mesh heating sheet or a spring-shaped heating wire. Specifically, two blind holes 1210 are provided on the bottom oil-sealing silicone 121. The mesh heating sheet or the spring-shaped heating wire has two heating wire pins 1234. The two heating wire pins 1234 are inserted into their respective blind holes. hole 1210, and penetrates toward the side of the electronic control component 40, so that the closed part formed by the bottom 12100 of the blind hole 1210 will contact with the passing heating wire pin. The periphery of 1234 is in close contact, which can effectively prevent the atomized medium from flowing out along the heating wire pin 1234 toward the electronic control component 40 side.

In a preferred embodiment, the position where the bottom oil-sealing silicone 121 contacts the heating wire pin 1234 is coated with an oil-proof coating (not shown). It can be understood that after the heating wire pin 1234 is inserted into and passed through the bottom 12100 of the blind hole 1210 to the side of the electronic control component 40, an anti-corrosive coating is applied at the position where the bottom oil sealing silicone 121 contacts the heating wire pin 1234. The oil coating and the oil-proof coating can further prevent the atomized medium from flowing out along the heating wire pin 1234 toward the electronic control component 40 side.

Please refer to Figures 16, 17, 3, 5 to 7. Figure 5 can be used as a schematic detailed view of the partial structure of an embodiment of the electronic atomizer in Figure 17, and Figure 6 can be used as a detailed view of the partial structure of the electronic atomizer in Figure 17. Figure 7 can be used as a schematic detailed view of the partial structure of Figure 5 from another perspective. Figure 3 can be used as a microphone protection structure of an embodiment of the electronic atomizer in Figure 17 schematic details. Further, the electronic control assembly 40 includes a microphone 130 and a microphone protection structure 401. The microphone protection structure 401 includes a protection structure main body 1310. The protection structure main body 1310 has an accommodating cavity 4011, and the microphone 130 is disposed in the accommodating cavity 4011. Preferably, the microphone protective structure 401 may be made of microphone silicone or other elastic materials. It can be understood that by adding a microphone protection structure 401 inside the electronic atomizer, the microphone protection structure 401 includes a protection structure main body 1310 with an accommodating cavity 4011, so the microphone 130 can be disposed in the accommodating cavity 4011, The microphone 130 is protected by the microphone protection structure 401; during the process of assembling the electronic atomizer, the microphone 130 is first installed in the accommodation cavity 4011 in the microphone protection structure 401, and then the microphone protection structure is 401 and the microphone 130 are installed in the electronic atomizer as a whole, which can not only fix the microphone 130, but also avoid the force generated when the microphone 130 is directly installed without the microphone protection structure 401. Squeezing will not damage the microphone 130, prevent the microphone 130 from malfunctioning or malfunctioning, and ensure that the electronic atomizer can be used normally and safely.

Further, the electronic atomizer housing 10 includes a top cover 100, a main body tube 101 and a bottom cover 102. The top cover 100 is disposed at the top opening of the main body tube 101 and is connected to the main body tube 101. The bottom cover 102 is disposed at the top of the main body tube 101. The bottom is open and connected to the main body tube 101, and the suction nozzle 20 is arranged on the top cover 100; the electronic control assembly 40 also includes a battery core 402, which is arranged between the atomization medium carrier 30 and the microphone protection structure 401. 402 is used to supply power to the atomized medium carrier 30 and the microphone 130. The battery core 402 can be an ordinary battery or a rechargeable battery. The microphone protection structure 401 is arranged on the side close to the bottom cover 102. The microphone protection structure 401 and the bottom cover 102 fixed connection. The main pipe 101 can be a steel pipe or made of other materials. It can be understood that by disposing the microphone 130 in the accommodation cavity 4011, and then fixing the microphone 130 with the bottom cover 102 through the microphone protection structure 401, the microphone protection structure 401 avoids the need to install the microphone. 130, it comes into direct contact with the bottom cover 102 and damages the microphone 130.

In addition, the oil-absorbing cotton 50 located between the atomized medium carrier 30 and the electronic control component 40 can be installed on the side of the battery core 402 facing the atomized medium carrier 30 through single-sided adhesive tape, so that the atomized medium carrier 30 When the atomized medium leaks out, the atomized medium is directly absorbed by the oil-absorbing cotton 50 and will not flow to the electronic control component 40.

In one embodiment, the microphone protective structure 401 includes a first protrusion 1312 extending from the protective structure main body 1310 toward the bottom cover 102 side. Specifically, since the microphone protection structure 401 is formed with a first protrusion 1312 extending from the protection structure main body 1310 to the bottom cover 102 side, the first protrusion 1312 makes the accommodation cavity between the bottom cover 102 and the protection structure main body 1310 There is a certain distance between the microphones 130 in the 4011, so if the atomization medium in the atomization medium carrier 30 leaks too much and causes the oil-absorbing cotton 50 to be saturated, the excess atomization medium will leak to the electronic control component 40 One side, and accumulates between the bottom cover 102 and the protective structure main body 1310 without soaking the microphone 130 in the accommodation cavity 4011, thereby preventing the atomized medium from soaking the microphone 130 and causing malfunction or malfunction.

Further, the first raised portion 1312 is provided with a first airflow channel 1313. An end of the first raised portion 1312 away from the protective structure main body 1310 has a first channel opening 1314. The first airflow channel 1313 is connected to the accommodation cavity 4011 and the first airflow channel 1313 respectively. A channel opening 1314 is connected; the bottom cover 102 is provided with an air inlet 1020, and the first airflow channel 1313 is connected with the air inlet 1020. Therefore, the airflow enters from the air inlet 1020, and the airflow passing through the first airflow channel 1313 can reach the accommodation cavity 4011, so the microphone 130 can start the circuit through the airflow movement of the suction nozzle 20 when the user suctions, thereby controlling the circuit. The atomized medium carrier 30 works. It is understandable that since the microphone 130 is assembled In the protection structure main body 1310 of the microphone protection structure 401, there is a first protrusion 1312 between the protection structure main body 1310 and the bottom cover 102. The inner wall of the first airflow channel 1313 is a step-like structure, that is, the first protrusion. 1312 is stepped, so the stepped first protrusion 1312 can suspend the microphone 130 at a certain height from the bottom cover 102, so even if the atomized medium in the atomized medium carrier 30 leaks down and flows to the microphone Due to the arrangement of the stepped first protrusion 1312 at the bottom of the microphone protection structure 401 , the atomized medium at the bottom of the microphone protection structure 401 cannot impregnate the lower surface of the microphone 130 .

Optionally, the height of the first protrusion 1312 is greater than or equal to 2 mm. Due to the first protrusion 1312, there is a certain distance between the accommodation cavity 4011 and the bottom of the bottom cover 102, so that a certain amount of atomized medium can be accumulated in the bottom cover 102 without soaking the media in the accommodation cavity 4011. The microphone 130 can prevent the atomized medium from invading the inside of the microphone 130 and prevent the microphone 130 from malfunctioning or malfunctioning. Specifically, the height of the first protruding part 1312 may be 2 mm, 4 mm, 5 mm, 6 mm, 7 mm, 8 mm, or 10 mm, etc.; in addition, when the first protruding part 1312 has a two-level step structure, the height of the first protruding part 1312 The height H1 of the first step of 1312 away from the microphone 130 is greater than the height H2 of the second step of the first protrusion 1312 close to the microphone 130. For example, the height H2 of the second step can be 3 mm, and the height H1 of the first step can be is 7mm. Of course, this embodiment does not limit the height of the first protrusion 1312, which can be determined according to the specifications and dimensions of the actual product, and try to ensure that there is a certain distance between the accommodation cavity 4011 and the bottom of the bottom cover 102. The structure of the atomizer is compact and reasonable.

In one embodiment, the microphone protection structure 401 includes a second protrusion 1315 extending from the main body 1310 of the protection structure toward the top cover 100. The second protrusion 1315 is provided with a second airflow channel 1316. The end of the portion 1315 away from the main body 1310 of the protective structure has a second channel opening 1317, and the second air flow channel 1316 is connected to the accommodation cavity 4011 and the second channel opening 1317 respectively; the suction nozzle 20 has an air outlet 200, and is provided on the top air-sealing silicone 301 There is a penetrating air outlet pipe 3010, which is connected with the air outlet 200. The bottom oil-sealing silicone 121 is provided with a penetrating air inlet pipe 3021. The air inlet pipe 3021 is connected with the second air flow channel 1316. The two ends of the atomization bracket 1230 are respectively connected with the air outlet 200. The top air-sealing silica gel 301 and the bottom oil-sealing silica gel 121 are connected, and the atomization chamber 1232 is connected to the air outlet pipe 3010 and the air inlet pipe 3021 respectively.

Further, the oil storage tank 303 is filled with oil storage cotton 304. The oil storage cotton 304 is used to store the atomization medium. The oil storage cotton 304 is wrapped around the atomization bracket 1230; because the oil storage cotton 304 is wrapped around the atomization bracket 1230, 1230 , the atomized medium stored in the oil storage cotton 304 can reach the atomization chamber 1232 through the oil guide groove 1233 opened on the side of the atomization bracket 1230 . The atomization core assembly 123 also includes an oil-conducting cotton 3005. The oil-conducting cotton 3005 is wrapped around the outside of the heating device 1231, and the oil-conducting cotton 3005 covers the oil-conducting groove 1233, ensuring that the atomized medium reaching the heating device 1231 passes through the oil-conducting cotton 3005. The liquid transfer speed is more uniform and the taste is more delicate; specifically, the atomized medium stored in the oil storage cotton 304 is transferred to the oil guide cotton 3005 through the oil guide groove 1233, and the oil guide cotton 3005 is wrapped around the outside of the heating device 1231, so the oil guide cotton 3005 is The atomized medium in the oil cotton 3005 can form an aerosol after contacting the heating device 1231 that generates heat. It can be understood that when the user inhales the electronic atomizer, the airflow enters from the air inlet 1020 of the bottom cover 102, flows through the first airflow channel 1313 to the microphone 130 in the accommodation cavity 4011, and the microphone 130 passes through the airflow. The movement realizes the start of the circuit, so that the circuit controls the work of the atomized medium carrier 30. Specifically, by controlling the heating work of the heating device 1231, the atomized medium in the oil storage bin 303 transitions from the oil storage cotton 304 to the oil guide cotton 3005, and generates heat. The heating device 1231 evaporates and vaporizes the atomization medium in contact with the oil-conducting cotton 3005 in the atomization chamber 1232 to form an aerosol; and the airflow passing through the accommodation chamber 4011 continues to flow, passing through the second airflow channel 1316 and then from the bottom The air inlet pipe 3021 on the oil-sealing silicone 121 enters the atomization chamber 1232. The aerosol in the atomization chamber 1232 flows along the air outlet tube 3010 on the top air-sealing silicone 301 to the suction nozzle 20, and is inhaled by the user from the air outlet 200 of the suction nozzle 20; and, the arrangement of the second protrusion 1315 Therefore, when the atomized medium in the atomized medium carrier 30 leaks and flows to the upper surface of the microphone protection structure 401, it is difficult to cross the height of the second protruding portion 1315 and cannot enter the second airflow channel from the second channel opening 1317. 1316, to prevent the atomized medium from invading the upper surface of the microphone 130. In addition, an accommodating groove 3011 is formed on the side of the top air-sealing silicone gel 301 facing the top cover 100, and an oil-repellent cotton 60 is disposed in the accommodating groove 3011. By disposing the oil-proof cotton 60 between the top air-sealing silica gel 301 and the suction nozzle 20 , the atomized medium flowing out through the air outlet pipe 3010 on the top air-sealing silica gel 301 can be absorbed by the oil-proof cotton 60 to avoid unvaporized atomization. The medium is used through the suction nozzle 20 Inhaled by the household.

Optionally, the second protruding portion 1315 can be provided with a stepped structure. The stepped structure of the second protruding portion 1315 prevents the atomized medium from flowing into the microphone 130 from the top of the microphone protection structure 401 into the accommodation cavity 4011. The upper surface of the microphone 130, or enter other parts of the microphone 130. Therefore, by providing the stepped first protrusion 1312 and the second protrusion 1315, it is possible to prevent the atomized medium from intruding into the upper surface of the microphone 130 in the accommodation cavity 4011 from above the microphone protection structure 401, and to avoid The atomized medium invades the lower surface of the microphone 130 from the bottom of the microphone protection structure 401, thereby preventing the atomized medium from eroding the microphone 130 in all directions.

Further, the protective structure main body 1310 is also provided with an overflow hole 1318. In some embodiments, the overflow hole 1318 penetrates the upper surface of the protective structure body 1310 on the side facing the top cover 100 and the lower surface of the side facing the bottom cover 102 . It can be understood that since the microphone 130 is disposed in the accommodation cavity 4011 of the protective structure main body 1310, a second protruding portion 1315 extends from the protective structural main body 1310 toward the top cover 100, and the second protruding portion 1315 is provided with The second airflow channel 1316 and the second protrusion 1315 have a second channel opening 1317 at one end away from the protective structure main body 1310. The second airflow channel 1316 is connected to the accommodation cavity 4011 and the second channel opening 1317 respectively. Therefore, when the oil-absorbing cotton is used, After 50 absorbs the atomized medium and is saturated, the excess atomized medium may flow to the upper surface of the microphone protection structure 401. When the atomized medium accumulates to a certain volume or height, there is a height beyond the second protrusion 1315 and The possibility of further entering the second airflow channel 1316 from the second channel opening 1317, and flowing along the second airflow channel 1316 to saturate the upper surface of the microphone 130; therefore, in order to avoid excessive fog accumulation on the upper surface of the protective structure main body 1310 To atomize the medium and enter the second airflow channel 1316, an overflow hole 1318 can be opened on the protective structure main body 1310. The overflow hole 1318 can directly guide the atomized medium accumulated on the upper surface of the protective structure main body 1310 to the side of the bottom cover 102. .

In one embodiment, the surface of the microphone 130 is covered with a nano waterproof and breathable coating (not shown). In order to facilitate the understanding of this embodiment, the existing microphone 130 without a nano-waterproof and breathable coating on the surface and the microphone 130 in this embodiment with a nano-waterproof and breathable coating on the surface were tested. The test results are as follows: when powered on When immersed in tap water, the existing microphone 130 without a nano-waterproof and breathable coating on the surface will fail after the immersion time reaches 2 to 5 minutes. However, the microphone 130 in this embodiment is covered with a nano-waterproof and breathable coating on the surface. The head 130 can still work normally after the immersion time reaches 10 to 11 hours; and when immersed in the atomized medium after being powered on, the existing microphone 130 that does not have a nano waterproof and breathable coating on the surface can still work normally after the immersion time reaches 2 It will fail after ~3 hours. However, the microphone 130 in this embodiment whose surface is covered with a nano-waterproof and breathable coating can still work normally after the soaking time reaches 202 hours. It can be found that the oil droplet angle, water droplet angle, and atomization medium infiltration on the surface of the microphone 130 covered with a nano-waterproof and breathable coating in this embodiment are significantly improved. By increasing the surface contact angle of the microphone 130, fog can be effectively reduced. Chemical media, water vapor, etc. can penetrate and condense on the surface of the microphone 130, which can inhibit the siphon effect, thereby protecting the microphone 130 and internal components of the microphone 130. Therefore, by coating the surface of the microphone 130 with a nano waterproof and breathable coating, when the oil-absorbing cotton 50 absorbs the atomized medium and is saturated, the excess atomized medium will overflow the first protrusion even if it accumulates in the bottom cover 102 due to excessive accumulation. 1312 and immersed in the containing cavity 4011, or the excess atomized medium drips directly to the second channel opening 1317 and flows along the second airflow channel 1316 to impregnate the upper surface of the microphone 130. The nano waterproof and breathable coating can also Block the atomized medium to prevent the atomized medium from invading the inside of the microphone 130, prevent the microphone 130 from malfunctioning or malfunctioning, and ensure that the atomizer can be used normally and safely.

In one embodiment, the microphone protective structure 401 further includes a third protruding portion 1319 extending from the protective structure main body 1310 toward the top cover 100 side. The third protruding portion 1319 is located around the periphery of the second protruding portion 1315 , the height of the third protruding portion 1319 is greater than the height of the second protruding portion 1315 . Specifically, since the microphone protection structure 401 has a second protrusion 1315 and a third protrusion 1319 extending from the protection structure main body 1310 to the top cover 100 side, and the height of the third protrusion 1319 is greater than the second protrusion. The height of the raised portion 1315 is such that the third raised portion 1319 can be supported on the side of the battery core 402 facing the bottom cover 102, and the height difference between the third raised portion 1319 and the second raised portion 1315 allows the second channel There is a certain distance between the opening 1317 and the surface of the side of the battery core 402 facing the bottom cover 102 to facilitate the passage of the airflow flowing out of the second airflow channel 1316 .

In one embodiment, as shown in FIG. 6 , the bottom cover 102 includes a cover bottom 1021 opposite to the top cover 100 . And the cover side portion 1022 extends from the outer edge of the cover bottom 1021 to the side of the top cover 100. The cover side portion 1022 is engaged with the bottom opening of the main body tube 101; the side of the protective structure main body 1310 close to the cover side portion 1022 is provided with at least One support rib 1311 is provided along the circumferential direction of the protective structure body 1310. The microphone protection structure 401 is engaged with the cover side 1022 through at least one support rib 1311. It can be understood that when the microphone protection structure 401 is installed on the bottom cover 102 as a whole, the support ribs 1311 interfere with the cover side 1022, and the microphone protection structure 401 is engaged with the cover side 1022. At this time, the protection structure The side of the main body 1310 close to the cover side 1022 is not completely in contact with the inner wall of the cover side 1022. That is to say, a gap is formed next to the support rib 1311 to facilitate the removal of the microphone protection structure 401 from the bottom cover 102. The overall installation and disassembly of the microphone protection structure 401 is easy to operate.

The oil-leakage-proof electronic atomizer in the embodiment of the present application disposes oil-absorbing cotton 50 between the atomizing medium carrier 30 and the electronic control assembly 40 of the electronic atomizer, so that the atomization in the atomizing medium carrier 30 is When the medium leaks to the side of the electronic control component 40, the atomized medium will be absorbed by the oil-absorbing cotton 50 and will not leak to the electronic control component 40, thus preventing the electronic control component 40 from malfunctioning or malfunctioning. Further, by passing the heating wire pin 1234 through the bottom oil sealing silicone 121 to the side of the electronic control component 40, the heating wire pin 1234 interferes with the bottom oil sealing silicone 121, so that the heating wire pin 1234 and the bottom oil sealing There is no gap at the position where the heating wire pin 1234 passes through on the silicone 121, so the atomized medium in the atomized medium carrier 30 will not leak to the electric circuit along the position where the heating wire pin 1234 passes through on the bottom sealing oil silicone 121. On the side of the control component 40, this prevents the oil-absorbing cotton 50 from absorbing the atomized medium and being saturated, causing the excess atomized medium to still flow to the electronic control component 40, further ensuring that the electronic control component 40 will not malfunction or malfunction. Further, by adding a microphone protection structure 401 inside the electronic atomizer, the microphone protection structure 401 includes a protection structure main body 1310 with an accommodating cavity 4011, so the microphone 130 can be disposed in the accommodating cavity 4011. As the microphone protection structure 401, the head protection structure 401 can protect the microphone 130; during the process of assembling the electronic atomizer, the microphone 130 is first installed in the accommodation cavity 4011 in the microphone protection structure 401, Then, the microphone protection structure 401 and the microphone 130 are installed in the electronic atomizer as a whole, which can not only fix the microphone 130, but also avoid the effects caused when the microphone 130 is directly installed without the microphone protection structure 401. The microphone 130 is squeezed by the force and will not be damaged. Further, a first protrusion 1312 is formed on the microphone protection structure 401 extending from the protection structure main body 1310 to the bottom cover 102 side. The first protrusion 1312 makes the accommodation cavity between the bottom cover 102 and the protection structure main body 1310 There is a certain distance between the microphones 130 in the 4011, so when the atomization medium in the atomization medium carrier 30 leaks too much and causes the oil-absorbing cotton 50 to be saturated, the excess atomization medium leaks to the electronic control component 40. side and accumulates between the bottom cover 102 and the main body 1310 of the protective structure without soaking the microphone 130 in the accommodation cavity 4011, thereby preventing the atomized medium from soaking the microphone 130 and causing malfunction or malfunction. In addition, a second protruding portion 1315 is formed on the microphone protective structure 401 extending from the protective structure main body 1310 to the top cover 100 side. The second protruding portion 1315 is arranged so that when the atomized medium in the atomized medium carrier 30 leaks When the atomized medium flows to the upper surface of the microphone protection structure 401, it is difficult to enter the second airflow channel 1316 from the second channel opening 1317 of the second protruding portion 1315, thereby preventing the atomized medium from intruding into the upper surface of the microphone 130. In addition, the surface of the microphone 130 is coated with a nano-waterproof and breathable coating, so that when the oil-absorbing cotton 50 absorbs the atomized medium and is saturated, the excess atomized medium will overflow the first protrusion even if it accumulates in the bottom cover 102 too much. 1312 and immersed in the containing cavity 4011, or the excess atomized medium drops directly to the second channel opening 1317 and flows along the second airflow channel 1316 to impregnate the upper surface of the microphone 130, the nano waterproof and breathable coating is also It can block the atomized medium, prevent the atomized medium from intruding into the inside of the microphone 130, prevent the microphone 130 from malfunctioning or malfunctioning, and ensure that the atomizer can be used normally and safely.

The technical features of the above-described embodiments can be combined in any way. To simplify the description, not all possible combinations of the technical features in the above-described embodiments are described. However, as long as there is no contradiction in the combination of these technical features, All should be considered to be within the scope of this manual.

The above-mentioned embodiments only express several implementation modes of the present invention, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of the invention. It should be noted that, for those of ordinary skill in the art, several modifications and improvements can be made without departing from the concept of the present invention, and these all belong to the protection scope of the present invention. Therefore, the scope of protection of the patent of the present invention should be determined by the appended claims.

Claims

A microphone protection structure, characterized in that the microphone protection structure is made of elastic material, and the microphone protection structure includes a protection structure main body and a first protrusion extending downward from one end of the protection structure main body. , a receiving cavity is provided in the main body of the protective structure, and the receiving cavity is used to accommodate the microphone.
The microphone protective structure according to claim 1, wherein the first protruding portion is provided with a first airflow channel, and an end of the first protruding portion away from the main body of the protective structure has a first channel opening. , the first air flow channel is connected with the accommodation cavity and the first channel opening respectively.
The microphone protection structure according to claim 2, wherein the microphone protection structure further includes a second protrusion extending from the main body of the protection structure to an end away from the first protrusion, and the The second protruding portion is provided with a second airflow channel. One end of the second protruding portion away from the main body of the protective structure has a second channel opening. The second airflow channel is connected to the accommodation cavity and the third airflow channel respectively. The two channels are connected through openings.
An atomized medium carrier, characterized in that the atomized medium carrier includes:

Atomized medium carrier shell;

Top air-sealing silica gel and bottom oil-sealing silica gel. The top air-sealing silica gel is provided at one end of the atomization medium carrier housing, and the bottom oil-sealing silica gel is provided at the other end of the atomization medium carrier housing. An oil storage tank is formed between the top air-sealing silica gel, the bottom oil-sealing silica gel and the atomization medium carrier shell;

The atomization core assembly is arranged in the atomization medium carrier housing. The atomization core assembly includes an atomization bracket and a heating device. An atomization chamber is formed in the middle of the atomization bracket. The sides of the atomization bracket An oil guide groove is provided on the side, the atomization chamber is connected with the oil storage bin through the oil guide groove, and the heating device is arranged in the atomization chamber;

Wherein, the heating device includes a heating wire pin, the heating wire pin passes through the bottom oil sealing silicone, and the heating wire pin is an interference fit with the bottom oil sealing silicone.
The atomization medium carrier according to claim 4, characterized in that the bottom oil-sealing silica gel is provided with blind holes, and during the process of installing the atomization core assembly on the bottom oil-sealing silica gel, the The heating wire pin penetrates into and passes through the bottom of the blind hole.
The atomized medium carrier according to claim 5, characterized in that the position where the bottom oil-sealing silicone is in contact with the heating wire pin is coated with an oil-proof coating;

And/or, the heating device includes a mesh heating sheet or a spring-shaped heating wire.
The atomization medium carrier according to any one of claims 4 to 6, characterized in that the oil storage bin is filled with oil storage cotton, and the oil storage cotton is used to store smoke oil, and the oil storage cotton bag Cover the periphery of the atomizer bracket.
The atomization medium carrier according to claim 7, characterized in that the atomization core assembly further includes oil-conducting cotton, the oil-conducting cotton is wrapped outside the heating device, and the oil-conducting cotton covers all Describe the oil guide tank.
An electronic atomizer, characterized in that the electronic atomizer includes:

Electronic atomizer housing;

A suction nozzle, the suction nozzle is provided at one end of the electronic atomizer housing;

An atomization medium carrier, which is installed on the side of the electronic atomizer housing close to the suction nozzle;

The electronic control assembly is installed on the side of the electronic atomizer housing away from the suction nozzle. The electronic control assembly includes a microphone and a microphone protection structure. The microphone protection structure is made of elastic material. The microphone protective structure includes a protective structure main body and a first protrusion extending from one end of the protective structure main body to the bottom of the electronic atomizer housing. A container is opened in the protective structure main body. A cavity is placed, and the microphone is arranged in the containing cavity.
The electronic atomizer according to claim 9, characterized in that the electronic atomizer housing includes a top cover, a main body tube and a bottom cover, and the top cover is disposed at the top opening of the main body tube and connected with the The main body tube is fixedly connected, the bottom cover is arranged on the bottom opening of the main body tube and is fixedly connected with the main body tube, and the suction nozzle is arranged on the top cover;

The microphone protection structure is disposed on the side of the main body tube close to the bottom cover, and the microphone protection structure is in contact with the bottom cover. The bottom cover is fixedly connected.
The electronic atomizer according to claim 10, characterized in that the first protruding part is provided with a first airflow channel, and an end of the first protruding part away from the main body of the protective structure has a first channel opening. , the first air flow channel is connected with the accommodation cavity and the first channel opening respectively; the bottom cover is provided with an air inlet, and the first air flow channel is connected with the air inlet.
The electronic atomizer according to claim 11, wherein the microphone protection structure includes a second protrusion extending from the main body of the protection structure to the top cover, and the second protrusion has an opening. There is a second airflow channel, the end of the second protrusion away from the main body of the protective structure has a second channel opening, the second airflow channel is connected to the accommodation cavity and the second channel opening respectively; The suction nozzle has an air outlet, and the atomized medium carrier includes an air inlet pipe, an atomization chamber, and an air outlet pipe that are connected in sequence. The air outlet pipe is connected with the air outlet, and the air inlet pipe is connected with the second air flow channel. .
The electronic atomizer according to claim 12, characterized in that the protective structure main body is also provided with an overflow hole, and the overflow hole penetrates the upper surface of the protective structure main body facing the top cover. surface and the lower surface facing the side of the bottom cover.
The electronic atomizer according to claim 12 or 13, wherein the microphone protective structure further includes a third protrusion extending from the main body of the protective structure to the top cover, the third protrusion The height of the raised portion is greater than the height of the second raised portion;

The electronic control assembly also includes an electric core, which is disposed between the atomizing medium carrier and the microphone protection structure, and the electric core is used to supply power to the atomizing medium carrier and the microphone. To supply power, the third protrusion is supported on the side of the battery core facing the bottom cover.
The electronic atomizer according to any one of claims 10 to 13, characterized in that the bottom cover includes a cover bottom opposite to the top cover, and a cover bottom extending from an outer edge of the cover bottom to the top cover. A cover side portion extends on one side, and the cover side portion is snap-fitted with the bottom opening of the main body tube; at least one support rib is provided on the side of the protective structure main body close to the cover side portion, and the support rib is arranged along the The protective structure body is arranged circumferentially, and the microphone protective structure is engaged with the side of the cover through the at least one support rib.
An electronic atomizer, characterized in that the electronic atomizer includes:

Electronic atomizer housing;

A suction nozzle, the suction nozzle is provided at one end of the electronic atomizer housing;

An atomization medium carrier and an electronic control assembly. The atomization medium carrier is installed on the side of the electronic atomizer housing close to the suction nozzle. The electronic control assembly is installed on the side of the electronic atomizer housing away from the suction nozzle. One side of the suction nozzle;

Wherein, the atomization medium carrier is the atomization medium carrier according to any one of claims 4 to 8, the top air-sealing silica gel is located near the side of the suction nozzle, and the bottom oil-sealing silica gel is located near the side of the suction nozzle. On the side of the electronic control component, the heating wire pin passes through the bottom oil-sealing silicone to the side of the electronic control component to be electrically connected to the electronic control component.
The electronic atomizer according to claim 16, characterized in that the electronic atomizer housing includes a top cover, a main body tube and a bottom cover, and the top cover is disposed at the top opening of the main body tube and connected with the The main body tube is fixedly connected, the bottom cover is arranged on the bottom opening of the main body tube and is fixedly connected with the main body tube, and the suction nozzle is arranged on the top cover.
The electronic atomizer according to claim 17, wherein the suction nozzle has an air outlet, the bottom cover is provided with an air inlet, and the top air-sealing silicone is provided with a penetrating air outlet pipe, and the The air outlet pipe is connected to the air outlet. The bottom oil-sealing silicone is provided with a penetrating air inlet pipe. The air inlet pipe is connected to the air inlet. The two ends of the atomization bracket are respectively connected to the top air seal. The silica gel is connected to the bottom sealing oil silica gel, and the atomization chamber is connected to the air outlet pipe and the air inlet pipe respectively.
The electronic atomizer according to claim 18, wherein the top air-sealing silicone has an accommodating groove formed on one side toward the top cover, and oil-absorbing cotton is disposed in the accommodating groove.
The electronic atomizer according to any one of claims 16 to 19, characterized in that the electronic control component includes a battery core and a microphone, the microphone is disposed on a side close to the bottom cover, and the electric control component The core is set in the bottom sealing oil Between the silica gel and the microphone, the electric core is used to supply power to the atomized medium carrier and the microphone.
An electronic atomizer, characterized in that the electronic atomizer includes:

Electronic atomizer housing;

A suction nozzle, the suction nozzle is provided at one end of the electronic atomizer housing;

An atomization medium carrier, which is installed on the side of the electronic atomizer housing close to the suction nozzle;

The electronic control component is installed on the side of the electronic atomizer housing away from the suction nozzle. The electronic control component includes a microphone, and the surface of the microphone is covered with a nano waterproof and breathable coating. .
The electronic atomizer according to claim 21, characterized in that the electronic atomizer housing includes a top cover, a main body tube and a bottom cover, and the top cover is disposed at the top opening of the main body tube and connected with the The main body tube is fixedly connected, the bottom cover is arranged on the bottom opening of the main body tube and is fixedly connected with the main body tube, and the suction nozzle is arranged on the top cover.
The electronic atomizer according to claim 22, characterized in that the electronic control component further includes a battery core, the microphone is disposed on a side close to the bottom cover, and the battery core is disposed on the atomizer. Between the medium carrier and the microphone, the electric core is used to supply power to the atomized medium carrier and the microphone.
The electronic atomizer according to claim 22, wherein the bottom cover protrudes toward one side of the top cover to form a support column, and the support column and the inner surface of the bottom cover form a liquid storage tank, The microphone is arranged on the support column.
The electronic atomizer according to claim 24, wherein the bottom cover is provided with an air inlet, the support column is provided with an air flow channel, and an end of the support column away from the bottom cover has a channel opening, Both ends of the air flow channel are connected to the air inlet and the channel opening respectively, and the microphone is disposed on the path of the air flow channel;

The suction nozzle has an air outlet, and the atomized medium carrier includes an air inlet pipe, an atomization chamber, and an air outlet pipe that are connected in sequence. The air outlet pipe is connected with the air outlet, and the air inlet pipe is connected with the air flow channel.
The electronic atomizer according to claim 25, wherein the microphone is disposed in the air flow channel.
The electronic atomizer according to claim 26, wherein at least one support rib is provided on the inner wall side of the air flow channel, and the support rib is arranged along the extension direction of the air flow channel.
The electronic atomizer according to claim 25, characterized in that there are multiple support ribs, and the multiple support ribs are evenly arranged along the circumferential direction of the air flow channel.
The electronic atomizer according to claim 25, wherein the microphone is disposed at the channel opening.
The electronic atomizer according to claim 25, characterized in that the distance between the channel opening and the bottom of the liquid reservoir is greater than 1 mm.
An electronic atomizer, characterized in that the electronic atomizer includes:

Electronic atomizer housing;

A suction nozzle, the suction nozzle is provided at one end of the electronic atomizer housing;

An atomization medium carrier and an electronic control assembly. The atomization medium carrier is installed on the side of the electronic atomizer housing close to the suction nozzle. The electronic control assembly is installed on the side of the electronic atomizer housing away from the suction nozzle. One side of the suction nozzle;

Wherein, oil-absorbing cotton is arranged between the atomized medium carrier and the electronic control component.
The electronic atomizer according to claim 31, characterized in that the atomization medium carrier includes an atomization core assembly, a top air-sealing silica gel near the side of the suction nozzle and a side near the electronic control component. The bottom oil-sealing silica gel, an oil storage bin is formed between the top air-sealing silica gel and the bottom oil-sealing silica gel; the atomization core assembly includes an atomization bracket and a heating device, and a mist is formed in the middle of the atomization bracket An atomization chamber, an oil guide groove is provided on the side of the atomization bracket, the atomization chamber is connected to the oil storage bin through the oil guide groove, and the heating device is arranged in the atomization chamber;

Wherein, the heating device includes a heating wire pin, and the heating wire pin passes through the bottom sealing oil silicone to one side of the electronic control component to be electrically connected to the electronic control component. The heating wire pin The feet have an interference fit with the bottom oil-sealing silicone.
The electronic atomizer according to claim 32, characterized in that:

The bottom oil-sealing silicone is provided with a blind hole. During the process of installing the atomization core assembly on the bottom oil-sealing silicone, insert and pass the heating wire pin through the blind hole. bottom to the side of the electronic control component.
The electronic atomizer according to any one of claims 31 to 33, characterized in that the electronic control assembly includes a microphone and a microphone protection structure, the microphone protection structure includes a protection structure main body, and the protection structure The main body has an accommodating cavity, and the microphone is arranged in the accommodating cavity.
The electronic atomizer according to claim 34, characterized in that the electronic atomizer housing includes a top cover, a main body tube and a bottom cover, the top cover is disposed at the top opening of the main body tube and connected with the The main body tube is connected, the bottom cover is arranged on the bottom opening of the main body tube and is connected with the main body tube, and the suction nozzle is arranged on the top cover;

The electronic control assembly also includes a battery core, which is disposed between the atomization medium carrier and the microphone protection structure, and the oil-absorbing cotton is attached to the battery core facing the atomization medium carrier. On one side, the battery core is used to supply power to the atomized medium carrier and the microphone. The microphone protection structure is arranged on the side close to the bottom cover. The microphone protection structure is connected to the bottom cover. Cover fixed connection.
The electronic atomizer according to claim 35, wherein the microphone protection structure includes a first protrusion extending from the main body of the protection structure to one side of the bottom cover.
The electronic atomizer according to claim 36, characterized in that the first protruding part is provided with a first airflow channel, and an end of the first protruding part away from the main body of the protective structure has a first channel opening. , the first air flow channel is connected with the accommodation cavity and the first channel opening respectively; the bottom cover is provided with an air inlet, and the first air flow channel is connected with the air inlet.
The electronic atomizer according to claim 37, wherein the microphone protection structure includes a second protrusion extending from the main body of the protection structure to one side of the top cover, and the second protrusion A second airflow channel is provided in the second protruding portion. One end of the second protruding portion away from the main body of the protective structure has a second channel opening. The second airflow channel is respectively connected with the accommodation cavity and the second channel opening. ; The suction nozzle has an air outlet, the top air-sealing silica gel is provided with a penetrating air outlet pipe, the air outlet pipe is connected with the air outlet, the bottom oil-sealing silica gel is provided with a penetrating air inlet pipe, the The air inlet pipe is connected to the second air flow channel, the two ends of the atomization bracket are connected to the top air sealing silica gel and the bottom oil sealing silica gel, and the atomization chamber is connected to the air outlet pipe and the bottom oil sealing silica gel respectively. The intake pipe is connected.
The electronic atomizer according to claim 38, characterized in that an overflow hole is also provided on the main body of the protective structure, and the overflow hole penetrates the upper surface of the main body of the protective structure facing the top cover. surface and the lower surface facing the side of the bottom cover.
The electronic atomizer according to claim 34, wherein the surface of the microphone is covered with a nano waterproof and breathable coating.