Split type electronic atomizer

Abstract

The application provides a split type electronic atomizer, which comprises a first body, a second body, an oil guide pipe and a switch component. The first body is provided with a first connecting part. The second body is provided with a second connecting part which is matched with the first connecting part. The oil guide pipe is arranged in the first body and is used for transmitting atomization medium. The switch component is arranged in the first body and is coupled with the oil guide pipe. An induction end of the switch component is exposed on a side of the first connecting part which is away from the first body. The switch component has a first working position and a second working position in the first body. The switch component in the first working position closes the oil guide pipe in a blocking mode. The switch component in the second working position opens the oil guide pipe in a butt joint mode. When the second connecting part is connected to the first connecting part, the induction end of the switch component is contacted through the second connecting part, so that the switch component is switched from the first working position to the second working position. The technical problem that an existing electronic atomizer cannot block the transmission of tobacco tar during factory transportation and sales is solved, and the service life is prolonged.

Description

Technical Field

[0001] This application relates to the technical field of atomizing devices, and more particularly to a split-type electronic atomizer. Background Technology

[0002] Electronic atomizers are a new type of smoking alternative that heats e-liquid to produce an inhalable aerosol, offering significant advantages over traditional cigarettes. They do not rely on combustion, thus avoiding the formation of harmful substances such as tar and carbon monoxide, thereby reducing health risks for users. Furthermore, electronic atomizers typically feature adjustable power, diverse flavors, and ease of use, meeting the personalized needs of different users. In addition, they are superior to traditional tobacco products in terms of environmental protection and social acceptance, and have rapidly gained popularity in the market in recent years, becoming a mainstream alternative in the context of increasing health awareness.

[0003] The common internal structure of electronic atomizers mainly consists of an e-liquid reservoir and an atomizing component. The reservoir stores e-liquid, while the atomizing component includes an atomization channel and a heating element to heat and atomize the e-liquid into an aerosol. The reservoir and atomization channel are connected by a conduit, ensuring a continuous supply of e-liquid to the atomization area for the user to inhale. This design ensures a stable e-liquid supply, improves atomization efficiency and user experience, and is widely used in various electronic cigarette products.

[0004] However, existing electronic atomizers still have significant drawbacks. Because the wicking channels lack opening and closing control, the e-liquid chamber and atomization channel remain constantly connected. This causes e-liquid to continuously seep into the atomization components during transportation or sale, potentially contaminating or damaging internal parts and affecting product lifespan. Furthermore, the direct connection between the atomization channel and the mouthpiece allows e-liquid to evaporate even without heating, resulting in waste, altering the flavor of the vapor, and reducing the user experience. Utility Model Content

[0005] This application provides a split-type electronic atomizer to solve the problem that the transmission of e-liquid in the electronic atomizer cannot be shut off during manufacturing, transportation, and sales. The technical solution is as follows:

[0006] This application provides a split-type electronic atomizer, including: a first body having a first connecting portion; a second body having a second connecting portion adapted to the first connecting portion; an oil guide channel disposed inside the first body for transmitting an atomizing medium; and a switch component disposed in the first body and coupled to the oil guide channel, wherein the sensing end of the switch component is exposed on the side of the first connecting portion away from the first body, the switch component has a first position and a second position in the first body, the switch component at the first position closes the oil guide channel in a blocking manner, and the switch component at the second position opens the oil guide channel in a docking manner.

[0007] When the second connecting part is connected to the first connecting part, the second connecting part contacts the sensing end of the switch component, so that the switch component switches from the first station to the second station.

[0008] In one embodiment, it further includes: a triggering component disposed on the side of the second connecting portion away from the second body, and the position of the triggering component corresponds to the position of the switching component; the first body has a slide groove, which is opened in a transverse manner on the oil guide pipe; the switching component is disposed in the slide groove and moves in the slide groove to switch between the first station and the second station, and the switching component has a connecting hole so that the triggering component can push the switching component to move from the first station to the second station;

[0009] Specifically, when the switching component is in the first position, the connecting hole and the oil guide pipe are misaligned to block the transmission path of the oil guide pipe through the switching component; when the switching component is in the second position, the connecting hole and the oil guide pipe are connected to open the transmission path of the oil guide pipe through the connecting hole.

[0010] In one embodiment, the switching component includes: a switch body, which has a plate-like structure and is slidably inserted into a groove; and a seal, which is disposed on the switch body and is interference-fitted with the groove. When the switch body slides through the seal to connect with the oil guide pipe, the seal can close the transmission path of the oil guide pipe.

[0011] In one embodiment, the switch body has a force-receiving part and a mounting part. The force-receiving part is located at the opening of the slide groove and is used to be pushed against by the triggering component to drive the switch body to move in the slide groove. A connecting hole is provided on the mounting part. A sealing member is sleeved on the mounting part and a clearance hole corresponding to the connecting hole is provided on the sealing member.

[0012] In one embodiment, the first body is further provided with an oil storage chamber and an atomization channel. The oil storage chamber is used to store the atomization medium, and the atomization channel is used to transport the converted atomization medium. The oil storage chamber and the atomization channel are connected by an oil guide pipe.

[0013] In one embodiment, it further includes: an atomizing component disposed in an atomizing channel for converting the atomizing medium from liquid to gas; and an input electrode disposed on a first connecting portion and electrically connected to the atomizing component, wherein the connecting end on the input electrode is exposed on the side of the first connecting portion away from the first body.

[0014] In one embodiment, it further includes: a power supply component disposed on the second body for storing electrical energy; and an output electrode disposed on the second connection portion and electrically connected to the power supply component, wherein the connection end of the output electrode is exposed on the side of the second connection portion away from the second body.

[0015] When the second connecting part is installed on the first connecting part, the output electrode and the input electrode are electrically connected in contact to deliver the electrical energy stored in the powered component to the atomizing component.

[0016] In one embodiment, it further includes: a first magnetic attractor, embedded in the first connecting portion; and a second magnetic attractor, embedded in the second connecting portion;

[0017] When the second connecting part is attached to the first connecting part, the second magnetic attractor is magnetically attracted to the first magnetic attractor.

[0018] In one embodiment, the first connecting part is provided with a positioning groove; the second connecting part is provided with a positioning protrusion that matches the positioning groove.

[0019] When the second connecting part is attached to the first connecting part, the positioning protrusion engages with the positioning groove to assist the second magnetic attractor in docking with the first magnetic attractor.

[0020] In one embodiment, it further includes: a mouthpiece, disposed on the first body, the mouthpiece being connected to the atomization channel for discharging the atomized medium converted into gas; and a dust plug, embedded in the smoke outlet of the mouthpiece for sealing the smoke outlet of the mouthpiece.

[0021] Compared to existing technologies, the split-type e-atomizer proposed in the above technical solution, through the linkage structure of a switch component and a trigger component between the first and second bodies, ensures that the e-atomizer's wicking channel is closed before initial use, significantly improving product safety, stability, and lifespan. Specifically, by incorporating a switch component with a one-way switching function into the wicking channel of the first body, the wicking channel remains closed before being "opened." In particular, when the e-atomizer is in transport or unused, the switch component is in the first position, completely blocking the wicking channel and preventing e-liquid from seeping into the atomization channel from the reservoir chamber. This design avoids internal contamination, component damage, and e-liquid evaporation problems caused by e-liquid leakage during transportation and storage, ensuring product quality stability in the distribution process and extending product lifespan. When the user prepares to use it for the first time, connecting the second body to the first body causes the trigger component on the second connection to abut against the outer end of the switch component, moving it from the first position to the second position, thereby opening the wicking channel and enabling normal e-liquid transport. It is worth noting that once the switch component moves from the first position to the second position, it cannot return to the first position. This means that once the wicking channel is opened, it cannot be closed again. This one-way operation design simplifies the user's steps, allowing for device activation without additional operations and improving ease of use. Since the switch component can only move from the first position to the second position, it ensures that the wicking channel remains closed until the product is first used, preventing e-liquid leakage during transportation and storage. Even after the user's first use, disassembling the first and second units will not affect the state of the wicking channel, avoiding seal failure caused by repeated disassembly and reassembly. Therefore, this application not only ensures the safety and reliability of the product during transportation and storage but also improves the user experience and reduces the flavor degradation caused by e-liquid prematurely entering the atomization component.

[0022] In summary, this application provides a compact, easy-to-operate, and safe split-type electronic atomizer. Its unique unidirectional switching mechanism overcomes many defects caused by continuous e-liquid penetration in existing technologies, offering a practical technical improvement solution for the transportation, storage, and use of electronic atomization products. This innovative design is particularly suitable for the electronic atomization market, which requires high reliability and strict quality control, and has broad application prospects and promotional value.

[0023] The above overview is for illustrative purposes only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of this application will become readily apparent from the accompanying drawings and the following detailed description. Attached Figure Description

[0024] In the accompanying drawings, unless otherwise specified, the same reference numerals throughout the various drawings denote the same or similar parts or elements. These drawings are not necessarily drawn to scale. It should be understood that these drawings depict only some embodiments disclosed in this application and should not be construed as limiting the scope of this application.

[0025] Figure 1 This is a schematic diagram of the internal structure of a split-type electronic atomizer in the separated state in an embodiment of this application;

[0026] Figure 2 This is a schematic diagram showing the position of the switch component in the separated state in an embodiment of this application;

[0027] Figure 3 This is a schematic diagram of the internal structure of a split-type electronic atomizer in its combined state, as described in this application embodiment.

[0028] Figure 4 This is a structural schematic diagram showing the position of the switch component in the combined state in an embodiment of this application;

[0029] Figure 5 This is a schematic diagram of the structure of the switch component in an embodiment of this application;

[0030] Figure 6 This is a schematic diagram of the electrical connection between the atomizing component and the input electrode in an embodiment of this application;

[0031] Figure 7 This is a diagram showing the installation of the input and output electrodes in an embodiment of this application.

[0032] Figure 8 This is a distribution diagram of the output electrodes in an embodiment of this application.

[0033] Figure label:

[0034] 1. The first ontology;

[0035] 11. First magnetic suction component; 12. Cigarette mouthpiece component; 13. Dust plug;

[0036] 101. First connecting part; 102. Slide groove; 103. Oil storage chamber; 104. Atomization channel; 105. Positioning groove;

[0037] 2. Second body;

[0038] 21. Second magnetic chuck;

[0039] 201. Second connecting part; 202. Positioning protrusion;

[0040] 3. Oil guiding pipe;

[0041] 4. Switching components;

[0042] 41. Switch body; 42. Seal;

[0043] 410. Connecting hole; 411. Force-bearing part; 412. Mounting part; 421. Clearance hole;

[0044] 5. Triggering component; 6. Atomizing component; 7. Input electrode; 8. Power supply component; 9. Output electrode. Detailed Implementation

[0045] In the following description, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments can be modified in various ways without departing from the spirit or scope of this application. Therefore, the drawings and description are considered to be exemplary in nature and not restrictive.

[0046] Reference Figures 1 to 8 As shown, an embodiment of this application proposes a split-type electronic atomizer, which may include: a first body 1 having a first connecting portion 101; a second body 2 having a second connecting portion 201 adapted to the first connecting portion 101; an oil guide tube 3 disposed inside the first body 1 for transmitting the atomizing medium; a switch component 4 disposed in the first body 1 and coupled to the oil guide tube 3, the outer end of the switch component 4 being exposed on the side of the first connecting portion 101 away from the first body 1; the switch component 4 having a first position and a second position in the first body 1; the switch component 4 at the first position closing the oil guide tube 3 in a blocking manner; and the switch component 4 at the second position opening the oil guide tube 3 in a docking manner; and a trigger component 5 protrudingly disposed on the side of the second connecting portion 201 away from the second body 2.

[0047] When the second connecting part 201 is installed on the first connecting part 101, the position of the switch component 4 corresponds to the position of the trigger component 5. The trigger component 5 abuts against the outer end of the switch component 4, so that the switch component 4 moves from the first station to the second station.

[0048] Specifically, in the technical solution adopted in this application, the first body 1 and the second body 2 are independent shells that can be detached or combined. In order to facilitate the combination of the first body 1 and the second body 2, a first connecting part 101 is provided on the first body 1, and a second connecting part 201 is provided on the second body 2. The combination of the first connecting part 101 and the second connecting part 201 facilitates the combination function of the first body 1 and the second body 2. An oil guiding pipe 3 is provided in the first body 1 for transmitting the atomizing medium. After conversion, the atomizing medium is used by the user, such as e-liquid. In order to improve the storage quality of the atomizing medium and prevent the atomizing medium from continuously penetrating the functional components inside the electronic atomizer during transportation, it is necessary to close the oil guiding pipe 3 under certain circumstances. Therefore, the key technical point of this application is that a mutually compatible switch component 4 and trigger component 5 are provided between the first body 1 and the second body 2. Since the oil guide pipe 3 is located inside the first body 1, the switch component 4 is disposed in the first connecting part 101 and coupled to the oil guide pipe 3 to adjust the opening and closing state of the oil guide pipe 3, so that the flow rate of the atomizing medium transmitted through the oil guide pipe 3 can be controlled by the switch component 4. Specifically, the switch component 4 has two movable positions in the first body 1, which can be defined as the first position and the second position. In use, when the switch component 4 is in the first position, the switch component 4 blocks the oil guide pipe 3 by blocking it, so that the atomizing medium cannot be transmitted through the oil guide pipe 3, thereby achieving the purpose of closing the oil guide pipe 3; while when the switch component 4 moves from the first position to the second position, the switch component 4 connects to the oil guide pipe 3 by connecting it, so that the atomizing medium can be transmitted through the oil guide pipe 3, thereby achieving the purpose of opening the oil guide pipe 3. The trigger component 5 is disposed on the second connecting part 201, located on the side of the second connecting part 201 opposite to the second body 2. To allow the trigger component 5 to contact the switch component 4, the outer end of the switch component 4 is exposed on the side of the first connecting part 101 opposite to the first body 1. When the second connecting part 201 connects to the first connecting part 101, the second body 2 and the first body 1 are combined. The trigger component 5 pushes the switch component 4 from the first position to the second position, thus enabling the split-type electronic atomizer proposed in this application to have a transport mode and a ready-to-use mode. In the transport mode, the switch component 4 is in the first position with the oil guide pipe 3 closed, thereby preventing premature penetration of the atomizing medium into the first body 1, which could cause product quality problems, effectively extending the product's lifespan and allowing for strict quality control. The product can be in transport mode before use, and can be switched to ready-to-use mode when the user uses it. For example, the split-type electronic atomizer can be in transport mode during the transportation process after manufacturing and during the sales process.

[0049] Furthermore, refer to Figure 2 and Figure 3As shown, in some embodiments, the first body 1 has a slide groove 102, which is opened in a transverse manner on the oil guide pipe 3; the switch component 4 is disposed in the slide groove 102 and moves in the slide groove 102 to switch the first working position and the second working position, and the switch component 4 is provided with a connecting hole.

[0050] When the switch component 4 is in the first position, the connecting hole is misaligned with the oil guide pipe 3 to block the transmission path of the oil guide pipe 3 through the switch component 4; when the switch component 4 is in the second position, the connecting hole is connected with the oil guide pipe 3 to open the transmission path of the oil guide pipe through the connecting hole.

[0051] Specifically, in the technical solution adopted in this application, in order to enable the switch component 4 to move from the first station to the second station, a slide groove 102 is provided on the first body 1 for the switch component 4 to slide in the slide groove 102. The slide groove 102 corresponds to the oil guide pipe 3 and is opened in a transverse manner on the oil guide pipe 3 so that the oil guide pipe 3 is cut off by the slide groove 102, and the switch component 4 is slidably arranged in the slide groove 102 to control the opening and closing of the oil guide pipe 3. Specifically, a connecting hole is provided on the switch component 4. The switch component 4 is moved in the slide groove 102 so that the connecting hole is in a misaligned or connected state with the oil guide pipe 3. For example, when the switch component 4 moves to the first position in the slide groove 102, the transmission path of the connecting hole and the oil guide pipe 3 is misaligned, thereby blocking the transmission path of the oil guide pipe 3 through part of the switch component 4 structure on the outer periphery of the connecting hole, so as to achieve the purpose of closing the oil guide pipe 3. When the switch moves to the second position in the slide groove 102, the transmission path of the connecting hole and the oil guide pipe 3 is connected, thereby connecting the transmission path of the cut-off oil guide pipe 3 through the connecting hole, so as to achieve the purpose of opening the oil guide pipe 3.

[0052] Furthermore, refer to Figure 5 As shown, in some embodiments, the switch component 4 includes: a switch body 41, which has a plate-like structure and is slidably inserted into the slide groove 102; and a seal 42, which is disposed on the switch body 41 and is interference-fitted with the slide groove 102. When the switch body 41 slides and the seal 42 connects to the oil guide pipe 3, the seal 42 can close the transmission path of the oil guide pipe 3.

[0053] Specifically, in the technical solution adopted in this application, the switch body 41 is disposed on a plate-like structure that can slide in the slide groove 102, so that the switch body 41 can move from the first station to the second station. The sealing element 42 is installed on the switch body 41 and fills the gap between the switch body 41 and the slide groove 102 in a tight fit, thereby preventing leakage of the atomizing medium through the slide groove 102. In use, when the switch body 41 is in the first station, the sealing element 42 can close the interrupted transmission path on the oil guide pipe 3; and when the switch body is in the second station, the sealing element 42 can fill the gap at the outer periphery of the connecting hole, that is, the gap between the switch body 41 and the slide groove 102, so that the atomizing medium is transmitted only through the connecting hole, and the oil guide pipe 3 can stably transmit the atomizing medium.

[0054] Furthermore, refer to Figure 5 As shown, in some embodiments, the switch body 41 has a force-receiving part 411 and a mounting part 412. The force-receiving part 411 is located at the opening of the slide groove 102 and is used to be pushed by the triggering component 5 to drive the switch body 41 to move in the slide groove 102. A connecting hole is provided on the mounting part 412. The sealing member 42 is sleeved on the mounting part 412 and a clearance hole 421 corresponding to the connecting hole is provided on the sealing member 42.

[0055] Specifically, in the technical solution adopted in this application, the force-bearing part 411 extends along the width direction of the slide groove 102, so that the force-bearing part 411 has a larger contact area for the triggering component 5 to contact, avoiding the situation where the triggering component 5 slides directly into the slide groove 102 without pushing the switch body 41 from the first station to the second station or cannot be pushed into place. The mounting part 412 extends along the depth direction of the slide groove 102, so that it can be configured in the slide groove 102 in a plug-in manner, and the connecting hole for connecting the oil guide pipe 3 is opened on the mounting part 412. The sealing member 42 is also sleeved on the mounting part 412, and the sealing member 42 is also provided with a relief hole 421 corresponding to the connecting hole, so that when the connecting hole is connected to the oil guide pipe 3, under the premise that the sealing member 42 closes the gap between the switch body 41 and the slide groove 102, the connecting hole can transmit the atomizing medium normally through the relief hole 421 without being affected by the sealing member 42.

[0056] Furthermore, refer to Figure 1 As shown, in some embodiments, the first body 1 is further provided with an oil storage chamber 103 and an atomization channel 104. The oil storage chamber 103 is used to store the atomization medium, and the atomization channel 104 is used to transport the converted atomization medium. The oil storage chamber 103 and the atomization channel 104 are connected through an oil guide pipe 3.

[0057] Specifically, in the technical solution adopted in this application, the first body 1 has an oil storage chamber 103 and an atomizing channel 104. In order to better store the atomizing medium in the oil storage chamber 103, oil storage cotton can be filled in the oil storage chamber 103. The atomizing channel 104 is used to transport the atomizing medium that is converted from liquid to gas. The atomizing channel 104 is connected to the oil storage chamber 103 through an oil guide channel, so that the liquid atomizing medium stored in the oil storage chamber 103 can be transferred to the atomizing channel 104 through the oil guide channel, so that the atomizing medium can be converted from liquid to gas in the atomizing channel 104.

[0058] Furthermore, refer to Figure 1 and Figure 6 As shown, in some embodiments, it further includes: an atomizing component 6, disposed in the atomizing channel 104, for converting the atomizing medium from liquid to gas; and an input electrode 7, disposed on the first connecting portion 101 and electrically connected to the atomizing component 6, with the connecting end on the input electrode 7 exposed on the side of the first connecting portion 101 away from the first body 1.

[0059] Specifically, in the technical solution adopted in this application, in order to convert the atomizing medium from liquid to gas, an atomizing component 6 is arranged in the atomizing channel 104. The atomizing component 6 can heat the liquid medium until it is converted into gas, and then transmit it to the user through the atomizing channel 104. An input electrode 7 is installed on the first connecting part 101 and is electrically connected to the atomizing component 6. The connection end of the output electrode 9 is exposed on the side of the first connecting part 101 away from the first body 1, for receiving electrical energy to supply the atomizing component 6. The atomizing component 6 then converts the electrical energy into heat energy and transmits the heat energy to the liquid atomizing medium in the atomizing channel 104.

[0060] Furthermore, refer to Figure 1 , Figure 7 and Figure 8 As shown, in some embodiments, it further includes: a power supply component 8, disposed on the second body 2, for storing electrical energy; and an output electrode 9, disposed on the second connection portion 201 and electrically connected to the power supply component 8, with the connection end of the output electrode 9 exposed on the side of the second connection portion 201 away from the second body 2.

[0061] When the second connection part 201 is installed on the first connection part 101, the output electrode 9 and the input electrode 7 are electrically connected in contact to deliver the electrical energy stored in the powered component 8 to the atomizing component 6.

[0062] Specifically, in the technical solution adopted in this application, in order to enable the second body 2 to supply electrical energy to the atomizing component 6 when it is combined with the first body 1 via the second connecting part 201 and the first connecting part 101, the second body 2 has a built-in power supply component 8 capable of storing electrical energy, such as a battery, and an output electrode 9 electrically connected to the power supply component 8 is installed on the second connecting part 201, with the connection end of the output electrode 9 exposed on the side of the second connecting part 201 away from the second body 2. In use, when the first connecting part 101 and the second connecting part 201 are connected, the output electrode 9 corresponds to the position of the input electrode 7, so that the output electrode 9 can be electrically connected to the input electrode 7 in a contact manner, so as to deliver the electrical energy stored in the power supply component 8 to the atomizing component 6. In this embodiment, when the first body 1 and the second body 2 are separated, not only is the oil guiding pipe 3 closed by the switch component 4, but the power to the atomizing component 6 is also cut off, so that the oil guiding function and power supply function of the split electronic atomizer are both turned off in the transportation mode, to ensure the quality control of the split electronic atomizer.

[0063] Furthermore, refer to Figure 1 and Figure 3 As shown, in some embodiments, it further includes: a first magnetic suction member 11, embedded in the first connecting portion 101; and a second magnetic suction member 21, embedded in the second connecting portion 201;

[0064] When the second connecting part 201 is attached to the first connecting part 101, the second magnetic member 21 is magnetically attracted to the first magnetic member 11.

[0065] Specifically, in the technical solution adopted in this application, in order to achieve a detachable connection between the first connecting part 101 and the second connecting part 201, a first magnetic attractor 11 can be embedded in the first connecting part 101, and a second magnetic attractor 21 can be embedded in the second connecting part 201. The first magnetic attractor 11 and the second magnetic attractor 21 can attract each other, so that when the second connecting part 201 is installed on the first connecting part 101, the second magnetic attractor 21 can adhere to the first magnetic attractor 11, thereby enabling the first body 1 and the second body 2 to quickly assemble and separate using magnetic attraction through the first connecting part 101 and the second connecting part 201. The first magnetic attractor 11 and the second magnetic attractor 21 can be made of magnetic material, and one end of the first magnetic attractor 11 and one end of the second magnetic attractor 21 that are mated with each other in the first connecting part 101 and the second connecting part 201 are opposite magnetic poles, thereby attracting each other.

[0066] Furthermore, refer to Figure 1 As shown, in some embodiments, the first connecting part 101 is provided with a positioning groove 105; the second connecting part 201 is provided with a positioning protrusion 202 that is adapted to the positioning groove 105.

[0067] When the second connecting part 201 is attached to the first connecting part 101, the positioning protrusion 202 engages with the positioning groove 105 to assist the second magnetic suction member 21 in docking with the first magnetic suction member 11.

[0068] Specifically, in the technical solution adopted in this application, in order to achieve accurate docking of the first magnet and the second magnet, as well as the switch component 4 and the trigger component 5, a positioning groove 105 can be formed on the first connecting part 101, and a positioning protrusion 202 can be provided on the second connecting part 201. When the first connecting part 101 and the second connecting part 201 are connected, the positioning protrusion 202 passes through the positioning groove 105 to position the second connecting part 201 to fit against the first connecting part 101. Preferably, the positioning groove 105 can be set as a closed-loop structure and arranged circumferentially on the outer edge of the first connecting part 101, and the positioning protrusion 202 can also be set as a closed-loop structure adapted to the positioning groove 105, arranged circumferentially along the second connecting part 201 and located on the outer edge of the second connecting part 201. When the second connecting part 201 connects to the first connecting part 101, it can be accurately positioned by engaging with the positioning groove 105 through the positioning protrusion 202. This allows the first magnetic suction member 11 and the second magnetic suction member 21 to be precisely connected, so that the second body 2 is stably connected to the first body 1. The triggering member 5 can also accurately push the switching member 4 deeper into the slide groove 102, i.e., move it from the first station to the second station. It should be noted that in this application, there are also input electrodes 7 and output electrodes 9 that need to be connected, which are also precisely connected through the positioning groove 105 and the positioning protrusion 202, so that the power supply member 8 supplies power to the atomizing member 6.

[0069] Furthermore, refer to Figure 1 As shown, in some embodiments, it further includes: a mouthpiece 12, disposed on the first body 1, the mouthpiece 12 being connected to the atomization channel 104 for discharging the atomized medium converted into gas; and a dust plug 13, embedded in the smoke outlet of the mouthpiece 12 for sealing the smoke outlet of the mouthpiece 12.

[0070] Specifically, in the technical solution adopted in this application, the mouthpiece 12 connected to the atomization channel 104 is used to provide the user with an atomizing medium that is converted into gas. When in use, the user can simply inhale by pointing their mouth at the mouthpiece 12. The dust plug 13 is embedded in the mouthpiece 12 when not in use to prevent dust or other foreign objects from entering the interior of the first body 1 through the mouthpiece 12 and causing damage.

[0071] In the description of this specification, the references to terms such as "one embodiment," "some embodiments," "example," "specific example," or "some examples," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of this application. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. Moreover, without contradiction, those skilled in the art can combine and integrate the different embodiments or examples described in this specification, as well as the features of those different embodiments or examples.

[0072] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. In the description of this application, "a plurality of" means two or more, unless otherwise explicitly specified.

[0073] Any process or method description in the flowchart or otherwise herein can be understood as representing a module, segment, or portion of code comprising one or more executable instructions for implementing a particular logical function or process. Furthermore, the scope of the preferred embodiments of this application includes additional implementations in which functions may be performed not in the order shown or discussed, including substantially simultaneously or in reverse order depending on the functionality involved.

[0074] The logic and / or steps represented in the flowchart or otherwise described herein, for example, can be considered as a sequenced list of executable instructions for implementing logical functions, and can be embodied in any computer-readable medium for use by, or in conjunction with, an instruction execution system, apparatus or device (such as a computer-based system, a processor-included system or other system that can fetch and execute instructions from, an instruction execution system, apparatus or device).

[0075] It should be understood that various parts of this application can be implemented using hardware, software, firmware, or a combination thereof. In the above embodiments, multiple steps or methods can be implemented using software or firmware stored in memory and executed by a suitable instruction execution system. All or part of the steps of the methods in the above embodiments can be implemented by a program instructing related hardware, the program being stored in a computer-readable storage medium, which, when executed, includes one or a combination of the steps of the method embodiments.

[0076] Furthermore, the functional units in the various embodiments of this application can be integrated into a processing module, or each unit can exist physically separately, or two or more units can be integrated into a module. The integrated module can be implemented in hardware or as a software functional module. If the integrated module is implemented as a software functional module and sold or used as an independent product, it can also be stored in a computer-readable storage medium. This storage medium can be a read-only memory, a disk, or an optical disk, etc.

[0077] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any person skilled in the art can easily conceive of various variations or substitutions within the technical scope disclosed in this application, and these should all be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. A split-type electronic atomizer, characterized in that, include: The first body has a first connecting part; The second body has a second connecting portion adapted to the first connecting portion; An oil guide pipe, disposed inside the first body, is used to transport the atomizing medium; and, A switching component is disposed in the first body and coupled to the oil guide pipe. The sensing end of the switching component is exposed on the side of the first connection portion away from the first body. The switching component has a first working position and a second working position in the first body. The switching component at the first working position closes the oil guide pipe in a blocking manner, and the switching component at the second working position opens the oil guide pipe in a docking manner. When the second connecting part is connected to the first connecting part, the second connecting part contacts the sensing end of the switch component, thereby switching the switch component from the first station to the second station.

2. A split-type electronic atomizer according to claim 1, characterized in that, Also includes: A triggering component is disposed on the side of the second connecting portion away from the second body, and the position of the triggering component corresponds to the position of the switch component; The first body has a groove, which is formed on the oil guide pipe in a transverse manner; The switching component is disposed in the slide groove and moves in the slide groove to switch between the first station and the second station. The switching component is provided with a connecting hole so that the triggering component can push the switching component to move from the first station to the second station. When the switch component is in the first working position, the connecting hole is misaligned with the oil guide pipe to block the transmission path of the oil guide pipe through the switch component; when the switch component is in the second working position, the connecting hole is connected with the oil guide pipe to open the transmission path of the oil guide pipe through the connecting hole.

3. A split-type electronic atomizer according to claim 2, characterized in that, The switching component includes: The switch body has a plate-like structure and is slidably inserted into the slide groove; A seal is disposed on the switch body, and the seal is interference-fitted with the slide groove. When the switch body slides and the seal connects to the oil guide pipe, the seal can close the transmission path of the oil guide pipe.

4. A split-type electronic atomizer according to claim 3, characterized in that, The switch body has a force-receiving part and a mounting part. The force-receiving part is located at the opening of the slide groove and is used to be pushed by the triggering component to drive the switch body to move in the slide groove. The mounting part is provided with the connecting hole. The sealing element is fitted onto the mounting portion, and the sealing element has a clearance hole corresponding to the communicating hole.

5. A split-type electronic atomizer according to claim 1, characterized in that, The first body also includes an oil storage chamber and an atomization channel. The oil storage chamber is used to store the atomization medium, and the atomization channel is used to transport the converted atomization medium. The oil storage chamber and the atomization channel are connected through the oil guide pipe.

6. A split-type electronic atomizer according to claim 5, characterized in that, Also includes: An atomizing component, disposed in the atomizing channel, is used to convert the atomizing medium from liquid to gas; An input electrode is disposed on the first connecting portion and electrically connected to the atomizing component, and the connecting end on the input electrode is exposed on the side of the first connecting portion away from the first body.

7. A split-type electronic atomizer according to claim 6, characterized in that, Also includes: A power supply component, disposed on the second body, is used to store electrical energy; An output electrode is disposed on the second connection portion and electrically connected to the power supply component, and the connection end of the output electrode is exposed on the side of the second connection portion away from the second body. When the second connection part is installed on the first connection part, the output electrode and the input electrode are electrically connected in contact to deliver the electrical energy stored in the powered component to the atomizing component.

8. A split-type electronic atomizer according to claim 1, characterized in that, Also includes: The first magnetic suction element is embedded in the first connecting part; The second magnetic attractor is embedded in the second connecting part; When the second connecting part is attached to the first connecting part, the second magnetic attractor is magnetically attracted to the first magnetic attractor.

9. A split-type electronic atomizer according to claim 8, characterized in that, The first connecting part is provided with a positioning groove; The second connecting part is provided with a positioning protrusion that matches the positioning groove; When the second connecting part is attached to the first connecting part, the positioning protrusion engages with the positioning groove to assist the second magnetic attractor in docking with the first magnetic attractor.

10. A split-type electronic atomizer according to claim 5, characterized in that, Also includes: A mouthpiece is disposed on the first body and is connected to the atomizing channel for discharging the atomizing medium that has been converted into gas. A dust plug is embedded in the smoke outlet of the mouthpiece to seal the smoke outlet of the mouthpiece.

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