Conductive air intake atomizing mechanism and aerosol generating device

By designing a conductive air intake atomization mechanism, the problems of long assembly time and complicated assembly steps in traditional aerosol generators are solved, enabling rapid and automated assembly and reducing the number of parts and wiring harnesses.

CN115153107BActive Publication Date: 2026-06-23SHENZHEN AEROSOL TECH RES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SHENZHEN AEROSOL TECH RES CO LTD
Filing Date
2022-08-17
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Traditional aerosol generators have many electronic components and wiring harnesses, resulting in long assembly times and complicated assembly steps, which is not conducive to automated assembly.

Method used

Design a conductive air intake atomizing mechanism, including a conductive flow guiding integrated component, a microphone, and a central atomizing component. The microphone is set in the trigger chamber, the central atomizing component is snapped into the conductive flow guiding integrated component, and the atomizing core is electrically connected to the conductive flow guiding integrated component, so as to achieve rapid assembly and reduce wiring.

Benefits of technology

It enables rapid and automated assembly of aerosol generators, reducing the number of parts and wiring harnesses and improving assembly efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a conductive air inlet atomization mechanism and an aerosol generating device. The conductive air inlet atomization mechanism is connected with a shell and a liquid storage assembly respectively. The conductive air inlet atomization mechanism comprises a conductive flow guide integrated assembly, a microphone element and a central atomization assembly. The conductive flow guide integrated assembly is installed in the shell. The conductive flow guide integrated assembly is formed with an air inlet hole, a trigger cavity and an airflow channel. The trigger cavity is in communication with the air inlet hole and the airflow channel. The microphone element is arranged in the trigger cavity and is electrically connected with the conductive flow guide integrated assembly. One end of the central atomization assembly is clamped to the conductive flow guide integrated assembly. The central atomization assembly is arranged through the liquid storage assembly to jointly form a liquid storage cavity with the liquid storage assembly. The central atomization assembly comprises an atomization core, thereby reducing the number of parts of the aerosol generating device. Since the atomization core is electrically connected with the conductive flow guide integrated assembly, the wire harness of the aerosol generating device can be reduced, and the automatic assembly of the aerosol generating device is facilitated.
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Description

Technical Field

[0001] This invention relates to the field of electronic atomization technology, and in particular to a conductive air intake atomization mechanism and an aerosol generating device. Background Technology

[0002] Traditional aerosol generators have numerous electronic components, most of which are electrically connected via wiring harnesses, resulting in a large number of wiring bundles. This leads to lengthy assembly times and complex steps, hindering automated assembly. Summary of the Invention

[0003] The purpose of this invention is to overcome the shortcomings of the prior art and provide a conductive air intake atomizing mechanism and aerosol generating device that can be assembled quickly and has fewer assembly steps.

[0004] The objective of this invention is achieved through the following technical solution:

[0005] A conductive air intake atomizing mechanism is provided for connection to a housing and a liquid storage assembly, respectively. The conductive air intake atomizing mechanism includes:

[0006] A conductive flow guiding integrated assembly is used to be installed in a housing. The conductive flow guiding integrated assembly has an air inlet, a trigger cavity, and an airflow channel. The trigger cavity is connected to the air inlet and the airflow channel respectively.

[0007] The microphone head is disposed within the trigger cavity and electrically connected to the conductive current-guiding integrated component;

[0008] A central atomizing component, one end of which is snapped into the conductive flow guiding integrated component, is used to pass through the liquid storage component to form a liquid storage cavity together with the liquid storage component. The central atomizing component includes an atomizing core, which is electrically connected to the conductive flow guiding integrated component. The atomizing cavity within the atomizing core is connected to the airflow channel. The atomizing core is used to heat and atomize the atomized liquid discharged from the liquid storage cavity.

[0009] In one embodiment, the air inlet is located at the periphery of the conductive flow-guiding integrated component.

[0010] In one embodiment, the conductive flow guiding integrated component further forms a first flow passage, which is connected to the trigger cavity and the airflow channel respectively;

[0011] The conductive flow guiding integrated component also has a trigger hole, which is connected to the air inlet and the trigger cavity respectively.

[0012] In one embodiment, the trigger hole is formed on the end face of the first end of the conductive current guiding integrated component, and the central atomizing component is snapped onto the first end of the conductive current guiding integrated component.

[0013] In one embodiment, both the first flow passage and the airflow channel are formed on the end face of the second end of the conductive flow guiding integrated component;

[0014] The conductive air intake atomizing mechanism also includes a sealing gasket, which abuts against the end face of the second end of the conductive flow guiding integrated component.

[0015] In one embodiment, the conductive flow guiding integrated component further forms a through air channel, the through air channel being connected to both the airflow channel and the atomizing chamber; and / or,

[0016] The conductive flow guiding integrated component also has a second flow passage, which is connected to the air inlet and the airflow channel respectively.

[0017] In one embodiment, the conductive current-guiding integrated assembly includes a printed circuit board and a current-guiding cover;

[0018] The flow guide is disposed on the printed circuit board, and both the printed circuit board and the flow guide are used to be installed inside the housing; the air inlet includes a first air inlet opened in the flow guide and a second air inlet opened in the printed circuit board, and the first air inlet and the second air inlet are connected.

[0019] The microphone head is disposed on one side of the printed circuit board and electrically connected to the printed circuit board; the central atomizing component is snapped onto the side of the printed circuit board opposite to the flow guide.

[0020] The trigger cavity and the airflow channel are both formed in the flow guide shroud; the flow guide shroud also has a first intermediate through hole, and the printed circuit board has a second intermediate through hole. The first intermediate through hole is connected to the airflow channel, and the second intermediate through hole is connected to the first intermediate through hole and the atomizing cavity respectively.

[0021] An aerosol generator includes a housing, a liquid storage component, a battery rod assembly, and a conductive air intake atomizing mechanism as described in any of the above embodiments. The housing has a mounting groove, the liquid storage component is located in the mounting groove and connected to the housing, the conductive flow guiding integrated component is located in the mounting groove and connected to the housing, the central atomizing component passes through the liquid storage component to form a liquid storage cavity together with the liquid storage component, and the atomizing core is used to heat and atomize the atomized liquid discharged from the liquid storage cavity; the battery rod assembly is located in the mounting groove and connected to the housing, and the battery rod assembly is electrically connected to the atomizing core.

[0022] In one embodiment, the liquid storage assembly includes a first seal and a second seal, both of which are located within the mounting groove and are sealed to the housing. Both the first and second seals are fitted onto the central atomizing assembly, and the first seal, the second seal, and the central atomizing assembly together form the liquid storage cavity. The conductive flow guiding integrated assembly abuts against the second seal, and a flow guiding cavity exists between the conductive flow guiding integrated assembly and the second seal. The air inlet communicates with the trigger cavity through the flow guiding cavity.

[0023] In one embodiment, the first seal has an air outlet and a insertion groove, the insertion groove surrounding the air outlet and communicating with the atomizing chamber, and the end of the central atomizing component furthest from the conductive flow guiding integrated component is inserted into the insertion groove; and / or

[0024] The liquid storage assembly further includes a liquid storage element disposed within the liquid storage cavity.

[0025] Compared with the prior art, the present invention has at least the following advantages:

[0026] The aforementioned conductive air intake atomizing mechanism, with the microphone element located within the trigger chamber of the conductive flow guiding integrated component and one end of the central atomizing component snapped into the conductive flow guiding integrated component, integrates and fixes both the microphone element and the central atomizing component onto the conductive flow guiding integrated component, facilitating rapid assembly and reducing the number of parts in the aerosol generator. Furthermore, the electrical connection between the atomizing core and the conductive flow guiding integrated component reduces the wiring harness of the aerosol generator, thus facilitating automated assembly of the aerosol generator. Attached Figure Description

[0027] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of the present invention and should not be regarded as a limitation on the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.

[0028] Figure 1 This is a schematic diagram of an aerosol generating device according to one embodiment;

[0029] Figure 2 for Figure 1 A cross-sectional view of the aerosol generator shown.

[0030] Figure 3 for Figure 1 Another cross-sectional view of the aerosol generator shown;

[0031] Figure 4 for Figure 1 Exploded view of the aerosol generator shown;

[0032] Figure 5 for Figure 2 A sectional view of the aerosol generator shown along line AA;

[0033] Figure 6 for Figure 2 The BB line cross-sectional view of the aerosol generator shown. Detailed Implementation

[0034] To facilitate understanding of the present invention, a more complete description will be given below with reference to the accompanying drawings. Preferred embodiments of the invention are shown in the drawings. However, the invention can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a thorough and complete understanding of the disclosure of the invention.

[0035] It should be noted that when an element is referred to as being "fixed to" another element, it can be directly attached to the other element or there may be an intervening element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or there may be an intervening element. The terms "vertical," "horizontal," "left," "right," and similar expressions used herein are for illustrative purposes only and do not represent the only possible implementation.

[0036] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.

[0037] This application provides a conductive air intake atomizing mechanism for connection to a housing and a liquid storage component; and / or, the conductive air intake atomizing mechanism includes a conductive flow guiding integrated component, a microphone element, and a central atomizing component; and / or, the conductive flow guiding integrated component is installed inside the housing; and / or, the conductive flow guiding integrated component forms an air intake hole, a trigger cavity, and an airflow channel; and / or, the trigger cavity is connected to the air intake hole and the airflow channel; and / or, the microphone element is disposed in the trigger cavity and integrated with the conductive flow guiding component. The components are electrically connected; and / or, one end of the central atomizing component is snapped into the conductive flow guiding integrated component; and / or, the central atomizing component is used to pass through the liquid storage component to form a liquid storage cavity together with the liquid storage component; and / or, the central atomizing component includes an atomizing core; and / or, the atomizing core is electrically connected to the conductive flow guiding integrated component; and / or, the atomizing cavity in the atomizing core is connected to the airflow channel; and / or, the atomizing core is used to heat and atomize the atomized liquid discharged from the liquid storage cavity.

[0038] The aforementioned conductive air intake atomizing mechanism, because its trigger chamber is connected to both the air intake port and the airflow channel, allows external airflow to flow into the trigger chamber through the air intake port to trigger the microphone, thus enabling the aerosol generator to start automatically. Furthermore, because the airflow channel is connected to the atomization chamber, the conductive air intake atomizing mechanism reliably intakes and atomizes air. Therefore, the conductive air intake atomizing mechanism has at least the functions of air intake, conductivity, and atomization. Since the microphone is located within the trigger chamber of the conductive flow guiding integrated component, and one end of the central atomizing component is snapped into the conductive flow guiding integrated component, both the microphone and the central atomizing component are integrated and fixed onto the conductive flow guiding integrated component, facilitating rapid assembly and reducing the number of parts in the aerosol generator. Because the atomizing core is electrically connected to the conductive flow guiding integrated component, the wiring harness of the aerosol generator can be reduced, which is beneficial for the automated assembly of the aerosol generator.

[0039] To better understand the technical solution and beneficial effects of this application, the following detailed description is provided in conjunction with specific embodiments:

[0040] like Figures 1 to 3 As shown, an embodiment of the aerosol generator 10 includes a housing 100, a liquid storage assembly 200, a battery rod assembly 300, and a conductive air intake atomizing mechanism 400. The housing 100 has a mounting groove 102, and the liquid storage assembly 200 is located within the mounting groove 102 and connected to the housing 100. In one embodiment, the conductive air intake atomizing mechanism 400 is located within the mounting groove 102 and connected to the housing 100. The conductive air intake atomizing mechanism 400 is used to connect to both the housing 100 and the liquid storage assembly 200. The conductive air intake atomizing mechanism 400 includes a conductive flow guiding integrated assembly 410, a microphone assembly 420, and a central atomizing assembly 430.

[0041] In one embodiment, the conductive current guiding integrated assembly 410 is used for mounting within the housing 100. In this embodiment, the conductive current guiding integrated assembly 410 is located within the mounting groove 102 and connected to the housing 100. The conductive current guiding integrated assembly 410 has an air inlet 402, a trigger cavity 404, and an airflow channel 406, with the trigger cavity 404 communicating with both the air inlet 402 and the airflow channel 406. The microphone element 420 is disposed within the trigger cavity 404 and electrically connected to the conductive current guiding integrated assembly 410.

[0042] In one embodiment, one end of the central atomizing component 430 is snapped into the conductive flow guiding integrated component 410. The central atomizing component 430 is used to pass through the liquid storage component 200 to form a liquid storage cavity 202 together with the liquid storage component 200. The central atomizing component 430 includes an atomizing core 432, which is electrically connected to the conductive flow guiding integrated component 410. The atomizing cavity 4322 within the atomizing core 432 is connected to the airflow channel 406. The atomizing core 432 is used to heat and atomize the atomized liquid discharged from the liquid storage cavity 202. When airflow flows into the trigger cavity 404 through the air inlet 402, the microphone 420 is triggered by the airflow to generate a trigger signal. The trigger signal is transmitted to the conductive flow guiding integrated component 410, which controls the atomizing core 432 to work, enabling the atomizing core 432 to heat and atomize the atomized liquid discharged from the liquid storage cavity 202.

[0043] Furthermore, the central atomizing component 430 is inserted into the liquid storage component 200 to form a liquid storage chamber 202 together with the liquid storage component 200. The atomizing core 432 is used to heat and atomize the atomized liquid discharged from the liquid storage chamber 202. The battery rod assembly 300 is located in the mounting groove 102 and connected to the housing 100. The battery rod assembly 300 is electrically connected to the atomizing core 432, so that the atomizing core 432 heats and atomizes the atomized liquid.

[0044] The aforementioned conductive air intake atomizing mechanism 400 and aerosol generating device, since the trigger chamber 404 is connected to the air inlet 402 and the airflow channel 406 respectively, allow external airflow to flow into the trigger chamber 404 through the air inlet 402 to trigger the microphone 420, thereby automatically starting the aerosol generating device 10. Furthermore, since the airflow channel 406 is connected to the atomization chamber 4322, the conductive air intake atomizing mechanism 400 reliably intakes and atomizes air. Thus, the conductive air intake atomizing mechanism 400 at least has the functions of air intake, conductivity, and atomization; because the microphone... The component 420 is disposed in the trigger cavity 404 of the conductive current guiding integrated assembly 410, and one end of the central atomizing component 430 is snapped into the conductive current guiding integrated assembly 410, so that the microphone component 420 and the central atomizing component 430 are both integrated and fixed on the conductive current guiding integrated assembly 410, so as to facilitate rapid assembly and reduce the number of parts of the aerosol generator 10. Since the atomizing core 432 is electrically connected to the conductive current guiding integrated assembly 410, the wiring harness of the aerosol generator 10 can be reduced, which is conducive to realizing the automated assembly of the aerosol generator 10.

[0045] like Figure 3 As shown, the conductive flow guiding integrated component 410 further abuts against the liquid storage component 200, and a flow guiding cavity 411 is formed between the conductive flow guiding integrated component 410 and the liquid storage component 200. The flow guiding cavity 411 is connected to the air inlet 402 and the trigger cavity 404 respectively, so that the air inlet 402 and the trigger cavity 404 are connected.

[0046] like Figure 2 and Figure 4 As shown, in one embodiment, the air inlet 402 is located at the periphery of the conductive current guiding integrated component 410, enabling reliable air intake into the conductive current guiding integrated component 410 while reducing the processing difficulty of the air inlet 402. It is understood that in other embodiments, the air inlet 402 is not limited to being located at the periphery of the conductive current guiding integrated component 410. For example, the air inlet 402 may be located near the periphery of the conductive current guiding integrated component 410.

[0047] like Figures 2 to 4 As shown, in one embodiment, the conductive current guiding integrated component 410 further forms a first flow passage 403, which is connected to the trigger cavity 404 and the airflow channel 406 respectively, so that the trigger cavity 404 is connected to the airflow channel 406.

[0048] like Figures 2 to 4 As shown, in one embodiment, the conductive flow guiding integrated component 410 also forms a trigger hole 408, which is connected to the air inlet 402 and the trigger cavity 404 respectively, so that the air inlet 402 is connected to the trigger cavity 404 through the trigger hole 408, thereby allowing the airflow flowing into the trigger cavity 404 to better trigger the microphone component 420.

[0049] like Figures 2 to 4 As shown, in one embodiment, a trigger hole 408 is formed on the end face of the first end of the conductive current guiding integrated component, and the central atomizing component 430 is snapped onto the first end of the conductive current guiding integrated component 410, so that the central atomizing component 430 is snapped onto the conductive current guiding integrated component 410, while facilitating the processing of the trigger hole 408.

[0050] like Figure 2 and Figure 5 As shown, in one embodiment, both the first flow-through hole 403 and the airflow channel 406 are formed on the end face of the second end of the conductive flow-guiding integrated component, making the processing difficulty of the first flow-through hole 403 and the airflow channel 406 lower, and allowing the first flow-through hole 403 and the airflow channel 406 to be separately opened from the trigger hole 408. In one embodiment, the conductive air intake atomizing mechanism 400 also includes a sealing gasket 440, which abuts against the end face of the second end of the conductive flow-guiding integrated component, so that the sealing gasket 440 and the conductive flow-guiding integrated component together form a reliable airflow channel 406. In this embodiment, the airflow channel 406 plays the role of guiding airflow, and the sealing gasket 440 abuts against the end face of the second end of the conductive flow-guiding integrated component, avoiding the problem of poor airflow guidance caused by the direct exposure of the airflow channel 406, while reducing the processing difficulty of the first flow-through hole 403 and the airflow channel 406.

[0051] like Figure 2 and Figure 6 As shown, the airflow channel 406 further includes an annular channel 4062 and an intermediate air guide channel 4064. The annular channel 4062 is circumferentially arranged along the end face of the second end of the conductive flow guiding integrated assembly 410. The annular channel 4062 communicates with the first flow passage 403, and the intermediate air guide channel 4064 communicates with both the annular channel 4062 and the atomizing chamber 4322, so that the airflow channel 406 communicates with both the first flow passage 403 and the atomizing chamber 4322. In this embodiment, a positioning groove 412 is provided on the end face of the second end of the conductive flow guiding integrated assembly 410. The positioning groove 412 communicates with both the annular channel 4062 and the atomizing chamber 4322, and the sealing gasket 440 is located in the positioning groove 412 and abuts against the conductive flow guiding integrated assembly 410.

[0052] like Figure 2 , Figure 3 , Figure 5 and Figure 6As shown, in one embodiment, the conductive flow guiding integrated component 410 further forms a through air channel 413, which is connected to the airflow channel 406 and the atomizing chamber 4322 respectively, so that the airflow channel 406 and the atomizing chamber 4322 are connected. Thus, the airflow, when flowing into the atomizing chamber 4322, must pass through a "labyrinthine" airflow channel consisting of the air inlet 402, the trigger hole 408, the trigger chamber 404, the first flow hole 403, the annular flow channel 4062, the intermediate air guide channel 4064, and the through air channel 413, thereby achieving reliable start-up and air intake of the aerosol generator 10. In this embodiment, the through air channel 413 is connected to the intermediate air guide channel 4064, so that the through air channel 413 is connected to the airflow channel 406. And / or,

[0053] like Figure 2 and Figure 5 As shown, in one embodiment, the conductive flow guiding integrated component 410 further forms a second flow passage 409. The second flow passage is connected to both the air inlet and the airflow channel, allowing direct communication between the air inlet and the airflow channel for normal operation and improving the reliability of the aerosol generator. In this embodiment, the second flow passage is connected to both the trigger chamber and the flow guiding chamber. Specifically, the second flow passage is offset from the microphone, while the trigger hole is directly opposite the microphone.

[0054] like Figure 3 and Figure 4 As shown, the conductive flow-guiding integrated assembly 410 further includes a printed circuit board 410a and a flow-guiding cover 410b. The flow-guiding cover 410b is disposed over the printed circuit board 410a, and both the printed circuit board 410a and the flow-guiding cover 410b are installed within the housing 100. The air inlet 402 includes a first air inlet 402a formed in the flow-guiding cover 410b and a second air inlet 402b formed in the printed circuit board 410a. The first air inlet 402a and the second air inlet 402b communicate with each other, and the second air inlet 402b communicates with the flow-guiding cavity 411. In this embodiment, the printed circuit board 410a abuts against the liquid storage assembly 200, and the flow-guiding cavity 411 is formed between the printed circuit board 410a and the liquid storage assembly 200.

[0055] like Figure 3 and Figure 4As shown, the microphone 420 is further disposed on one side of the printed circuit board 410a and electrically connected to the printed circuit board 410a, so that the microphone 420 is integrated and mounted on the printed circuit board 410a, further reducing the amount of wiring harness used in the aerosol generator 10. The central atomizing component 430 is snapped onto the side of the printed circuit board 410a opposite to the flow guide 410b. The trigger cavity 404 and the airflow channel 406 are both formed in the flow guide 410b. Since the flow guide 410b covers the printed circuit board 410a, the printed circuit board 410a covers the trigger cavity 404, which also facilitates the processing of the trigger cavity 404. The air guide shroud 410b also has a first intermediate through hole 4102, and the printed circuit board 410a has a second intermediate through hole 4104. The first intermediate through hole 4102 is connected to the airflow channel 406, and the second intermediate through hole 4104 is connected to the first intermediate through hole 4102 and the atomizing chamber 4322 respectively. The second intermediate through hole 4104 and the first intermediate through hole 4102 are connected to form a through air channel 413, so that the airflow channel 406 is connected to the atomizing chamber 4322.

[0056] like Figure 3 and Figure 4 As shown, further, a leak-proof groove 4106 is provided on the side of the flow guide 410b adjacent to the printed circuit board 410a. A retaining flange 4107 protrudes from the inner peripheral wall of the leak-proof groove 4106, surrounding the first intermediate through-hole 4102. The leak-proof groove 4106 serves to collect and prevent condensation, thus preventing condensation in the atomizing chamber 4322 from flowing directly through the first intermediate through-hole 4102 along the second intermediate through-hole 4104, which could cause a short circuit in the battery assembly 300 and thus prevent damage to the battery assembly 300. Furthermore, the first intermediate through-hole 4102 and the second intermediate through-hole 4104 are staggered to better prevent condensation in the atomizing chamber 4322 from flowing directly through the first intermediate through-hole 4102 along the second intermediate through-hole 4104, which could cause a short circuit in the battery assembly 300.

[0057] To ensure a reliable connection between the flow guide 410b and the printed circuit board 410a, such as... Figure 3 As shown, furthermore, the flow guide 410b is glued to the printed circuit board 410a, so that the flow guide 410b and the printed circuit board 410a are reliably fixedly connected.

[0058] like Figure 2As shown, in one embodiment, the liquid storage assembly 200 includes a first seal 210 and a second seal 220. Both the first seal 210 and the second seal 220 are located within the mounting groove 102 and are sealed to the housing 100. Both the first seal 210 and the second seal 220 are sleeved onto the central atomizing assembly 430. The first seal 210, the second seal 220, and the central atomizing assembly 430 together form the liquid storage cavity 202. The conductive flow guiding integrated assembly 410 abuts against the second seal 220, and a flow guiding cavity 411 exists between the conductive flow guiding integrated assembly 410 and the second seal 220. The air inlet 402 communicates with the trigger cavity 404 through the flow guiding cavity 411. In this embodiment, both the first seal 210 and the second seal 220 can be silicone or rubber components, ensuring a tight connection between the first seal 210 and the second seal 220 and the housing 100.

[0059] like Figure 2 and Figure 3 As shown, the second seal 220 is elastically abutted against the printed circuit board 410a, and the abutment portion of the second seal 220 and the printed circuit board 410a is arranged around the second intermediate through hole 4104, so that the flow guide cavity 411 and the second intermediate through hole 4104 are reliably separated, avoiding the problem of mutual air leakage between the two affecting the reliable start-up of the aerosol generator 10.

[0060] like Figure 2 and Figure 3 As shown, in one embodiment, the first sealing member 210 has an air outlet 212 and a insertion groove 214. The insertion groove 214 is arranged around the air outlet 212, which communicates with the atomizing chamber 4322. One end of the central atomizing component 430 away from the conductive flow guiding integrated component 410 is inserted into the insertion groove 214, so that the central atomizing component 430 and the first sealing member 210 are reliably connected. At the same time, the first sealing member 210 plays a sealing and plugging role. And / or, in one embodiment, the liquid storage component 200 further includes a liquid storage member 230, which is disposed in the liquid storage chamber 202 to store the atomized liquid in the liquid storage chamber 202. In this embodiment, the liquid storage member 230 can be a liquid storage cotton component.

[0061] like Figure 3 and Figure 4As shown, the central atomizing assembly 430 further includes a central tube 434. One end of the central tube 434 is inserted into the insertion slot 214, and the other end of the central tube 434 is sleeved with the second sealing member 220. The atomizing core 432 is disposed at the position where the central tube 434 communicates with the liquid storage chamber 202. The atomizing core 432 is electrically connected to the printed circuit board 410a, so that the atomizing core 432 heats and atomizes the atomized liquid when energized. In this embodiment, the central tube 434 has a liquid passage hole 4342, which communicates with the liquid storage chamber 202. The atomizing core 432 is disposed in the central tube 434 at a position corresponding to the liquid passage hole 4342. The central tube 434 is snapped onto the printed circuit board 410a and communicates with the second intermediate through hole 4104.

[0062] like Figure 3 and Figure 4 As shown, the battery assembly 300 further includes an energy storage device 310 and a conductive wire 320. The energy storage device 310 is electrically connected to the conductive current-conducting integrated assembly 410 via the conductive wire 320. In this embodiment, the energy storage device 310 can be a lithium battery. The energy storage device 310 is electrically connected to the printed circuit board 410a via the conductive wire 320, thereby electrically connecting the energy storage device 310 to the conductive current-conducting integrated assembly 410. See also... Figure 5 Furthermore, the conductive wire 320 passes through the air inlet 402 so that the conductive wire 320 can be better assembled and electrically connected to the energy storage device 310.

[0063] Furthermore, a positioning groove is provided on the inner wall of the air inlet 402. The conductive wire 320 is inserted into the positioning groove, so that the conductive wire 320 is engaged and positioned in the positioning groove, and the conductive wire 320 is installed and positioned in the positioning hole, while avoiding the problem of the conductive wire 320 affecting the unobstructed flow of the air inlet 402.

[0064] like Figure 3 and Figure 4 As shown, the aerosol generator 10 further includes a bottom cover 500, which is respectively sleeved on the energy storage component 310 and the housing 100 to reliably seal and install the energy storage component 310 inside the housing 100. Furthermore, the housing 100 includes a soft rubber sleeve 110 and a support sleeve 120. The soft rubber sleeve 110 is sleeved on the support sleeve 120, and a mounting groove 102 is formed in the support sleeve 120. During assembly, the liquid storage component 200, the battery rod component 300, and the conductive air intake atomizing mechanism 400 can be assembled onto the support sleeve 120 first, and then the soft rubber sleeve 110 can be sleeved onto the outer peripheral wall of the support sleeve 120, improving the ease of assembly and allowing for better gripping of the housing 100 during use, thus improving the user experience of the aerosol generator 10. In this embodiment, the support sleeve 120 is sleeved on the outer peripheral wall of the bottom cover 500, so that the bottom cover 500 is sleeved onto the housing 100.

[0065] Compared with the prior art, the present invention has at least the following advantages:

[0066] The aforementioned conductive air intake atomizing mechanism 400, with the microphone 420 disposed within the trigger cavity 404 of the conductive flow guiding integrated assembly 410 and one end of the central atomizing assembly 430 snapped into the conductive flow guiding integrated assembly 410, integrates and fixes both the microphone 420 and the central atomizing assembly 430 onto the conductive flow guiding integrated assembly 410, facilitating rapid assembly and reducing the number of parts in the aerosol generator 10. Since the atomizing core 432 is electrically connected to the conductive flow guiding integrated assembly 410, the wiring harness of the aerosol generator 10 can be reduced, which is beneficial for achieving automated assembly of the aerosol generator 10.

[0067] The embodiments described above are merely illustrative of several implementations of the present invention, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the invention patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of the present invention, and these all fall within the protection scope of the present invention. Therefore, the protection scope of this invention patent should be determined by the appended claims.

Claims

1. A conductive air intake atomizing mechanism, used for connection to a housing and a liquid storage component respectively, characterized in that, The conductive air intake atomizing mechanism includes: A conductive flow guiding integrated assembly is used to be installed in a housing. The conductive flow guiding integrated assembly has an air inlet, a trigger cavity, and an airflow channel. The trigger cavity is connected to the air inlet and the airflow channel respectively. The microphone head is disposed within the trigger cavity and electrically connected to the conductive current-guiding integrated component; A central atomizing component, one end of which is snapped into the conductive flow guiding integrated component, is used to pass through the liquid storage component to form a liquid storage cavity together with the liquid storage component. The central atomizing component includes an atomizing core, which is electrically connected to the conductive flow guiding integrated component. The atomizing cavity inside the atomizing core is connected to the airflow channel. The atomizing core is used to heat and atomize the atomized liquid discharged from the liquid storage cavity. The conductive current-guiding integrated component includes a printed circuit board and a current-guiding cover; The flow guide is disposed on the printed circuit board, and both the printed circuit board and the flow guide are used to be installed inside the housing; the air inlet includes a first air inlet opened in the flow guide and a second air inlet opened in the printed circuit board, and the first air inlet and the second air inlet are connected. The microphone head is disposed on one side of the printed circuit board and electrically connected to the printed circuit board; the central atomizing component is snapped onto the side of the printed circuit board opposite to the flow guide. The trigger cavity and the airflow channel are both formed in the guide shroud; the guide shroud also has a first intermediate through hole, and the printed circuit board has a second intermediate through hole. The first intermediate through hole communicates with the airflow channel, and the second intermediate through hole communicates with the first intermediate through hole and the atomizing cavity, respectively. A leak-proof groove is formed on the side of the guide shroud adjacent to the printed circuit board, and a retaining flange protrudes from the inner peripheral wall of the leak-proof groove, which surrounds the first intermediate through hole. The airflow channel includes an annular channel and an intermediate air guide channel. The annular channel is circumferentially arranged along the end face of the guide shroud away from the printed circuit board, and the annular channel communicates with the first through hole of the guide shroud. The intermediate air guide channel... The airflow is connected to the annular flow channel and the atomizing chamber respectively; the airflow flowing in through the first air inlet passes sequentially through the second air inlet, the trigger hole of the flow guide shroud, the trigger chamber, the first flow passage, the annular flow channel, the intermediate air guide channel, the first intermediate through hole, and the second intermediate through hole into the atomizing chamber; the first flow passage and the airflow channel are both formed on the end face of the second end of the conductive flow guide integrated component; the conductive flow guide integrated component also forms a first flow passage, which is connected to the trigger chamber and the airflow channel respectively; the conductive flow guide integrated component also forms a trigger hole, which is connected to the air inlet and the trigger chamber respectively.

2. The conductive air intake atomizing mechanism according to claim 1, characterized in that, The air inlet is located at the periphery of the conductive flow guiding integrated component.

3. The conductive air intake atomizing mechanism according to claim 1, characterized in that, The trigger hole is formed on the end face of the first end of the conductive current guiding integrated component, and the central atomizing component is snapped into the first end of the conductive current guiding integrated component.

4. The conductive air intake atomizing mechanism according to claim 3, characterized in that, Both the first flow passage and the airflow channel are formed on the end face of the second end of the conductive flow guiding integrated component; The conductive air intake atomizing mechanism also includes a sealing gasket, which abuts against the end face of the second end of the conductive flow guiding integrated component.

5. The conductive air intake atomizing mechanism according to claim 1, characterized in that, The conductive flow guiding integrated component also forms a through air channel, which is connected to the airflow channel and the atomizing chamber respectively; and / or The conductive flow guiding integrated component also has a second flow passage, which is connected to the air inlet and the airflow channel respectively.

6. An aerosol generating device, characterized in that, The device includes a housing, a liquid storage assembly, a battery rod assembly, and a conductive air intake atomizing mechanism as described in any one of claims 1 to 5. The housing has a mounting groove, the liquid storage assembly is located in the mounting groove and connected to the housing, the conductive flow guiding integrated assembly is located in the mounting groove and connected to the housing, the central atomizing assembly passes through the liquid storage assembly to form a liquid storage cavity together with the liquid storage assembly, and the atomizing core is used to heat and atomize the atomized liquid discharged from the liquid storage cavity; the battery rod assembly is located in the mounting groove and connected to the housing, and the battery rod assembly is electrically connected to the atomizing core.

7. The aerosol generating device according to claim 6, characterized in that, The liquid storage assembly includes a first seal and a second seal. Both the first and second seals are located within the mounting groove and are sealed to the housing. Both the first and second seals are sleeved on the central atomizing assembly. The first seal, the second seal, and the central atomizing assembly together form the liquid storage cavity. The conductive flow guiding integrated assembly abuts against the second seal, and there is a flow guiding cavity between the conductive flow guiding integrated assembly and the second seal. The second air inlet communicates with the trigger cavity through the flow guiding cavity.

8. The aerosol generating apparatus according to claim 7, characterized in that, The first sealing element has an air outlet and a insertion groove, the insertion groove being arranged around the air outlet and communicating with the atomizing chamber. The end of the central atomizing component furthest from the conductive flow guiding integrated component is inserted into the insertion groove; and / or The liquid storage assembly further includes a liquid storage element disposed within the liquid storage cavity.