Atomizer and atomizing device thereof
By incorporating isolators and blocking elements in the atomizer to control the flow channel state, the problem of odorous matrix volatilization during transportation is solved, ensuring matrix concentration and improving the user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NEVILLA (HONG KONG) LTD
- Filing Date
- 2025-04-29
- Publication Date
- 2026-06-05
Smart Images

Figure CN224320250U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of atomization technology, and in particular to an atomizer and atomization device thereof. Background Technology
[0002] An atomizer is an electronic device that transforms its internal matrix into an aerosol that can be inhaled. Inside the atomizer, there is a storage chamber for storing the odor matrix and an airway. After the odor matrix in the storage chamber is transformed into an aerosol, it can reach the outside of the atomizer through the airway and be inhaled by the user.
[0003] However, during the transportation of atomizers, the odor matrix itself is volatile and is prone to excessive evaporation during transportation, which may cause it to enter the mouthpiece prematurely or even escape from the outside of the atomizer. This premature evaporation of the odor matrix affects the concentration of the odor matrix and causes a concentration decay phenomenon. As a result, when the user inhales, there is only a small amount of odor matrix inside the atomizer, or the odor matrix may even evaporate prematurely during transportation, affecting the user's experience. Utility Model Content
[0004] The embodiments of this application provide an atomizer and atomizing device thereof, which can control the position of the first channel in the isolation member by setting an isolation member, thereby preventing the liquid matrix in the first storage cavity from evaporating during transportation, and ensuring that the content of the liquid matrix or its effective components can support the user to achieve a predetermined number of inhalations during use.
[0005] In a first aspect, embodiments of this application provide an atomizer, comprising: a mouthpiece having a suction channel; a first chamber having a receiving cavity; an isolating member disposed in the receiving cavity for dividing the receiving cavity into a first storage cavity and a second storage cavity, the first storage cavity being used to store a liquid matrix, and the second storage cavity being configured to communicate with the suction channel; a second chamber being disposed at one end of the first chamber away from the mouthpiece, and the second chamber being in airflow communication with the first chamber; the second chamber being provided with a third storage cavity and an atomizing core; the third storage cavity being used to store an atomizing matrix, and the atomizing core being used to atomize the atomizing matrix; wherein, the isolating member has a first through groove for communicating the first storage cavity and the second storage cavity; the isolating member is configured to have a connected state and a closed state through the first through groove, in which the liquid matrix in the first storage cavity can enter the second storage cavity in the connected state.
[0006] In some embodiments, the first compartment is further provided with a first blocking member, which is configured to be movable relative to the isolation member to be in a first relative position or a second relative position; wherein, in the first relative position, the first blocking member is misaligned or spaced from the first through slot so that the first through slot is in a connected state; in the second relative position, the first blocking member blocks the first through slot so that the first through slot is in a closed state.
[0007] In some embodiments, the first blocking element is partially disposed within the first storage cavity or the second storage cavity to allow the first through slot to be in a connected or closed state.
[0008] In some embodiments, the isolation member and the suction nozzle are linked together; the suction nozzle and the first chamber member can move relative to each other, so that the first blocking member and the isolation member can move relative to each other to be in the first relative position or the second relative position.
[0009] In some embodiments, the first blocking member is at least partially disposed within the first storage cavity. The first blocking member has a first blocking surface. The first blocking member and the isolation member are rotatable or movable relative to each other, so that the first blocking surface slides along the wall of the isolation member. When the first blocking surface completely blocks the first through slot, the first blocking member and the isolation member are in the second relative position, and the first through slot is in a closed state.
[0010] In some embodiments, the isolator has a first locking portion at one end near the nozzle, and the nozzle has a second locking portion corresponding to the first locking portion. The second locking portion engages with the first locking portion to link the isolator and the nozzle; and / or, the outer wall of the first blocking member has a third locking portion, and the first chamber has a fourth locking portion corresponding to the third locking portion. The fourth locking portion engages with the third locking portion to define the relative position of the first blocking member and the first chamber.
[0011] In some embodiments, the second storage cavity is provided with a first liquid storage element for storing the liquid matrix; the first storage cavity is also provided with a limiting structure for linking the first liquid storage element with the isolation element.
[0012] In some embodiments, the atomizer further includes: an airway tube, the airway tube being at least partially disposed within the first chamber, one end of the airway tube communicating with the mouthpiece; wherein the airway tube is provided with a second through groove, the second through groove being used to connect the second storage chamber and the airway within the airway tube, the second through groove being configured to have an open state and a closed state, wherein in the open state, the liquid matrix in the second storage chamber enters the airway within the airway tube.
[0013] In some embodiments, the first chamber component is further provided with a second blocking component, which is movable relative to the airway component to be located in a first relative position or a second relative position; wherein, in the first relative position, the first through channel is in a connected state, and the second blocking component is aligned with the second through channel to make the second through channel open; in the second relative position, the first through channel is in the closed state, and the second blocking component blocks the second through channel to make the second through channel closed.
[0014] In some embodiments, the first storage cavity is disposed adjacent to the second storage cavity; or, the first storage cavity is disposed around the outside of the second storage cavity; or, multiple first storage cavities are provided, and the multiple first storage cavities are arranged along the outer periphery of the second storage cavity, and the number of the first through slots corresponds to the number of the first storage cavities.
[0015] In some embodiments, the suction nozzle has an extension extending toward the first chamber component, the extension covering the exterior of the first chamber component; wherein, a positioning structure is provided on the inner side of the extension, and a mating structure corresponding to the positioning structure is provided on the outer wall of the first chamber component; when the suction nozzle moves relative to the first chamber component, the positioning structure and the mating structure cooperate with each other to position the first through groove in the connected state or the closed state, and the second through groove in the open state or the closed state.
[0016] In some embodiments, the first compartment component and the second compartment component are integrally formed, or the first compartment component and the second compartment component are detachably connected.
[0017] In some embodiments, the second chamber component is further provided with a second air passage, and the atomizing core is connected between the second air passage and the air passage component.
[0018] In a first aspect, embodiments of this application provide an atomizing device, the atomizing device including an atomizer and a battery assembly, the battery assembly being electrically connected to the atomizer, and the atomizer being any of the atomizers described above.
[0019] The beneficial effects of this application are as follows: By setting an isolation component inside the first compartment and forming a first storage cavity and a second storage cavity through the isolation component, and by controlling the state of the first through groove on the isolation component, the connection or non-connection between the first storage cavity and the second storage cavity can be controlled. This can prevent the liquid matrix from evaporating prematurely during transportation, ensure that the liquid matrix has sufficient concentration before it is used, reduce the concentration decay of odor, and thus improve the quality of the product and enhance the user experience. Attached Figure Description
[0020] To more clearly illustrate the technical solutions in the embodiments of this application, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the accompanying 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 This is a three-dimensional structural diagram of an atomizer according to an embodiment of this application;
[0022] Figure 2 This is a schematic diagram of an atomizer structure according to an embodiment of this application;
[0023] Figure 3 This is a schematic diagram of an atomizer structure according to another embodiment of this application;
[0024] Figure 4 It is in this application Figure 1 A schematic diagram of the AA cross-sectional structure;
[0025] Figure 5 It is in this application Figure 1 A schematic diagram of the BB cross-sectional structure;
[0026] Figure 6 This is a schematic diagram of the cooperation between the isolation member and the first blocking member in one embodiment of this application;
[0027] Figure 7 This is a schematic diagram of the position and structure of the airway tubing and the first chamber component according to one embodiment of this application;
[0028] Figure 8 This is a schematic cross-sectional view of the internal structure of the first compartment component according to an embodiment of this application;
[0029] Figure 9 This is a cross-sectional schematic diagram of the internal structure of the first compartment component according to another embodiment of this application;
[0030] Figure 10 This is a three-dimensional structural diagram of the first and second compartment components according to an embodiment of this application;
[0031] Figure 11 This is a three-dimensional structural diagram of a suction nozzle component according to an embodiment of this application;
[0032] Figure 12 This is a front view of a suction nozzle component according to an embodiment of this application;
[0033] Figure 13 It is in this application Figure 12 Schematic diagram of CC cross-section structure;
[0034] Figure 14 It is in this application Figure 12 Schematic diagram of the DD cross-sectional structure;
[0035] Figure 15 This is a schematic diagram of the atomizing device structure according to one embodiment of this application.
[0036] Explanation of reference numerals in the attached drawings: 10-Sucking nozzle; 101-Suction channel; 20-First chamber; 201-Accommodating cavity; 30-Isolation member; 21-First storage cavity; 22-Second storage cavity; 31-First through groove; 40-First blocking member; 400-First blocking surface; 41-First blocking part; 32-First locking part; 11-Second locking part; 42-Third locking part; 23-Fourth locking part; 32-Ventilation hole; 221-First liquid storage member; 43-Limiting structure; 50-Air passage Tubing; 51-Second through groove; 60-Second blocking member; 12-Extension; 121-Positioning structure; 24-Matching structure; 52-Fifth locking part; 13-Sixth locking part; 25-First sealing member; 26-Second sealing member; 70-Second chamber member; 71-Third storage chamber; 72-Atomizing core; 711-Second liquid storage member; 73-Second air passage; 80-Mouth seal; 90-Sealing sticker; 1000-Atomizing device; 100-Atomizer; 200-Battery assembly. Detailed Implementation
[0037] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this application.
[0038] Please refer to Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 8 and Figure 9One embodiment of this application provides an atomizer, including: a mouthpiece 10 with a suction channel 101; a first chamber 20 having a receiving cavity 201; a separator 30 disposed in the receiving cavity 201 to divide the receiving cavity 201 into a first storage cavity 21 and a second storage cavity 22, the first storage cavity 21 being used to store a liquid matrix, and the second storage cavity 22 being configured to communicate with the suction channel 101; and a second chamber 70 disposed at the end of the first chamber 20 away from the mouthpiece 10. The second chamber 70 is in airflow communication with the first chamber 20; the second chamber 70 is provided with a third storage chamber 71 and an atomizing core 72; the third storage chamber 71 is used to store the atomizing matrix, and the atomizing core 72 is used to atomize the atomizing matrix; wherein, the isolation member 30 is provided with a first through groove 31, which is used to connect the first storage chamber 21 and the second storage chamber 22; the isolation member 30 is configured to have a connected state and a closed state through the first through groove 31. In the connected state, the liquid matrix in the first storage chamber 21 can enter the second storage chamber 22.
[0039] In this embodiment, the nozzle 10 is used to allow the user to conveniently inhale the aerosol generated in the atomizer, wherein the suction channel 101 is used to allow the aerosol to flow and be inhaled by the user.
[0040] In this embodiment, the first chamber component 20 is a structure in the atomizer used to store the liquid matrix, wherein the accommodating cavity 201 can be used to store the liquid matrix.
[0041] In this embodiment, the isolator 30 divides the accommodating cavity 201 into two cavities: a first storage cavity 21 and a second storage cavity 22. Furthermore, the first channel 31 is configured to have a connected state and a closed state. In the connected state, the liquid matrix in the first storage cavity 21 can enter the second storage cavity 22. By controlling the first channel 31 to be in the connected or closed state, the replenishment of the liquid matrix from the first storage cavity 21 to the second storage cavity 22 can be controlled. By providing the isolator 30, it is possible to prevent the liquid matrix from entering the mouthpiece 10 through the second storage cavity 22 during evaporation, or even escaping outside the atomizer, thereby improving product quality, reducing the attenuation of odor concentration, and enhancing the user experience.
[0042] In this embodiment, both the first storage cavity 21 and the second storage cavity 22 are capable of storing liquid matrix. The second storage cavity 22 is connected to the suction nozzle 10. When in use, the liquid matrix in the second storage cavity 22 is consumed.
[0043] In one embodiment, the liquid matrix is initially stored in the first storage cavity 21, while the second storage cavity 22 does not store the liquid matrix. Since the first channel 31 is initially sealed, it prevents the liquid matrix from evaporating and entering the nozzle 10. The separator 30 is positioned between the first and second storage cavities 21 and 22, isolating them and preventing communication between them in the initial state, thus ensuring the airtightness of the first storage cavity 21. During use, the state of the first channel 31 is controlled so that the first storage cavity 21 can communicate with the second storage cavity 22 through the first channel 31 on the separator 30, allowing the liquid matrix in the first storage cavity 21 to enter the second storage cavity 22 through the first channel 31.
[0044] The liquid matrix in this application will be further described. In one case, the liquid matrix in this application can be an aerosol matrix that needs to be atomized into an aerosol by means of heating by an atomizer or ultrasonic vibration, such as e-liquid. In this case, an atomizing core communicating with the second storage cavity 22 can be provided in the first chamber 20 to heat and atomize the liquid matrix entering the second storage cavity 22 of the first chamber 20. In another case, the liquid matrix in this application can be a volatile odor matrix that can evaporate without heating, such as fragrance, etc. In this case, an atomizing core may not be provided in the first chamber 20.
[0045] In this embodiment, a second chamber 70 is added to increase the variety of substrates stored in the atomizer and enrich the user experience. Specifically, the second storage chamber 22 can store the atomizing substrate to be atomized and can be atomized through the atomizing core 72. The atomizing substrate can be a substrate with the same or similar flavor as the liquid substrate, or it can be a substrate with a different flavor than the liquid substrate.
[0046] In one embodiment, a second liquid storage element 711 is provided within the third storage cavity 71, which can be used to absorb and store the atomized matrix. In one example, the second liquid storage element 711 is a liquid storage cotton.
[0047] In one embodiment, the atomizing matrix in the second chamber 70 is heated and atomized by the atomizing core 72 to generate an aerosol. The aerosol enters the first chamber 20 and mixes with the gas generated by the evaporation of the liquid matrix in the second storage chamber 22, eventually reaching the mouthpiece 10 and being inhaled by the user.
[0048] In one embodiment, the second chamber component 70 is the chamber portion of the atomizer 100 used for atomization, while the first chamber component 20 is the chamber portion of the atomizer 100 used for flavoring.
[0049] Please continue to refer to this. Figure 2 , Figure 3 , Figure 6 , Figure 8 and Figure 9 In one embodiment, the first compartment 20 is further provided with a first blocking member 40, which is configured to be able to move relative to the isolation member 30 to be in a first relative position or a second relative position; wherein, in the first relative position, the first blocking member 40 is misaligned or spaced from the first through groove 31 so that the first through groove 31 is in a connected state; in the second relative position, the first blocking member 40 blocks the first through groove 31 so that the first through groove 31 is in a closed state.
[0050] In this embodiment, a first blocking member 40 is added. The first blocking member 40, in cooperation with the isolating member 30, blocks the first through groove 31 on the isolating member 30. It should be noted that there can be multiple first relative positions where the first through groove 31 is in a connected state; that is, as long as the first blocking member 40 does not completely block the first through groove 31, the first blocking member 40 and the isolating member 30 are in the first relative position. In this embodiment, the first blocking member 40 and the isolating member 30 can move relative to each other, either by rotation or movement. Furthermore, the relative movement of the first blocking member 40 and the isolating member 30 can exist in multiple directions. For details, please refer to the following embodiments.
[0051] Please refer to Figure 2 , Figure 3 , Figure 8 and Figure 9 In one embodiment, the first blocking member 40 is partially disposed in the first storage cavity 21 or the second storage cavity 22 so that the first through slot 31 is in a connected state or a closed state.
[0052] In this embodiment, the first through channel 31 is either in a connected or closed state by a first blocking member 40 partially disposed within the first storage cavity 21 or the second storage cavity 22. Specifically, when the portion of the first blocking member 40 disposed within the first storage cavity 21 or the second storage cavity 22 is fitted into the first through channel 31 and completely blocks it, the first through channel 31 is in a closed state; while when the portion of the first blocking member 40 does not completely block the first through channel 31, the first through channel 31 is in a connected state.
[0053] Please continue to refer to this. Figure 6 To further optimize the setting position of the first blocking member 40, in one embodiment, the first blocking member 40 is set in the first storage cavity 21 or the second storage cavity 22. The first blocking member 40 can move in the first storage cavity 21 or the second storage cavity 22 so that the first through groove 31 is in a connected state or a closed state.
[0054] In this embodiment, the first blocking member 40 can be disposed within the first storage cavity 21 or the second storage cavity 22. This reduces the atomizer volume while simultaneously blocking the first through-slot 31 by the movement of the first blocking member 40 within the cavity, thereby changing the state of the first through-slot 31. In one embodiment, please refer to... Figure 1 The first blocking member 40 moves along the X direction in the cavity, gradually approaching the first through groove 31 until it completely covers and fits the first through groove 31, so that the first through groove 31 is in a closed state.
[0055] Please continue to refer to this. Figure 2 , Figure 3 , Figure 8 and Figure 9 In one embodiment, the isolation member 30 is linked to the suction nozzle member 10; the suction nozzle member 10 and the first chamber member 20 can move relative to each other, so that the first blocking member 40 and the isolation member 30 can move relative to each other and be in a first relative position or a second relative position.
[0056] In this embodiment, the isolating member 30 and the suction nozzle 10 are linked, meaning that the movement of one of them can drive the movement of the other. Simultaneously, the first blocking member 40 and the first chamber member 20 are stationary relative to the suction nozzle 10. Based on this, the suction nozzle 10 and the first chamber member 20 are configured to move relative to each other, thereby allowing the first blocking member 40 and the isolating member 30 to move relative to each other. It should be noted that the relative movement in this embodiment includes relative rotation and relative translation. It should also be noted that the relative movement of the suction nozzle 10 and the first chamber member 20 can be achieved in several ways: in one case, both the suction nozzle 10 and the first chamber member 20 can be controlled to move to achieve relative movement; in another case, the suction nozzle 10 can be controlled to move while the first chamber member 20 remains stationary to achieve relative movement; and in yet another case, the first chamber member 20 can be controlled to move while the suction nozzle 10 remains stationary to achieve relative movement.
[0057] Please continue to refer to this. Figure 8 and Figure 9 The structure of the first blocking member 40 is further optimized. In one embodiment, the first blocking member 40 is at least partially disposed in the first storage cavity 21. The first blocking member 40 is provided with a first blocking surface 400. The first blocking member 40 and the isolation member 30 can rotate or move relative to each other so that the first blocking surface 400 slides along the wall surface of the isolation member 30. When the first blocking surface 400 completely blocks the first through groove 31, the first blocking member 40 and the isolation member 30 are in a second relative position, and the first through groove 31 is in a closed state.
[0058] In this embodiment, the structure of the first blocking member 40 is optimized so that the first blocking member 40 has a first blocking part 41 disposed in the first storage cavity 21. The first blocking part 41 is provided with a first blocking surface 400. By controlling the first blocking member 40 and the isolation member 30 to rotate or move relative to each other, the first blocking surface 400 slides along the wall of the isolation member 30. When the first blocking surface 400 completely blocks the first through groove 31, the first through groove 31 can be blocked. That is, at this time, the first blocking member 40 and the isolation member 30 are in the second relative position. That is, at this time, the first through groove 31 is in the closed state, and the liquid matrix in the first storage cavity 21 will not enter the second storage cavity 22.
[0059] Please continue to refer to this. Figure 12 , Figure 13 and Figure 14 The specific structure of the linkage between the isolator 30 and the nozzle 10, and the specific structure of the linkage between the first blocking member 40 and the first chamber 20 are optimized. In one embodiment, the isolator 30 is provided with a first locking part 32 at one end near the nozzle 10, and the nozzle 10 is provided with a second locking part 11 corresponding to the first locking part 32. The second locking part 11 and the first locking part 32 are engaged to make the isolator 30 and the nozzle 10 linked; and / or, the outer wall of the first blocking member 40 is provided with a third locking part 42, and the first chamber 20 is provided with a fourth locking part 23 corresponding to the third locking part 42. The fourth locking part 23 and the third locking part 42 are engaged to limit the relative position of the first blocking member 40 and the first chamber 20.
[0060] In this embodiment, a first locking part 32 is provided on the isolator 30, and a second locking part 11 is provided on the nozzle 10. The first locking part 32 and the second locking part 11 engage with each other, so that the isolator 30 and the nozzle 10 are linked together. In one example, the isolator 30 and the nozzle 10 can also be fixedly connected.
[0061] In one embodiment, the first locking portion 32 can be a protruding structure, and the second locking portion 11 can be a recessed structure. The cooperation between the protruding structure and the recessed structure enables the nozzle 10 and the separator 30 to move together. In another embodiment, the second locking portion 11 can be a protruding structure, and the first locking portion 32 can be a recessed structure. The cooperation between the protruding structure and the recessed structure enables the nozzle 10 and the separator 30 to move together.
[0062] In this embodiment, a third locking part 42 is provided on the first blocking member 40, and a fourth locking part 23 is provided on the first compartment member 20. The third locking part 42 and the fourth locking part 23 engage with each other to limit the relative position of the first blocking member 40 and the first compartment member 20. In one example, the first blocking member 40 and the first compartment member 20 may also be fixedly connected.
[0063] In one embodiment, the third locking part 42 can be a protruding structure, and the fourth locking part 23 can be a recessed structure. The cooperation between the protruding structure and the recessed structure enables the first blocking member 40 and the first compartment member 20 to move together. The fourth locking part 23 can be a protruding structure, and the third locking part 42 can be a recessed structure. The cooperation between the protruding structure and the recessed structure defines the relative position of the first blocking member 40 and the first compartment member 20.
[0064] Please continue to refer to this. Figure 2 , Figure 3 , Figure 8 and Figure 9 The structure inside the second storage cavity 22 is optimized. In one embodiment, the second storage cavity 22 is provided with a first liquid storage component 221, which is used to store liquid matrix. The first storage cavity 22 is also provided with a limiting structure 43, which is used to link the first liquid storage component 221 with the isolation component 30.
[0065] In this embodiment, a first liquid storage component 221 is provided in the second storage cavity 22 to store the liquid matrix entering the second storage cavity 22. When the first liquid storage component 221 is in a first relative position relative to the isolator 30 and the first blocking component 40, in order to further prevent the first liquid storage component 221 from blocking the first channel 31 of the isolator 30 and thus hindering the communication of the first channel 31 and affecting the flow of the liquid matrix in the first storage cavity 21 into the second storage cavity 22, a limiting structure 43 is added in this embodiment. This allows the first liquid storage component 221 to move with the isolator 30, thereby limiting the position of the first liquid storage component 221 in the second storage cavity 22 when the isolator 30 and the first blocking component 40 move relative to each other. This ensures that when the isolator 30 and the first blocking component 40 are in the first relative position, the first blocking component 40 can be moved away from, misaligned with, or spaced apart from the first channel 31, thus avoiding affecting the conductivity of the first channel 31.
[0066] In one embodiment, the limiting structure 43 links the first liquid reservoir 221 with the isolator 30. In this case, the limiting structure 43 only needs to limit the position of the first liquid reservoir 221 relative to the first through groove 31 of the isolator 30 within the first storage cavity 21, ensuring that the first liquid reservoir 221 remains in a position away from, misaligned with, or spaced apart from the first through groove 31. Simultaneously, the limiting structure 43 links the two, allowing the first liquid reservoir 221 to move with the isolator 30. In this case, the open and closed states of the first through groove 31 are only affected by the first blocking member 40. In one example, the limiting structure 43 is used to fix the first liquid reservoir 221 to the isolator 30; in another example, the limiting structure 43 and the isolator 30 are integrally formed.
[0067] The following section continues to improve the atomizer in this application. Please refer to [link / reference]. Figure 2 , Figure 3 , Figure 8 and Figure 9 In one embodiment, the atomizer further includes an airway tube 50, which is at least partially disposed within the first chamber 20, and one end of the airway tube 50 is connected to the mouthpiece 10; wherein the airway tube 50 is provided with a second through groove 51, which is used to connect the second storage chamber 22 and the airway within the airway tube 50, and the second through groove 51 is configured to have an open state and a closed state. In the open state, the liquid matrix in the second storage chamber 22 enters the airway of the airway tube 50.
[0068] In this embodiment, the airway fitting 50 forms an airway and communicates with the second storage chamber 22 to receive the gas formed by the liquid matrix within the second storage chamber 22. In this embodiment, by providing a second through-slot 51 in the airway fitting 50 and controlling the state of the second through-slot 51, the liquid matrix within the second storage chamber 22 can only enter the airway of the airway fitting 50 when the second through-slot 51 is open. This design further prevents the liquid matrix from evaporating into the airway and entering the mouthpiece 10, or even escaping outside the atomizer, when the atomizer is not in use.
[0069] In this embodiment, the aerosol generated after being atomized by the atomizing core 72 can enter the mouthpiece of the mouthpiece 10 in two ways. In one case, the atomizing core 72 connects the third storage chamber 71 and the mouthpiece of the mouthpiece 10. In this case, the first chamber 20 and the second chamber 70 can be arranged side-by-side, allowing the aerosol to directly reach the mouthpiece 10 and be drawn in. In the other case, the atomizing core 72 connects the third storage chamber 71 and the air passage 50, allowing the aerosol to reach the mouthpiece of the mouthpiece 10 and be drawn in through the air passage 50.
[0070] Please refer to Figure 2 , Figure 3 , Figure 8 and Figure 9 Furthermore, the airway fitting 50 is optimized. In one embodiment, a second blocking member 60 is also provided inside the first chamber 20. The second blocking member 60 and the airway fitting 50 can move relative to each other to be located in a first relative position or a second relative position. In the first relative position, the first through groove 31 is in a connected state, and the second blocking member 60 is aligned with the second through groove 51 so that the second through groove 51 is in an open state. In the second relative position, the first through groove 31 is in a closed state, and the second blocking member 60 blocks the second through groove 51 so that the second through groove 51 is in a closed state.
[0071] In this embodiment, the airway tube 50 and the isolator 30 are both linked to the nozzle 10, meaning the airway tube 50 can also move with the nozzle 10. Simultaneously, the second blocking member 60 and the first blocking member 40 are stationary relative to the nozzle 10, together with the first chamber 20. Under this configuration, when the first blocking member 40 and the isolator 30 move relative to each other and are in a first relative position, the first through groove 31 is in a connected state. At the same time, the second blocking member 40 is aligned with the second through groove 51, meaning the second blocking member 40 does not completely block the opening of the second through groove 51, and the second through groove 51 is also in an open state. At this time, the liquid matrix in the first storage chamber 21 can enter the second storage chamber 22 through the first through groove 31, and the liquid matrix in the second storage chamber 22 can enter the air passage 50. If the liquid matrix is a volatile matrix, the gas after the liquid matrix evaporates can enter the air passage 50 and then enter the nozzle 10. If the liquid matrix is a matrix that needs to be atomized, an atomizing core is set in the air passage 50. The liquid matrix first enters the atomizing core and is atomized to obtain an aerosol. The aerosol enters the nozzle 10 along the air passage 50. In this configuration, when the first blocking member 40 and the isolating member 30 move relative to each other and are in the second relative position, the first through groove 31 is in the closed state. At the same time, the second blocking member 40 completely blocks the opening of the second through groove 51 of the airway fitting 50, and the second through groove 51 is also in the closed state. At this time, the liquid matrix in the first storage cavity 21 will not enter the second storage cavity 22, and the liquid matrix in the second storage cavity 22 will not enter the airway fitting 50, thereby improving the sealing performance of the liquid matrix in the first storage cavity 21.
[0072] In one embodiment, the structure of the airway tube 50 and the nozzle 10 being linked together is further described. The airway tube 50 has a fifth locking portion 52 at one end near the nozzle 10, and the nozzle has a sixth locking portion 13 corresponding to the fifth locking portion 52. The linkage between the airway tube 50 and the nozzle 10 is achieved through the cooperation of the fifth locking portion 52 and the sixth locking portion 13.
[0073] In one embodiment, the fifth locking part 52 can be a protruding structure, and the sixth locking part 13 can be a recessed structure. The cooperation between the protruding structure and the recessed structure enables the airway tube 50 and the nozzle 10 to move together. In another embodiment, the sixth locking part 13 can be a protruding structure, and the fifth locking part 52 can be a recessed structure. The cooperation between the protruding structure and the recessed structure enables the airway tube 50 and the nozzle 10 to move together.
[0074] In one embodiment, the second blocking member 60 is integrally formed with the first chamber member 20.
[0075] Please continue to refer to this. Figure 2 , Figure 3 and Figure 7Furthermore, the relative positions of the airway tube 50 and the second storage cavity 22 are optimized. In one embodiment, the airway tube 50 is disposed through the second storage cavity 22, or the airway tube 50 is disposed on one side of the second storage cavity 22.
[0076] In this embodiment, the position of the airway tube 50 is further optimized. When the airway tube 50 passes through the second storage cavity 22, the suction nozzle 10 and the first chamber 20 rotate relative to each other about the airway tube 50. When the airway tube 50 is located on one side of the first storage cavity 21, the suction nozzle 10 and the first chamber 20 rotate relative to each other about the airway tube 50.
[0077] Please continue to refer to this. Figure 2 , Figure 3 and Figure 7 Furthermore, the relative positions of the first storage cavity 21 and the second storage cavity 22 are optimized. In one embodiment, the first storage cavity 21 and the second storage cavity 22 are arranged adjacent to each other. Adjacent arrangement includes the first storage cavity 21 and the second storage cavity 22 being arranged along the extension direction of the airway tube 50, or the first storage cavity 21 and the second storage cavity 22 being arranged perpendicular to the extension direction of the airway tube 50.
[0078] In another embodiment, the first storage cavity 21 is disposed around the outside of the second storage cavity 22. In this case, the first storage cavity 21 and the second storage cavity 22 are configured as an inner and outer structure.
[0079] In another embodiment, multiple first storage cavities 21 are provided, arranged along the outer periphery of the second storage cavity 22, and the number of first through slots 31 corresponds to the number of first storage cavities 21. In this case, multiple first storage cavities 21 are provided, enabling the storage of liquid bases with various flavors. Since the multiple first storage cavities 21 are arranged along the outer periphery of the second storage cavity 22, a first through slot 31 can be provided on the isolator 30 for each first storage cavity 21. At the first relative position, the number of first through slots 31 that are attached can be controlled by controlling the area of the first blocking surface 400 of the first blocking member 40, thereby controlling the number of one or more first storage cavities 21 that need to be connected.
[0080] Please continue to refer to this. Figure 10 and Figure 11The suction nozzle 10 has an extension 12 extending toward the first chamber 20, and the extension 12 covers the outside of the first chamber 20. The extension 12 has a positioning structure 121 on its inner side, and the outer wall of the first chamber 20 has a corresponding mating structure 24. When the suction nozzle 10 moves relative to the first chamber 20, the positioning structure 121 and the mating structure 24 work together to position the first through groove 31 in a connected state or a closed state, and the second through groove 51 in an open state or a closed state.
[0081] In this embodiment, the relative movement can be the relative rotation or translation of the nozzle 10 and the first chamber 20 as described in the previous embodiment. A positioning structure 121 and a mating structure 24 are provided to determine the relative position of the nozzle 10 and the first chamber 20, helping the user perceive their relative positions. Furthermore, multiple positioning structures 121 and mating structures 24 can be provided to enhance user perception. Even further, markings can be placed on the outer wall of the first chamber 20 at positions corresponding to the first and second relative positions to help the user identify their relative positions during rotation.
[0082] In one embodiment, the positioning structure 121 is a protrusion, and the mating structure 24 is a groove. In another embodiment, the mating structure 24 is a protrusion, and the positioning structure 121 is a groove. The resistance created by the protrusion engaging with the groove helps the user perceive the position.
[0083] In one embodiment, the first chamber 20 is further provided with a first sealing element 25 and a second sealing element 26. The first sealing element 25, the inner wall of the first chamber 20, the first blocking element 40 and the isolation element 30 together form a first storage cavity 21; the second sealing element 26, the isolation element 30, the first blocking element 40 and the second blocking element 60 together form a second storage cavity 22.
[0084] Please continue to refer to this. Figure 13 In one embodiment, the side wall of the isolation member 30 is also provided with a vent 32; the vent 32 is located on the side of the isolation member 30 near the first seal member 25.
[0085] In this embodiment, the vent 32 can balance the air pressure between the first storage cavity 21 and the second storage cavity 22 isolated by the isolation member 30 inside the accommodating cavity 201, so that the air pressure between the two cavities reaches a balance, thereby ensuring that the liquid matrix can be replenished from the first storage cavity 21 and the second storage cavity 22.
[0086] For further optimization of the atomizer structure in this application, please refer to [reference needed]. Figure 1 , Figure 4 and Figure 5 The first compartment component 20 and the second compartment component 70 are integrally formed, or the first compartment component 20 and the second compartment component 70 are detachably connected.
[0087] In this embodiment, the connection method between the first chamber component 20 and the second chamber component 70 is optimized. When the first chamber component 20 and the second chamber component 70 are integrally formed, the atomizer can be a disposable atomizer. Alternatively, liquid matrix can be continuously replenished when it is depleted to extend the atomizer's service life. When the first chamber component 20 and the second chamber component 70 are detachably connected, either the first chamber component 20 or the second chamber component 70 in the atomizer can be replaced according to actual needs after disassembly, which also extends the atomizer's service life.
[0088] In one embodiment, please refer to Figure 4 and Figure 5 The second chamber 70 is also provided with a second air passage 73, and the atomizing core is connected between the second air passage 73 and the air passage tube 50.
[0089] In this embodiment, the second airway 73 can be directly connected to the nozzle 10, or it can be connected to the nozzle 10 through the airway tube 50.
[0090] In one embodiment, please refer to Figure 4 and Figure 5 The nozzle assembly 10 also has a nozzle seal 80 on its nozzle opening, which is used to seal the nozzle opening to further prevent leakage. In one example, the nozzle seal 80 is made of sealing silicone.
[0091] In one embodiment, please refer to Figure 5 The bottom of the atomizer is equipped with a sealing sticker 90. The sealing sticker is used to further ensure the internal sealing of the atomizer when it is set at the factory, and to prevent the electrical parts from coming into contact with moisture in the outside air.
[0092] Please refer to this first. Figure 15 Another embodiment of this application provides an atomizing device 1000, which includes an atomizer 100 and a battery assembly 200. The battery assembly 200 is electrically connected to the atomizer 100, and the atomizer 100 is any of the atomizers in the above embodiments.
[0093] In this embodiment, the battery assembly 200 is used to store energy and control the opening and closing of the atomizing core 72 in the atomizer 100, as well as the working state of the atomizing core 72.
[0094] The above description is merely an embodiment of this application and does not limit the patent scope of this application. Any equivalent structural or procedural transformations made using the content of this application's specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this application.
Claims
1. An atomizer, characterized in that, include: The nozzle is equipped with a suction channel; The first compartment component forms a accommodating cavity; An isolator is disposed in the accommodating cavity to divide the accommodating cavity into a first storage cavity and a second storage cavity, wherein the first storage cavity is used to store a liquid matrix and the second storage cavity is configured to communicate with the suction air passage. The second chamber component is disposed at the end of the first chamber component away from the nozzle component, and the second chamber component is in airflow communication with the first chamber component; the second chamber component is provided with a third storage cavity and an atomizing core; the third storage cavity is used to store the atomizing matrix, and the atomizing core is used to atomize the atomizing matrix; The isolation component is provided with a first through groove, which is used to connect the first storage cavity and the second storage cavity; The isolation element is configured to have a connected state and a closed state via the first through groove. In the connected state, the liquid matrix in the first storage cavity can enter the second storage cavity.
2. The atomizer according to claim 1, characterized in that, The first compartment is further provided with a first blocking member, which is configured to be able to move relative to the isolation member to be in a first relative position or a second relative position. In the first relative position, the first blocking member is misaligned or spaced from the first through groove so that the first through groove is in a connected state; in the second relative position, the first blocking member blocks the first through groove so that the first through groove is in a closed state.
3. The atomizer according to claim 2, characterized in that, The first blocking element is partially disposed within the first storage cavity or the second storage cavity, so that the first through slot is in a connected state or a closed state.
4. The atomizer according to claim 2, characterized in that, The isolation component is linked to the suction nozzle component; the suction nozzle component and the first chamber component can move relative to each other, so that the first blocking component and the isolation component can move relative to each other and be in the first relative position or the second relative position.
5. The atomizer according to claim 4, characterized in that, The first blocking member is at least partially disposed within the first storage cavity. The first blocking member has a first blocking surface. The first blocking member and the isolation member are rotatable or movable relative to each other, so that the first blocking surface slides along the wall of the isolation member. When the first blocking surface completely blocks the first through slot, the first blocking member and the isolation member are in the second relative position, and the first through slot is in a closed state.
6. The atomizer according to claim 5, characterized in that, The isolator is provided with a first locking part at one end near the nozzle, and the nozzle is provided with a second locking part corresponding to the first locking part. The second locking part is engaged with the first locking part so that the isolator and the nozzle are linked together. And / or, the outer wall of the first blocking member is provided with a third locking part, and the first compartment member is provided with a fourth locking part corresponding to the third locking part. The fourth locking part and the third locking part are engaged to limit the relative position of the first blocking member and the first compartment member.
7. The atomizer according to claim 6, characterized in that, The second storage cavity is provided with a first liquid storage device, which is used to store the liquid matrix; The first storage cavity is also provided with a limiting structure, which is used to enable the first liquid storage component and the isolation component to be linked.
8. The atomizer according to claim 4, characterized in that, The atomizer also includes: An airway assembly, at least partially disposed within the first chamber assembly, with one end of the airway assembly connected to the nozzle assembly; The airway fitting is provided with a second through groove, which is used to connect the second storage cavity and the airway in the airway fitting. The second through groove is configured to have an open state and a closed state. In the open state, the liquid matrix in the second storage cavity enters the airway in the airway fitting.
9. The atomizer according to claim 8, characterized in that, The first chamber component is further provided with a second blocking component, which can move relative to the airway component to be located in a first relative position or a second relative position; In the first relative position, the first through groove is in a connected state, and the second blocking member is aligned with the second through groove to make the second through groove open; in the second relative position, the first through groove is in the closed state, and the second blocking member blocks the second through groove to make the second through groove closed.
10. The atomizer according to claim 1, characterized in that, The first storage cavity and the second storage cavity are arranged adjacent to each other; Alternatively, the first storage cavity may be disposed around the outside of the second storage cavity; Alternatively, the first storage cavity may be provided in multiple ways, with the multiple first storage cavities arranged along the outer periphery of the second storage cavity, and the number of the first through slots corresponding to the number of the first storage cavities.
11. The atomizer according to claim 9, characterized in that, The suction nozzle has an extension extending toward the first chamber component, the extension covering the exterior of the first chamber component; The extension has a positioning structure on its inner side, and the outer wall of the first chamber has a corresponding mating structure. When the suction nozzle moves relative to the first chamber, the positioning structure and the mating structure work together to position the first through groove in the connected state or the closed state, and the second through groove in the open state or the closed state.
12. The atomizer according to any one of claims 1-11, characterized in that, The first compartment component and the second compartment component are integrally formed, or the first compartment component and the second compartment component are detachably connected.
13. The atomizer according to claim 8, characterized in that, The second chamber is also provided with a second air passage, and the atomizing core is connected between the second air passage and the air passage tube.
14. An atomizing device, characterized in that, The atomizing device includes an atomizer and a battery assembly, the battery assembly being electrically connected to the atomizer, and the atomizer being the atomizer described in any one of claims 1-13.