Atomizer and electronic atomization device

Abstract

The application belongs to the technical field of electronic atomization equipment, and provides an atomizer, which comprises a shell, a bottom cover and a microphone air channel. The bottom cover and the shell are connected with each other to form a cavity in the shell for mounting an atomization assembly. The microphone air channel is installed in the cavity. The microphone air channel is a pipe body made of a soft elastic material. Two ends of the microphone air channel are connected with the shell and the bottom cover respectively, and the microphone air channel can be bent and deformed under pressure. The application also provides an electronic atomization device with the atomizer. The application aims to solve the technical problem that the microphone air channel independently arranged on the atomizer of the prior art electronic atomization device is difficult to manufacture and difficult to assemble.

Description

Technical Field

[0001] This application belongs to the technical field of electronic atomization equipment, and particularly relates to an atomizer and an electronic atomization device. Background Technology

[0002] The microphone in an e-cigarette typically refers to a sensor, whose main function is to receive the user's inhalation signal, thereby controlling the e-cigarette's on and off operation. To enable the microphone to sense the user's inhalation signal, an airflow channel connected to the microphone needs to be incorporated into the atomizer. There are two common structures for this microphone airflow channel: one shares a channel with the atomization channel, which saves space, but allows condensate in the atomization channel to flow back to the microphone, making it susceptible to water damage; the other is a dedicated microphone airflow channel (hereinafter referred to as the microphone airflow channel), allowing it to operate independently from the atomization channel, thus solving the condensate backflow problem. However, the microphone airflow channel increases space requirements, affecting the overall size of the atomizer.

[0003] In existing technology, the atomizer in an electronic atomizing device has a built-in liquid reservoir. The atomizer generally consists of a shell and a bottom cover, which need to be connected and assembled to form a complete atomizer. However, if there are dimensional tolerances in the internal components, the connection between the shell and the bottom cover will be loose, affecting the atomizer's sealing performance. This is especially true for atomizers using independent microphone channels. The bottom cover has a vent for communicating with the channel on the main body of the electronic atomizing device. The microphone channel is generally molded together with the internal structure of the shell, meaning that after the shell is molded, the microphone channel is integrally formed within the shell. If there are dimensional tolerances in this microphone channel, such as the microphone channel extending too short towards the bottom cover, the microphone channel will not be able to connect properly to the bottom cover when the shell and bottom cover are connected, and it will also be unable to communicate with the microphone on the main body. If the microphone channel extends too long towards the bottom cover, the connection between the shell and the bottom cover will be loose, easily resulting in gaps at the connection point, affecting the atomizer's sealing performance.

[0004] Current solutions only allow for post-processing corrections, such as pre-setting an extra length for the microphone airflow and then adjusting it through cutting or grinding to make the microphone airflow length meet assembly requirements. It is evident that manufacturing microphone airflow integrated into the atomizer is difficult, the correction process is cumbersome, production costs are high, and it is difficult to meet assembly requirements. Summary of the Invention

[0005] The purpose of this application is to provide an atomizer and an electronic atomizing device to solve the technical problem that the independently set microphone airway on the atomizer of the prior art electronic atomizing device is difficult to manufacture and difficult to meet assembly requirements.

[0006] To achieve the above objectives, the technical solution adopted in this application is as follows:

[0007] In a first aspect, embodiments of this application provide an atomizer, comprising:

[0008] case;

[0009] The bottom cover is interconnected with the housing to form a cavity inside the housing for installing the atomizing components;

[0010] The microphone airway is installed inside the cavity. The microphone airway is a tube made of soft and elastic material. Both ends of the microphone airway are connected to the housing and the bottom cover, respectively, and can be bent and deformed under pressure.

[0011] Therefore, the microphone airway is made of a soft, elastic material. Utilizing the elastic bending and deformation property of the hose, it is beneficial that when the microphone airway is installed between the housing and the bottom cover, it can bend and deform under the pressure at both ends, thereby automatically correcting the length tolerance of the microphone airway and meeting the assembly requirements of the atomizer.

[0012] An improvement is made to the microphone airway mounting structure. The housing has a first insertion part for mounting the microphone airway; the bottom cover has a second insertion part corresponding to the position of the first insertion part. Both ends of the microphone airway are respectively inserted and fixed into the first insertion part and the second insertion part. This allows the microphone airway to be easily installed as a separate component within the atomizer, and it automatically bends and deforms to correct dimensional tolerances, effectively ensuring the sealing of the connection between the housing and the bottom cover.

[0013] Another improvement is made to the microphone airway mounting structure. The housing has a mounting hole communicating with the outside, and the bottom cover has a socket corresponding to the mounting hole. The microphone airway is inserted into the housing through the mounting hole and extends to the bottom cover to connect with the socket. This allows the microphone airway to be installed after the housing and bottom cover are assembled, effectively ensuring a tight seal between the housing and bottom cover.

[0014] The atomizer's structure has been improved. The cavity of the housing contains an output pipe, a ventilation chamber, and a liquid storage chamber, with the microphone airflow located within the ventilation chamber. The output pipe extends from the housing to the liquid storage chamber and communicates with the outside of the housing. The atomizing assembly includes an atomizing core, which is disposed in the liquid storage chamber and connected to the output pipe. The atomizing core heats the aerosol matrix in the liquid storage chamber during use, producing aerosol that is output through the output pipe. Thus, the microphone airflow and output pipe are independently configured, which, compared to the traditional design using a shared airflow, helps eliminate the risk of condensate backflow causing water damage to the microphone. Furthermore, the housing integrates a liquid storage chamber and a ventilation chamber. The liquid storage chamber holds the aerosol matrix, essentially integrating the mouthpiece and liquid storage chamber into a single unit, effectively eliminating the assembly gaps that easily form between the mouthpiece and liquid storage chamber after traditional assembly, ensuring the cleanliness and hygiene of the atomizer.

[0015] In one embodiment, the housing is further equipped with a suction nozzle, which has a first suction port and a second suction port arranged adjacent to each other. The first suction port is connected to the output pipe. The housing is also provided with a connecting portion that communicates with the microphone airway, and the second suction port is connected to the microphone airway through the connecting portion. This allows the suction nozzle to be removed and replaced separately, effectively ensuring hygienic use.

[0016] In one embodiment, the housing is further provided with a ventilation port communicating with the ventilation chamber, and the bottom cover is further provided with a mounting base for mounting the atomizing core. The mounting base has a ventilation channel communicating with the ventilation chamber. The ventilation chamber is connected to the mounting base and communicates with one end of the ventilation channel, while the other end of the ventilation channel communicates with the atomizing core. Thus, the ventilation port on the housing, the ventilation chamber, the ventilation channel in the mounting base, the atomizing core in the liquid storage chamber, and the output pipe on the housing are sequentially connected, forming a channel for exchanging gas with the outside environment on the atomizer. This helps reduce suction resistance and improve the user experience.

[0017] In one embodiment, the mounting base further includes a sealing sleeve made of a sealing material, on which both the atomizing core and the ventilation chamber are connected; the mounting base also has a connection port extending through it, with the extension end of the ventilation chamber connected to the connection port, and the microphone air passage extending through the connection port to the bottom cover. Thus, by using a sealing sleeve on the mounting base and connecting it to the atomizing core and ventilation chamber, leakage gaps are effectively filled, thereby improving the sealing effect and preventing liquid leakage.

[0018] In one embodiment, the atomizer further includes an adjusting member for adjusting the inhalation resistance during use. The adjusting member is disposed on the air vent of the housing and is disposed within the air vent chamber, avoiding contact with the microphone airway. The adjusting member has an adjusting hole that aligns with the air vent. This allows the atomizer to integrate an adjustment mechanism for adjusting the inhalation resistance, with the adjusting member located on the air vent of the housing, and the inhalation resistance adjusted during use. This helps save space and reduces production difficulty and costs.

[0019] Secondly, embodiments of this application also provide an electronic atomizing device, including a body, a power supply component, and an atomizer, wherein the atomizer is detachably connected to the body; the power supply component is disposed within the body, and includes a circuit board and a battery for supplying power to the atomizer; the atomizing component includes at least a heating element, which is electrically connected to the circuit board. This allows the atomizer to be used as a replaceable component; when the liquid level in the reservoir is depleted, the atomizer can be removed from the body and replaced with a new one, effectively achieving rapid battery life.

[0020] In one embodiment, the bottom cover of the atomizer has a vent hole communicating with the outside, and the microphone airway is connected to the bottom cover and communicates with the vent hole. The main body also includes a microphone and a detection airway communicating with the vent hole. The microphone is electrically connected to the circuit board and is used to receive the inhalation signal in the detection airway to control the opening and closing of the electronic atomizing device. This separates the atomizing airway on the atomizer and the microphone airway on the microphone into two independent airways, effectively preventing condensate from easily flowing back to the microphone and / or circuit board, thus extending the service life of the electronic atomizing device.

[0021] The beneficial effects of the atomizer and electronic atomizing device provided in this application are as follows: Compared with the prior art, the atomizer of this application has an independently set microphone airway, which is assembled and set in the atomizer. Compared with the traditional structure in which the microphone airway and the shell are integrally formed, it is beneficial to reduce production costs and save space.

[0022] The microphone airway is a flexible tube made of soft and elastic material. Utilizing the characteristic that the tube can bend and deform when pressure is applied to both ends, it is beneficial to bend and deform under pressure after the shell and bottom cover are connected and assembled, thereby automatically correcting dimensional tolerances and ensuring that the shell and bottom cover are connected in place. This effectively improves the connection and sealing of the shell and bottom cover and ensures the sealing effect of the atomizer. Attached Figure Description

[0023] To more clearly illustrate the technical solutions in the embodiments of this application, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0024] Figure 1 Exploded view of the atomizer provided in the embodiments of this application Figure 1 ;

[0025] Figure 2 Exploded view of the atomizer provided in the embodiments of this application Figure 2 ;

[0026] Figure 3 Schematic diagram of the internal structure of the atomizer provided in the embodiments of this application Figure 1 ;

[0027] Figure 4 This is a schematic diagram of the internal structure of the housing provided in an embodiment of this application;

[0028] Figure 5 This is a schematic diagram of the exploded structure of the shell provided in an embodiment of this application;

[0029] Figure 6 Exploded view of the atomizer provided in the embodiments of this application Figure 3 ;

[0030] Figure 7 Schematic diagram of the internal structure of the atomizer provided in the embodiments of this application Figure 2 ;

[0031] Figure 8 Exploded view of the atomizer provided in the embodiments of this application Figure 4 ;

[0032] Figure 9 A schematic diagram of the assembly structure of the bottom cover and mounting base provided in an embodiment of this application;

[0033] Figure 10 A schematic diagram of the assembly structure of the bottom cover, mounting base and atomizing core provided in the embodiments of this application;

[0034] Figure 11 A schematic diagram of the assembly structure of the atomizer and the body provided in the embodiments of this application;

[0035] Figure 12 Schematic diagram of the internal structure of the electronic atomizing device provided in the embodiments of this application Figure 1 ;

[0036] Figure 13Schematic diagram of the internal structure of the electronic atomizing device provided in the embodiments of this application Figure 2 ;

[0037] Figure 14 for Figure 13 A partially enlarged structural diagram of part A.

[0038] The following are the labeling elements in the figure:

[0039] 100 - Atomizer; 200 - Main unit;

[0040] 1-Shell; 10-Bottom opening; 11-First insertion part; 12-Output pipe; 13-Ventilation chamber; 14-Liquid storage chamber; 15-Connecting part; 16-Ventilation port;

[0041] 2-Bottom cover; 21-Second insertion part; 22-Vent hole;

[0042] 3-Mic head airway;

[0043] 4-Atomizing component; 41-Atomizing core; 42-Heating element;

[0044] 5- Suction nozzle; 51- First suction port; 52- Second suction port; 53- Guide tube;

[0045] 6-Mounting base; 60-Ventilation passage; 61-Sealing sleeve; 62-Connection port;

[0046] 7-Adjusting component; 71-Adjusting hole;

[0047] 8-Power supply components; 81-Circuit board; 82-Battery;

[0048] 9 - Microphone; 91 - Detects airway. Detailed Implementation

[0049] To make the technical problems, technical solutions, and beneficial effects to be solved by this application clearer, the following detailed description is provided in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and are not intended to limit the scope of this application.

[0050] It should be noted that when a component is referred to as being "fixed to" or "set on" another component, it can be directly on or indirectly on that other component. When a component is referred to as being "connected to" another component, it can be directly connected to or indirectly connected to that other component.

[0051] It should be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this application.

[0052] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this application, "multiple" means two or more, unless otherwise explicitly specified.

[0053] In related technologies, there are also assembly structures where the microphone channel on the atomizer is designed as a separate component. During the atomizer assembly process, the microphone channel is installed before the shell and bottom cap are connected, so that both ends of the microphone channel connect to the shell and bottom cap respectively, thus installing the microphone channel inside the atomizer. However, to reduce the space occupied by the microphone channel, it is generally made of a rigid material such as metal, i.e., the microphone channel is a metal tube. Compared with the traditional structure of directly molding and forming a single piece from the shell, the metal tube microphone channel is more space-saving. However, in practical applications, the dimensional requirements for this metal microphone channel are high. If there is a tolerance in the length of the microphone channel, it cannot be installed smoothly inside the atomizer, and corresponding cutting and correction processing is still required to meet the installation requirements. It is evident that the microphone channel design in the above-mentioned related technologies still requires correction processing during assembly, which is cumbersome and affects assembly efficiency.

[0054] Therefore, this application provides a novel atomizer and electronic atomizing device, which improves the microphone airway and its installation structure on the atomizer, effectively solving the problem that the independently set microphone airway on the atomizer of traditional electronic atomizing devices is difficult to manufacture and difficult to meet assembly requirements. It will now be described in detail.

[0055] Please refer to the following: Figure 1 , Figure 2 and Figure 3 An atomizer includes at least a housing 1, a bottom cover 2, and a microphone airway 3.

[0056] The housing 1 and the bottom cover 2 are interconnected to form a cavity inside the housing 1 for mounting the atomizing component. In this embodiment, as... Figure 1As shown, the housing 1 has a bottom opening 10 for mounting the bottom cover 2, and the bottom cover 2 is located at the bottom opening 10 of the housing 1 so that a cavity is formed inside the housing 1, and the cavity can be used to mount the atomizing component 4.

[0057] The microphone airway 3 is installed inside the internal cavity of the housing 1. The microphone airway 3 is a tube made of a soft, elastic material, preferably a flexible tube made of silicone, so that the flexible microphone airway 3 has the characteristic of bending and deforming when pressure is applied to both ends. The two ends of the microphone airway 3 are connected to the housing 1 and the bottom cover 2, respectively. Utilizing the characteristics of the flexible tube, the microphone airway 3 can bend and deform under pressure from both ends, such as when pressure is applied to both ends of the microphone airway 3 by the housing 1 and the bottom cover 2 when they are connected.

[0058] Compared with the prior art, the atomizer provided in this application embodiment has an independently set microphone airway 3, which is assembled inside the atomizer. The microphone airway 3 is a flexible tube made of a soft, elastic material. Utilizing the characteristic that the tube can bend and deform under pressure at both ends, it is advantageous that when the microphone airway 3 is installed between the housing 1 and the bottom cover 2, it can bend and deform under pressure at both ends, thereby automatically correcting the length tolerance of the microphone airway 3 and meeting the assembly requirements of the atomizer.

[0059] Compared to the traditional structure where the microphone airway 3 is integrally molded onto the housing 1, the microphone airway 3 in this embodiment is installed between the housing 1 and the bottom cover 2 as a separate component, which helps reduce production costs. However, from the perspective of structural component manufacturing, to ensure the connection strength of the microphone airway 3, additional material is used at the connection point between the microphone airway 3 and the housing 1, resulting in a structure where the microphone airway 3 is integrally molded within the housing 1 occupying a larger internal space. The microphone airway 3 in this embodiment is installed within the atomizer as a separate component, which helps save space.

[0060] Compared to the aforementioned related technologies where the microphone airway 3 is a metal tube, the metal tube microphone airway 3 is advantageous in saving space. However, it has higher dimensional requirements, and any tolerances still need to be corrected, affecting assembly efficiency. In this embodiment, the microphone airway 3 is an elastic flexible tube. Utilizing its characteristic of bending and deforming under pressure at both ends, it is advantageous to bend and deform under pressure after the housing 1 and bottom cover 2 are connected and assembled, thereby automatically correcting dimensional tolerances to ensure proper connection between the housing 1 and bottom cover 2, effectively improving the sealing performance of the connection between the housing 1 and bottom cover 2.

[0061] As an example, in practical applications, a pre-length setting can be preferred for the production length of the microphone air passage 3. This ensures that the microphone air passage 3 is properly connected between the housing 1 and the bottom cover 2, and that it can automatically correct tolerances by bending deformation under pressure at both ends, effectively ensuring the sealing of the connection between the housing 1 and the bottom cover 2. During this assembly process, there is no need to perform tolerance correction on the microphone air passage 3, thereby improving installation efficiency.

[0062] The installation structure of the microphone airway 3 includes, but is not limited to, the following installation methods:

[0063] In one embodiment of this application, please refer to the following: Figure 2 and Figure 3 The housing 1 is provided with a first insertion part 11 for installing the microphone airway 3. The bottom cover 2 is provided with a second insertion part 21 corresponding to the position of the first insertion part 11. The two ends of the microphone airway 3 are respectively inserted and fixed to the first insertion part 11 and the second insertion part 21.

[0064] In this embodiment, the first insertion portion 11 on the housing 1 is preferably a first insert that matches the cross-sectional shape of the microphone airway 3; correspondingly, the second insertion portion 21 on the bottom cover 2 is also preferably a second insert that matches the cross-sectional shape of the microphone airway 3. When the microphone airway 3 is installed between the housing 1 and the bottom cover 2, both ends of the microphone airway 3 are respectively inserted and fixed with the first insert and the second insert.

[0065] In practical operation, it is preferable to first insert one end of the flexible microphone airway 3 into the second insertion part 21 of the bottom cover 2, and then, when installing the housing 1, align the other end of the microphone airway 3 with the first insertion part 11 inside the housing 1 and insert them together, thereby easily installing the microphone airway 3 into the atomizer. When the microphone airway 3 is subjected to pressure from both ends, it can automatically bend and deform to correct dimensional tolerances, effectively ensuring the sealing of the connection between the housing 1 and the bottom cover 2.

[0066] In another embodiment of this application (not shown), the housing 1 has a mounting hole (not shown) for mounting the microphone airway 3, which communicates with the outside of the housing 1. The bottom cover 2 has a socket (not shown) corresponding to the position of the mounting hole. The microphone airway 3 is inserted into the interior of the housing 1 through the mounting hole and extends to the bottom cover 2 to connect with the socket.

[0067] In practical applications, a retaining plug (not shown in the figure) can be installed on the mounting hole of the housing 1. The retaining plug is used to install on the mounting hole of the housing 1 after the microphone airway 3 is inserted into the atomizer, thereby confining the microphone airway 3 inside the atomizer. An air passage is provided on the retaining plug so that the microphone airway 3 can communicate with the outside of the atomizer through this air passage.

[0068] Therefore, the microphone airway 3 can be installed after the housing 1 and the bottom cover 2 are assembled and connected, effectively ensuring the sealing of the connection between the housing 1 and the bottom cover 2.

[0069] In another embodiment of this application, in a conventional atomizer, the mouthpiece and the reservoir are two separate components, assembled together during the manufacturing process. This can easily create gaps at the connection point between the two components, resembling tiny pits. Over time, these gaps can accumulate condensed aerosol matrix, which attracts dirt and is difficult to clean, affecting hygiene. However, since the atomizer has a mouthpiece for user use, this feature is unacceptable and makes the atomizer unusable.

[0070] Therefore, the overall structure of the atomizer is described in the embodiments of this application. Figure 3 and Figure 4 The cavity of the housing 1 contains an output pipe 12, an air exchange chamber 13, and a liquid storage chamber 14, with the microphone air passage 3 located within the air exchange chamber 13. The output pipe 12 extends from the housing 1 into the liquid storage chamber 14 and connects to the outside of the housing 1. It is evident that the microphone air passage 3 and the output pipe 12 are independently configured. Compared to the traditional design using a shared air passage, this design helps to eliminate the risk of condensate backflow causing water damage to the microphone.

[0071] The atomizing assembly 4 includes an atomizing core 41, which is disposed in the liquid storage chamber 14 and connected to the output pipe 12. The atomizing core 41 is used to heat the aerosol matrix in the liquid storage chamber 14 during use and produce aerosol that is output from the output pipe 12.

[0072] Thus, the housing 1 integrates a liquid storage chamber 14 and a ventilation chamber 13. The liquid storage chamber 14 is used to load the aerosol matrix, which is equivalent to molding the nozzle of a traditional atomizer and the liquid storage chamber 14 into one piece. This effectively eliminates the assembly gap that is easily formed between the nozzle and the liquid storage chamber 14 after assembly, and solves the problem that aerosol matrix can easily accumulate in these gaps, causing dirt to be easily adsorbed and affecting use. This ensures the cleanliness and hygiene of the atomizer and improves the user experience.

[0073] Preferably, in this embodiment, such as Figure 4 As shown, the ventilation chamber 13 is housed within the liquid storage chamber 14, which helps to increase the usable space of the liquid storage chamber 14, thereby increasing the volume of the liquid storage chamber 14 that can hold the aerosol matrix. In other embodiments, the ventilation chamber 13 and the liquid storage chamber 14 may also equally distribute the internal space of the housing 1. The specific configuration can be determined according to actual usage requirements, and is not specifically limited here.

[0074] For the structure of the atomizer, please refer to one embodiment of this application. Figure 5 and Figure 6 The housing 1 is also equipped with a suction nozzle 5. This can be understood as the suction nozzle 5 being an outer sleeve set on the housing 1, which comes into contact with the user's mouth during use.

[0075] The suction nozzle 5 has a first suction port 51 and a second suction port 52 arranged adjacent to each other, and the first suction port 51 is connected to the output pipe 12. In this embodiment, as shown... Figure 6 As shown, the nozzle 5 has a guide tube 53 inside that communicates with the first suction port 51. The shape of the guide tube 53 matches the shape of the output pipe 12 and is inserted into the output pipe 12, thereby enabling the first suction port 51 to communicate with the output pipe 12. Preferably, the guide tube 53 is gradually widened towards the first suction port 51, which is beneficial to improving the output effect.

[0076] The housing 1 is also provided with a connecting part 15 that communicates with the microphone airway 3, and the second suction port 52 is connected to the microphone airway 3 through the connecting part 15. Figure 5 and Figure 6 As shown, in this embodiment, one end of the connecting portion 15 on the housing 1 is connected to the second suction port 52 on the mouthpiece 5, and the other end of the connecting portion 15 can be provided with the aforementioned first insertion portion 11 so as to connect to one end of the microphone airway 3, thereby allowing the second suction port 52 on the mouthpiece 5 to be connected to the microphone airway 3 through the connecting portion 15 on the housing 1.

[0077] Therefore, the nozzle 5 and the housing 1 are detachable, and the nozzle 5 can be removed and replaced separately, effectively ensuring hygienic use.

[0078] In one embodiment of this application, please refer to the following: Figure 7 and Figure 8 The housing 1 is also provided with an air exchange port 16 that communicates with the air exchange chamber 13. The bottom cover 2 is also provided with a mounting base 6 for setting the atomizing core 41. The mounting base 6 has an air exchange channel 60 that communicates with the air exchange chamber 13. The air exchange chamber 13 is connected to the mounting base 6 and communicates with one end of the air exchange channel 60. The other end of the air exchange channel 60 communicates with the atomizing core 41.

[0079] like Figure 7 As shown, the air exchange port 16 on the housing 1, the air exchange chamber 13, the air exchange channel 60 in the mounting base 6, the atomizing core 41 in the liquid storage chamber 14, and the output pipe 12 on the housing 1 are connected in sequence to form a channel for exchanging gas with the outside on the atomizer, which helps to reduce suction resistance and improve the user experience.

[0080] In one embodiment of this application, please refer to the following: Figure 7 , Figure 8 and Figure 9The mounting base 6 also includes a sealing sleeve 61 made of sealing material, and the atomizing core 41 and the air exchange chamber 13 are both connected to the sealing sleeve 61. The mounting base 6 also has a connection port 62 that passes through the mounting base 6, and the extension end of the air exchange chamber 13 is connected to the connection port 62 of the mounting base 6.

[0081] Please combine Figure 8 , Figure 9 and Figure 10 As shown, the microphone airway 3 is located inside the ventilation chamber 13, passes through the connection port 62 and extends to the bottom cover 2, where it is connected and fixed.

[0082] Preferably, the diameter of the connection port 62 matches the width of the ventilation chamber 13 to ensure that the flexible microphone airway 3 can be bent and deformed within it.

[0083] Therefore, by using the sealing sleeve 61 to be installed on the mounting base 6 and connected to the atomizing core 41 and the ventilation chamber 13, it is beneficial to fill the leakage gaps, thereby improving the sealing effect and avoiding the situation of liquid leakage.

[0084] In another embodiment of this application, please refer to Figure 7 The atomizer also includes an adjustment element 7 for adjusting the suction resistance during use. The adjustment element 7 is set on the air exchange port 16 of the housing 1. Since the adjustment element 7 and the microphone airway 3 are both set in the air exchange chamber 13, the adjustment element 7 is set in the air exchange chamber 13 to avoid mutual interference with the microphone airway 3.

[0085] The adjusting member 7 has an adjusting hole 71 that aligns with the air vent 16. This adjusting hole 71 can preferably be a row of holes formed by a plurality of small holes arranged in an orderly manner on the adjusting member 7, or it can preferably be an elongated hole formed on the adjusting member 7. In this embodiment, as... Figure 7 As shown, the adjusting member 7 can preferably be a sliding switch set on the air exchange port 16. Under manual operation, the adjusting member 7 can slide on the air exchange port 16, thereby changing the conduction range of the air exchange port 16, realizing flexible adjustment of the suction resistance, and improving the user experience.

[0086] This allows the atomizer to integrate an adjustment mechanism for regulating the suction resistance. The adjustment component 7 is located on the air vent 16 of the housing 1, and adjusts the suction resistance during use. This helps save space and reduce production difficulty and costs.

[0087] Please refer to the following: Figure 11 and Figure 12 This application also provides an electronic atomizing device, including a body 200 of the electronic atomizing device, a power supply component 8, and an atomizer 100 of this application embodiment, wherein the atomizer 100 is detachably connected to the body 200.

[0088] The power supply component 8 is located within the main body 200, and includes a circuit board 81 and a battery 82 that supplies power to the atomizer 100. Figure 12 As shown, in the atomizer 100 of this application embodiment, the atomizing core 41 of the atomizing component 4 includes at least a heating element 42, and the heating element 42 has electrodes. When the atomizer 100 is installed on the body 200, the electrodes on the heating element 42 can be electrically connected to the circuit board 81.

[0089] In this way, the atomizer 100 can be used as a replacement part. When the liquid in the reservoir 14 is depleted, the atomizer 100 can be removed from the main body 200 and a new atomizer 100 can be replaced on the main body 200, effectively achieving rapid battery life and improving the user experience.

[0090] Please refer to the following: Figure 3 , Figure 13 and Figure 14 In the atomizer 100 of this application embodiment, the bottom cover 2 is also provided with a vent 22 that communicates with the outside, and the microphone air channel 3 is connected to the bottom cover 2 and communicates with the vent 22.

[0091] The main body 200 also includes a microphone 9 and a detection airway 91 for communicating with the vent 22. The microphone 9 can preferably be an airflow sensor, and it is electrically connected to the circuit board 81. In this embodiment, the microphone 9 can preferably be disposed on the circuit board 81, and it is used to receive the inhalation signal in the detection airway 91 to control the opening and closing of the electronic atomizing device.

[0092] Therefore, compared with the shared airway structure in related technologies, the shared airway easily causes condensate in the airway to flow back onto the microphone 9 and / or circuit board 81, which easily poses a risk of water damage. In the electronic atomizing device of this application embodiment, the atomizing airway on the atomizer 100 and the microphone airway 3 of the microphone 9 are separated into two independent airways, which effectively prevents condensate from easily flowing back onto the microphone 9 and / or circuit board 81 and causing risks, thereby improving the protection effect on the microphone 9 and circuit board 81 and helping to extend the service life of the electronic atomizing device.

[0093] The above description is merely a preferred embodiment of this application and is not intended to limit this application. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of this application should be included within the protection scope of this application.

Claims

1. An atomizer, characterized in that, include: case; The bottom cover is interconnected with the housing to form a cavity inside the housing for installing the atomizing component; The microphone airway is installed inside the cavity. The microphone airway is a tube made of soft and elastic material. Both ends of the microphone airway are connected to the housing and the bottom cover, respectively, and can be bent and deformed under pressure.

2. The atomizer according to claim 1, characterized in that: The housing is provided with a first insertion part for installing the microphone airway; the bottom cover is provided with a second insertion part corresponding to the position of the first insertion part, and the two ends of the microphone airway are respectively inserted and fixed to the first insertion part and the second insertion part.

3. The atomizer according to claim 1, characterized in that: The housing has an installation hole that communicates with the outside, and the bottom cover has a socket corresponding to the position of the installation hole. The microphone air passage is inserted into the interior of the housing through the installation hole and extends to the bottom cover to connect with the socket.

4. The atomizer according to claim 1, characterized in that: The cavity of the housing is provided with an output pipe, a ventilation chamber, and a liquid storage chamber, and the microphone air passage is placed in the ventilation chamber; the output pipe extends from the housing to the liquid storage chamber and communicates with the outside of the housing; the atomizing component includes an atomizing core, which is disposed in the liquid storage chamber and connected to the output pipe; the atomizing core is used to heat the aerosol matrix in the liquid storage chamber during use and produce aerosol that is output from the output pipe.

5. The atomizer according to claim 4, characterized in that: The housing is also equipped with a suction nozzle, which has a first suction port and a second suction port arranged adjacent to each other. The first suction port is connected to the output pipe. The housing is also provided with a connecting part that is connected to the microphone airway. The second suction port is connected to the microphone airway through the connecting part.

6. The atomizer according to claim 4, characterized in that: The housing is also provided with an air vent that communicates with the air exchange chamber. The bottom cover is also provided with a mounting base for setting the atomizing core. The mounting base has an air exchange channel that communicates with the air exchange chamber. The air exchange chamber is connected to the mounting base and communicates with one end of the air exchange channel. The other end of the air exchange channel communicates with the atomizing core.

7. The atomizer according to claim 6, characterized in that: The mounting base also includes a sealing sleeve made of sealing material, and the atomizing core and the air exchange chamber are both connected to the sealing sleeve; the mounting base also has a connection port that passes through the mounting base, the extension end of the air exchange chamber is connected to the connection port of the mounting base, and the microphone air passage extends through the connection port to the bottom cover.

8. The atomizer according to claim 6, characterized in that: The atomizer also includes an adjustment component for adjusting the suction resistance during use. The adjustment component is disposed on the air vent of the housing and is disposed in the air vent chamber to avoid the microphone air passage. The adjustment component has an adjustment hole that aligns with the air vent.

9. An electronic atomizing device, characterized in that: The device includes a body, a power supply assembly, and an atomizer as described in any one of claims 1 to 8, wherein the atomizer is detachably connected to the body; the power supply assembly is disposed within the body and includes a circuit board and a battery that provides power to the atomizer; The atomizing component includes at least a heating element, which is electrically connected to the circuit board.

10. The electronic atomizing device according to claim 9, characterized in that: The bottom cover of the atomizer has a vent hole that communicates with the outside. The microphone air channel is connected to the bottom cover and communicates with the vent hole. The main body also includes a microphone and a detection air channel that communicates with the vent hole. The microphone is electrically connected to the circuit board and is used to receive the inhalation signal in the detection air channel to control the opening and closing of the electronic atomizing device.

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