Electronic atomization device

Abstract

The application belongs to the technical field of electronic atomization equipment, and provides an electronic atomization device, which comprises a body of the electronic atomization device and an atomizer, a microphone and a detection air channel are arranged in the body, the microphone is used for receiving an inhalation signal in the detection air channel to control the opening and closing of the electronic atomization device, a liquid storage chamber, an output pipeline, an atomization core and a ventilation channel are arranged in the atomizer, two ends of the atomization core are communicated with the output pipeline and the ventilation channel respectively, the atomization core is used for heating an aerosol base in the liquid storage chamber, and an aerosol is generated and output from the output pipeline, and a ventilation hole and a ventilation hole are further arranged on the atomizer and communicated with the ventilation channel in the atomizer, wherein the ventilation hole is communicated with the outside, and the ventilation hole is communicated with the detection air channel on the body. The application aims to solve the technical problems that the microphone air channel structure of the prior art electronic atomization device occupies a large space and causes the microphone to be prone to water immersion risk.

Description

Technical Field

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

[0002] The microphone in an e-cigarette device usually refers to a sensor, whose main function is to receive the user's inhalation signal, thereby controlling the e-cigarette device to turn on and off. In order for the microphone in the e-cigarette device to be able to sense the user's inhalation signal, an airway (hereinafter referred to as the microphone airway) needs to be set on the atomizer of the e-cigarette device and connected to the part where the microphone is located.

[0003] There are two common structures for microphone airflow channels on atomizers: one is to share an airflow channel with the atomization channel. This design saves space, but condensation will occur in the atomization channel. This condensation can easily flow back from the vent at the bottom of the atomizer to the microphone, making the microphone susceptible to water damage. The other is to set up a separate independent airflow channel that connects to the microphone, separating the microphone airflow channel from the atomization channel. This helps solve the problem of condensation flowing back to the microphone, but the microphone airflow channel will increase the space occupied and affect the overall size of the atomizer.

[0004] Therefore, existing electronic atomization devices can only choose between the two structures mentioned above. Summary of the Invention

[0005] The purpose of this application is to provide an electronic atomizing device to solve the technical problems of the microphone airway structure in existing electronic atomizing devices occupying a large space and causing the microphone to be prone to water immersion risk.

[0006] To achieve the above objectives, the technical solution adopted in this application is as follows: This application provides an electronic atomizing device, including a body of the electronic atomizing device and an atomizer disposed on the body.

[0007] The body is equipped with a microphone and a detection airway. The microphone is used to receive the inhalation signal in the detection airway to control the opening and closing of the electronic atomizing device.

[0008] The atomizer is provided with a liquid storage chamber, an output pipe, an atomizing core, and a ventilation channel. The two ends of the atomizing core are respectively connected to the output pipe and the ventilation channel. The atomizing core is used to heat the aerosol matrix in the liquid storage chamber and produce aerosol that is output from the output pipe.

[0009] The atomizer is also provided with a ventilation hole and a vent hole, both of which are connected to the ventilation channel inside the atomizer; wherein, the ventilation hole is connected to the outside, and the vent hole is connected to the detection air channel on the main body.

[0010] The beneficial effects of the electronic atomizing device provided in this application are as follows: Compared with the prior art, the electronic atomizing device of this application has an air exchange channel inside the atomizer that communicates with the atomizing core and the output pipe, an air exchange hole on the side of the atomizer, and a vent hole at the bottom of the atomizer. The air exchange hole and the vent hole are connected to the air exchange channel from different positions. The air exchange hole communicates with the outside and is connected to the atomizing core and the output pipe through the air exchange channel. The vent hole is used to communicate with the detection air passage and microphone inside the main body of the electronic atomizing device when the atomizer is connected to it. Thus, the air exchange channel and the air exchange hole constitute a diversion air passage on the atomizer that can communicate with the outside. When the atomizer is used, such as during inhalation, outside air can enter the interior of the atomizer through the air exchange hole on the side of the atomizer and then pass through the air exchange channel, the atomizing core, and the output pipe before being output. As can be seen, gas does not flow through the detection airway inside the main body; only a negative pressure is formed in the detection airway. The microphone inside the main body can detect this negative pressure to ensure the on / off control of the electronic atomizer. Simultaneously, since there is no airflow in the detection airway inside the main body, condensation will not occur, effectively reducing the risk of water damage to the microphone. Furthermore, because a separate microphone airway is not required within the atomizer, it effectively saves internal space.

[0011] An improvement has been made to the waterproof structure inside the atomizer, wherein the vent on the atomizer is located outside the downward projection range of the atomizing core, thereby preventing condensate formed on the output pipe from dripping directly onto the vent after passing through the atomizing core. This helps to reduce the leakage of liquid from the bottom vent of the atomizer and reduces the impact on the microphone inside the atomizer.

[0012] Another improvement to the waterproof structure within the atomizer is made: an air vent tube communicating with the vent is provided inside the atomizer, and the bottom of the atomizer also has a water-receiving surface for catching condensate. The opening of the air vent tube inside the atomizer is higher than the water-receiving surface. This helps reduce the flow of condensate from the water-receiving surface into the air vent tube, thereby reducing the impact of condensate flowing into the detection air passage of the atomizer on the microphone.

[0013] In one embodiment, the air duct is further provided with a top cap at its opening inside the atomizer, and a through hole is formed on the side wall of the top cap. This top cap at the opening of the air duct helps prevent condensate from dripping directly into the air duct. The through hole on the side wall of the top cap ensures airflow, allowing the microphone to function properly.

[0014] A third improvement is made to the waterproof structure inside the atomizer: the inner bottom of the atomizer has a water-receiving surface for catching condensate, and a liquid-absorbing element is provided on the water-receiving surface of the atomizer to absorb condensate.

[0015] The internal structure of the atomizer is improved by including a separator and a mounting base. The separator divides the atomizer's interior into a ventilation chamber and a liquid storage chamber. The ventilation channel is formed inside the mounting base, and the atomizing core is mounted on the mounting base. A connection port is provided on the mounting base, and the ventilation chamber is connected to this connection port, sequentially connecting the ventilation port, the ventilation chamber, the ventilation channel within the mounting base, the atomizing core, and the output pipe. This integration of the liquid storage chamber and ventilation chamber within the atomizer, with the liquid storage chamber used to hold the aerosol matrix, effectively eliminates the assembly gaps that easily form after assembling the traditional mouthpiece and liquid storage section, thus ensuring the cleanliness and hygiene of the atomizer.

[0016] The mounting base has been improved by incorporating a baffle to prevent condensation from falling directly onto the bottom of the atomizer or the vent.

[0017] In one embodiment, the water baffle is an arched frame with its outer perimeter inclined outwards. This facilitates the discharge of collected condensate into all directions, thereby improving drainage efficiency.

[0018] In one embodiment, the atomizer further includes a pair of electrodes for electrical connection with the body, at least a portion of which is exposed at the bottom of the atomizer; the atomizing core includes a heating element with a pair of outwardly extending leads, which pass through flow guide holes on the baffle and connect to the pair of electrodes. Thus, by utilizing the flow guide holes on the baffle, the leads of the heating element can pass through the flow guide holes and connect to the electrodes, effectively reducing the connection stroke between the leads and electrodes, and contributing to a smaller overall size.

[0019] In one embodiment, the body further includes a power supply component, which includes a circuit board and a battery. The microphone is electrically connected to the circuit board. The body also has a pair of spring-loaded pins electrically connected to the circuit board. When the atomizer is installed on the body, the pair of spring-loaded pins contact a pair of electrodes on the atomizer. Thus, the atomizer can be used as a replaceable component, detachably mounted on the body of the electronic atomizing device, and allows the electrodes at the bottom of the atomizer to contact the spring-loaded pins on the body to achieve electrical connection, effectively achieving rapid battery life and improving the user experience. Attached Figure Description

[0020] 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.

[0021] Figure 1 A schematic diagram of the assembly structure of the atomizer and the body provided in the embodiments of this application;

[0022] Figure 2 Schematic diagram of the internal structure of the electronic atomizing device provided in the embodiments of this application Figure 1 ;

[0023] Figure 3 Schematic diagram of the internal structure of the atomizer provided in the embodiments of this application Figure 1 ;

[0024] Figure 4 Enlarged schematic diagram of the inner bottom part of the atomizer provided in the embodiments of this application. Figure 1 ;

[0025] Figure 5 Enlarged schematic diagram of the inner bottom part of the atomizer provided in the embodiments of this application. Figure 2 ;

[0026] Figure 6 Enlarged schematic diagram of the inner bottom part of the atomizer provided in the embodiments of this application. Figure 3 ;

[0027] Figure 7 Schematic diagram of the internal structure of the atomizer provided in the embodiments of this application Figure 2 ;

[0028] Figure 8 Schematic diagram of the internal structure of the atomizer provided in the embodiments of this application Figure 3 ;

[0029] Figure 9 This is a schematic diagram of the structure of the atomizing core mounted on the mounting base according to an embodiment of the present application;

[0030] Figure 10 A schematic diagram of the assembly structure of the atomizing core and the mounting base provided in the embodiments of this application;

[0031] Figure 11 Schematic diagram of the internal structure of the atomizing core and mounting base provided in the embodiments of this application Figure 1 ;

[0032] Figure 12 This is a three-dimensional structural diagram of the mounting base provided in the embodiments of this application;

[0033] Figure 13 Schematic diagram of the internal structure of the atomizing core and mounting base provided in the embodiments of this application Figure 2 ;

[0034] Figure 14 Schematic diagram of the internal structure of the electronic atomizing device provided in the embodiments of this application Figure 2 .

[0035] The following are the labeling elements in the figure:

[0036] 100 - Atomizer; 200 - Main unit;

[0037] 1-Mic head; 11-Airway detection;

[0038] 2-Liquid reservoir; 21-Divider;

[0039] 3-Output pipe; 31-Suction port;

[0040] 4-Atomizer core; 41-Electrode; 42-Heating element; 421-Pin;

[0041] 5-Ventilation channel; 51-Ventilation hole; 52-Ventilation port; 521-Ventilation pipe; 522-Top cap; 523-Through hole; 53-Water receiving surface; 54-Liquid suction component; 55-Ventilation chamber;

[0042] 6-Mounting base; 61-Connection port; 62-Sealing sleeve;

[0043] 7-Water baffle; 71-Flow guide hole;

[0044] 8-Power supply component; 81-Circuit board; 82-Battery; 83-Pin spring. Detailed Implementation

[0045] 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.

[0046] 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.

[0047] 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.

[0048] 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.

[0049] In related technologies, POD atomizers are generally divided into the following two types:

[0050] One type features a bottom-intake structure for the atomizer, with a vent at the bottom. The microphone airway and atomization channel share a common airway, connecting to the microphone within the main body of the electronic atomizer via the bottom vent, thus activating the microphone during use. With this design, air intake is at the bottom of the atomizer during inhalation. If condensation or leakage occurs inside the atomizer, it can easily seep out through the bottom vent and flow back down along the internal airway to the microphone, making the microphone more susceptible to water damage.

[0051] Another type uses a top-mounted air intake structure in the atomizer, with a separate microphone airflow channel inside. This allows the microphone airflow channel to be independent of the atomization channel. The lower end of the microphone airflow channel can directly connect to the microphone inside the main body, while the upper airflow port is located at the top of the atomizer and adjacent to the atomizer's inlet, thus triggering microphone activation during use. This type of atomizer requires a larger space and is more expensive because it necessitates a separate microphone airflow channel inside the atomizer.

[0052] Therefore, this application provides a novel electronic atomizing device that improves the airway structure in the atomizer, which can reduce the space occupied and reduce the risk of water immersion in the microphone caused by condensation. It effectively solves the problems of large space occupation and easy water immersion risk in the microphone airway structure of traditional electronic atomizing devices. It will now be described in detail.

[0053] Please see Figure 1An electronic atomizing device includes an atomizer 100 and a body 200 of the electronic atomizing device, with the atomizer 100 disposed on the body 200.

[0054] Please see Figure 2 The main body 200 is provided with a microphone 1 and a detection air channel 11 connected to the microphone 1. In this embodiment, the detection air channel 11 can preferably be formed by the mutual enclosure or reserved channel of the internal structure of the main body 200; in other embodiments, it is also preferable to provide a dedicated physical pipe in the main body 200 and let the pipe connect to the microphone 1.

[0055] The microphone 1 can preferably be an airflow sensor, which is used to receive and detect inhalation signals in the airway 11 to control the opening and closing of the electronic atomization device.

[0056] Please refer to the following: Figure 2 and Figure 3 The atomizer 100 is provided with a liquid storage chamber 2, an output pipe 3, an atomizing core 4 and an air exchange channel 5. The two ends of the atomizing core 4 are connected to the output pipe 3 and the air exchange channel 5 respectively. The atomizing core 4 is used to heat the aerosol matrix in the liquid storage chamber 2 and produce aerosol that is output from the output pipe 3.

[0057] The atomizer 100 is also provided with an air exchange hole 51 and an air vent 52, both of which are connected to the air exchange channel 5 inside the atomizer 100. In this embodiment, as... Figure 2 and Figure 3 As shown, the top of the atomizer 100 has a suction port 31 that communicates with the output pipe 3. An air vent 51 is located on the side of the atomizer 100 and communicates with the outside. An air vent 52 is located at the bottom of the atomizer 100, and when the atomizer 100 is mounted on the body 200, this air vent 52 communicates with the detection air passage 11 on the body 200.

[0058] As can be seen, inside the atomizer 100, the ventilation port 51 is connected to the atomizing core 4 through the ventilation channel 5, and the ventilation channel 5 is connected to the vent 52 located at the bottom of the atomizer 100, and is also connected to the microphone 1 located inside the main body 200 through the vent 52, so that the ventilation channel 5 and the branch channel of the ventilation port 51 constitute a split airflow channel on the atomizer 100. In this way, when the atomizer 100 is used (such as when the user is inhaling), air can enter from the ventilation port 51 on the side of the atomizer 100, and then be output from the atomizing core 4 and the output pipe 3 through the ventilation channel 5. During this process, the gas does not flow through the detection airflow channel 11 of the main body 200. Only a negative pressure is formed in the detection airflow channel 11 for the microphone 1 to detect, which helps to reduce condensation in the detection airflow channel 11.

[0059] Compared with the prior art, the electronic atomizing device provided in this application embodiment has an air exchange channel 5 inside the atomizer 100, which communicates with the atomizing core 4 and the output pipe 3. An air exchange hole 51 is opened on the side of the atomizer 100, and a vent hole 52 is opened at the bottom of the atomizer 100. The air exchange hole 51 and the vent hole 52 communicate with the air exchange channel 5 from different positions. The air exchange hole 51 communicates with the outside and is connected to the atomizing core 4 and the output pipe 3 through the air exchange channel 5. The vent hole 52 is used to communicate with the detection air passage 11 and the microphone 1 inside the body 200 of the electronic atomizing device when the atomizer 100 is connected to the body 200.

[0060] Therefore, as Figure 2 and Figure 3 As shown, the ventilation channel 5 and the ventilation hole 51 constitute a diversion airway on the atomizer 100 that can connect to the outside. When the atomizer 100 is used, such as during inhalation, outside air can enter the interior of the atomizer 100 through the ventilation hole 51 on the side of the atomizer 100, and then pass through the ventilation channel 5, the atomizing core 4, and the output pipe 3 in sequence before being output. It can be seen that the gas does not flow through the detection airway 11 inside the main body 200; only a negative pressure is formed in the detection airway 11. The microphone 1 can detect this negative pressure to ensure the opening and closing control of the electronic atomizing device. At the same time, since there is no airflow in the detection airway 11 inside the main body 200, condensation will not occur in the detection airway 11, effectively reducing the risk of water damage to the microphone 1.

[0061] Compared to the aforementioned related technologies that include a separate microphone airflow channel within the atomizer 100, this increases the internal space occupied by the atomizer 100 and is more expensive. In the electronic atomizing device of this application embodiment, a separate microphone airflow channel is not required within the atomizer 100, thus saving space. Only the ventilation hole 51 on the side of the atomizer 100 is connected to the ventilation channel 5, which in turn connects to the atomizing core 4 and the output pipe 3, forming a semi-independent split airflow channel within the atomizer 100. This split airflow channel alters the airflow direction during use, preventing the airflow from passing through the detection airflow channel 11 within the main body 200. This creates negative pressure in the detection airflow channel 11, ensuring normal operation of the microphone 1 and effectively reducing condensation in the detection airflow channel 11, thus eliminating the risk of water damage to the microphone 1.

[0062] In practical applications, for the electronic atomizing device provided in this application embodiment, the condensation on the atomizer 100 is mainly formed in the atomizing core 4 and the output pipe 3. After the condensate is formed in the output pipe 3, it passes through the atomizing core 4 and drips to the bottom of the atomizer 100, and then flows back from the vent 52 at the bottom of the atomizer 100 to the detection air passage 11 in the main body 200. This condensate flowing back to the detection air passage 11 can easily affect the microphone 1.

[0063] Therefore, the atomizer 100 in this embodiment of the application is provided with a waterproof structure for condensation, which includes, but is not limited to, the following forms:

[0064] In one embodiment of this application (not shown in the figure), the vent 52 on the bottom of the atomizer 100 is located outside the downward projection range of the atomizing core 4.

[0065] Specifically, it is preferable to open the vent 52 outside the downward vertical projection range of the atomizing core 4, so as to prevent the condensate formed on the output pipe 3 from dripping directly onto the vent 52 after passing through the atomizing core 4, and from seeping out or flowing back to the detection air channel 11 of the main body 200, which helps to reduce the leakage of the atomizer 100 or the impact on the microphone 1.

[0066] In another embodiment of this application, please refer to [the relevant document / reference]. Figure 3 and Figure 4 The atomizer 100 has an internal ventilation tube 521 that communicates with the ventilation hole 52. The ventilation tube 521 extends from the ventilation hole 52 into the interior of the atomizer 100. The inner bottom of the atomizer 100 also has a water-receiving surface 53 for catching condensate. This can be understood as the atomizer 100 having an inner bottom surface facing the atomizing core 4, which can catch condensate dripping from the output pipe 3 and the atomizing core 4.

[0067] Specifically, the opening of the air vent 521 inside the atomizer 100 is higher than the water inlet surface 53. In particular, the protrusion of the air vent 521 at the bottom of the atomizer 100 is higher than the water inlet surface 53 at the bottom of the atomizer 100.

[0068] Therefore, by using the setting that the opening of the air pipe 521 inside the atomizer 100 is higher than the water receiving surface 53, it is beneficial to reduce the flow of condensate on the water receiving surface 53 into the air pipe 521, thereby reducing the impact of condensate flowing into the detection air channel 11 of the main body 200 on the microphone 1.

[0069] Preferably, please refer to the following: Figure 5 and Figure 6 The ventilation pipe 521 is also provided with a top cap 522 on the pipe opening inside the atomizer 100, and a through hole 523 is provided on the side wall of the top cap 522.

[0070] In this embodiment, the top cap 522 is installed on the opening of the vent pipe 521, similar to a cover, to prevent condensate from dripping into the vent pipe 521. A through hole 523 is provided on the side wall of the top cap 522 to ensure airflow, thereby allowing the microphone 1 to function normally.

[0071] Please refer to the third embodiment of this application as well. Figure 3 and Figure 6 The inner bottom of the atomizer 100 has a water receiving surface 53 for catching condensate, which is as understood above and will not be described again here.

[0072] The atomizer 100 has a liquid-absorbing component 54 on its water-receiving surface 53. In this embodiment, the liquid-absorbing component 54 can preferably be made of absorbent cotton, which absorbs condensate and effectively reduces the flow of condensate into the vent 52, thereby eliminating the risk of water damage to the microphone 1.

[0073] It should be noted that two or more of the above three embodiments can be selectively combined to form a composite waterproof structure, thereby effectively preventing condensate from leaking into the vent 52.

[0074] Regarding the internal structure of the atomizer 100, please refer to one embodiment of this application. Figure 7 The atomizer 100 also includes a separator 21 and a mounting base 6. The separator 21 divides the interior of the atomizer 100 into an air exchange chamber 55 and the aforementioned liquid storage chamber 2. The air exchange channel 5 is formed inside the mounting base 6, and the atomizing core 4 is mounted on the mounting base 6.

[0075] The mounting base 6 has a connection port 61, and the extension end of the air exchange chamber 55 is connected to the connection port 61 of the mounting base 6, so that the air exchange hole 51, the air exchange chamber 55, the air exchange channel 5 in the mounting base 6, the atomizing core 4 and the output pipe 3 are connected in sequence.

[0076] In this way, the atomizer 100 integrates a liquid storage chamber 2 and an air exchange chamber 55. The liquid storage chamber 2 is used to load the aerosol matrix. This is equivalent to molding the mouthpiece and the liquid storage chamber 2 into one piece, effectively eliminating the assembly gaps that are easily formed after assembling the mouthpiece and the liquid storage part in the traditional way. It also solves the problem that aerosol matrix can easily accumulate in these gaps, causing dirt to be easily absorbed and affecting the use. This ensures the cleanliness of the atomizer 100 and improves the user experience.

[0077] Preferably, in this embodiment, such as Figure 8 As shown, the volume of the ventilation chamber 55 is smaller than that of the liquid storage chamber 2. The ventilation chamber 55 is housed inside the liquid storage chamber 2, which helps to increase the usable space of the liquid storage chamber 2, thereby increasing the volume of the liquid storage chamber 2 that can hold the aerosol matrix.

[0078] In other embodiments (not shown), the ventilation chamber 55 and the liquid storage chamber 2 may be evenly distributed within the internal space of the atomizer 100. Furthermore, functional components are installed within the enlarged ventilation chamber 55.

[0079] As an example, an adjusting element (not shown in the figure) can be provided in the ventilation chamber 55. The adjusting element is preferably a sliding switch provided on the ventilation hole 51. The adjusting element has an adjusting hole for alignment with the ventilation hole 51. The adjusting element can be operated by hand to move on the ventilation hole 51, thereby changing the conduction range of the ventilation hole 51 and realizing flexible adjustment of the suction resistance when the user uses it, which is beneficial to improving the user experience.

[0080] In one embodiment of this application, please refer to the following: Figure 7 , Figure 9 and Figure 10 The mounting base 6 also includes a sealing sleeve 62 made of a sealing material such as silicone. The atomizing core 4 is disposed on the sealing sleeve 62 and is connected and fixed to the mounting base 6 through the sealing sleeve 62.

[0081] In this embodiment, please refer to Figure 7 and Figure 9 As shown, one side of the sealing sleeve 62 is misaligned with the side of the mounting base 6, and has the aforementioned connection port 61 for connecting the ventilation chamber 55. This allows the extended end of the ventilation chamber 55 to be connected to the mounting base 6 and to be in close contact with the sealing sleeve 62.

[0082] Therefore, by using the sealing sleeve 62 on the mounting base 6, it is beneficial to fill the leakage gaps between the various connecting parts, thereby improving the sealing effect and effectively preventing the leakage of aerosol matrix in the liquid storage chamber 2.

[0083] In another embodiment of this application, to further prevent condensate from falling into the bottom of the atomizer 100 and reaching the vent 52, a waterproof structure can be added to the mounting base 6. Please refer to [further details omitted]. Figure 11 and Figure 12 The mounting base 6 also has a baffle 7 for blocking condensate, and the baffle 7 has a guide hole 71 to ensure smooth airflow.

[0084] In this embodiment, the water baffle 7 can be set between the atomizing core 4 and the ventilation channel 5. Specifically, it can preferably be set at the connection between the atomizing core 4 and the ventilation channel 5. The baffle 7 can prevent condensed water from falling directly onto the bottom of the atomizer 100 or the ventilation hole 52.

[0085] Preferably, the water baffle 7 on the mounting base 6 is an arched frame, with the middle of the water baffle 7 arching upwards and the outer periphery of the water baffle 7 inclined outwards, which facilitates the discharge of collected condensate water to all sides, thereby improving the drainage effect. In this embodiment, the water baffle 7 can preferably be a spherical arched structure, with the outer periphery of the water baffle 7 smoothly transitioning outwards, so that the water can flow smoothly to all sides and be discharged away.

[0086] In other embodiments (not shown in the figure), the water baffle 7 can also be a conical structure with an arched center. The outer periphery of the water baffle 7 is inclined outward in a straight line, which helps to accelerate the flow rate of the water and allow the condensate on the water baffle 7 to be drained away quickly.

[0087] like Figure 12 As shown, the baffle frame 7 has multiple guide holes 71 evenly distributed on its frame. Preferably, the multiple guide holes 71 on the baffle frame 7 can be symmetrically arranged on the baffle frame 7, which is beneficial to improving the uniformity and smoothness of gas flow and effectively ensuring the suction effect.

[0088] Because a water baffle 7 is provided on the mounting base 6, the connection structure between the atomizing core 4 and the mounting base 6 needs to be improved. Please refer to one embodiment of this application for further details. Figure 10 , Figure 13 and Figure 14 The atomizer 100 also includes a pair of electrodes 41, at least a portion of which is exposed at the bottom of the atomizer 100, and which are used for electrical connection with the body 200 of the electronic atomizing device.

[0089] The atomizing core 4 includes a heating element 42, which has a pair of outwardly extending pins 421. The pair of pins 421 pass through the guide holes 71 on the water baffle 7 and are connected to the pair of electrodes 41.

[0090] In this way, by utilizing the guide hole 71 on the water baffle 7, the pin 421 of the heating element 42 can pass through the guide hole 71 and connect with the electrode 41, avoiding the pin 421 from being wound to other parts before connecting with the electrode 41, effectively reducing the connection stroke between the pin 421 and the electrode 41, thereby simplifying the connection structure, reducing the space occupied, and helping to reduce the overall volume.

[0091] In one embodiment of this application, please refer to the following: Figure 13 and Figure 14The electronic atomizing device body 200 provided in this application embodiment also includes a power supply component 8, which includes a circuit board 81 and a battery 82 that provides power to the atomizer 100 of this application embodiment. The microphone 1 in the body 200 is electrically connected to the circuit board 81. In this embodiment, the microphone 1 can preferably be disposed on the circuit board 81, which is beneficial to saving the connection structure between the microphone 1 and the circuit board 81 and improving the fixing effect of the microphone 1; in other embodiments, a traditional structure in which the microphone 1 is electrically connected to the circuit board 81 via a cable can also be used.

[0092] The main body 200 is also provided with a pair of spring pins 83 electrically connected to the circuit board 81. The pair of spring pins 83 can preferably be common spring pin connectors. The pair of spring pins 83 correspond to the positions of a pair of electrodes 41 on the atomizer 100, and when the atomizer 100 is installed on the main body 200, the pair of spring pins 83 contact the pair of electrodes 41 on the atomizer 100, realizing the electrical connection between the atomizer 100 and the main body 200.

[0093] This allows the atomizer 100 to be used as a replacement part, detachably mounted on the main body 200 of the electronic atomizing device, and enables the electrode 41 at the bottom of the atomizer 100 to contact the spring pin 83 on the main body 200 to achieve electrical connection. In actual use, when the liquid in the reservoir 2 is depleted, the atomizer 100 can be removed from the main body 200 and replaced with a new atomizer 100 for continued use, effectively achieving rapid battery life and improving the user experience.

[0094] 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 electronic atomizing device, comprising a body of the electronic atomizing device and an atomizer disposed on the body, characterized in that: The body is equipped with a microphone and a detection airway. The microphone is used to receive the inhalation signal in the detection airway to control the opening and closing of the electronic atomizing device. The atomizer is provided with a liquid storage chamber, an output pipe, an atomizing core, and a ventilation channel. The two ends of the atomizing core are respectively connected to the output pipe and the ventilation channel. The atomizing core is used to heat the aerosol matrix in the liquid storage chamber and produce aerosol that is output from the output pipe. The atomizer is also provided with a ventilation hole and a vent hole, both of which are connected to the ventilation channel inside the atomizer; wherein, the ventilation hole is connected to the outside, and the vent hole is connected to the detection air channel on the main body.

2. The electronic atomizing device according to claim 1, characterized in that: The vent on the atomizer is located outside the downward projection range of the atomizing core.

3. The electronic atomizing device according to claim 1, characterized in that: The atomizer has an internal ventilation pipe that communicates with the ventilation hole. The bottom of the atomizer also has a water receiving surface for catching condensate. The opening of the ventilation pipe inside the atomizer is higher than the water receiving surface.

4. The electronic atomizing device according to claim 3, characterized in that: The ventilation tube is also provided with a top cap on the opening inside the atomizer, and a through hole is provided on the side wall of the top cap.

5. The electronic atomizing device according to claim 1, characterized in that: The atomizer has a water-receiving surface at its inner bottom for catching condensate, and a liquid-absorbing element is provided on the water-receiving surface of the atomizer.

6. The electronic atomizing device according to any one of claims 1 to 5, characterized in that: The atomizer also includes a separator and a mounting base. The separator divides the interior of the atomizer into a ventilation chamber and a liquid storage chamber. The ventilation channel is formed inside the mounting base, and the atomizing core is disposed on the mounting base. The mounting base has a connection port, and the ventilation chamber is connected to the connection port of the mounting base, so that the ventilation port, the ventilation chamber, the ventilation channel in the mounting base, the atomizing core, and the output pipe are sequentially connected.

7. The electronic atomizing device according to claim 6, characterized in that: The mounting base has a baffle for blocking condensate, and the baffle has a flow guide hole.

8. The electronic atomizing device according to claim 7, characterized in that: The water-blocking frame is an arched frame, and the outer periphery of the water-blocking frame is inclined outward.

9. The electronic atomizing device according to claim 7, characterized in that: The atomizer also includes a pair of electrodes for electrical connection with the body, at least a portion of which is exposed at the bottom of the atomizer; the atomizing core includes a heating element with a pair of outwardly extending pins, which pass through flow guide holes on the baffle and are connected to the pair of electrodes.

10. The electronic atomizing device according to claim 9, characterized in that: The body also includes a power supply component, which includes a circuit board and a battery. The microphone is electrically connected to the circuit board. The body is also provided with a pair of spring pins electrically connected to the circuit board. When the atomizer is installed on the body, the pair of spring pins contact a pair of electrodes on the atomizer.

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