KR20240049334A - electronic atomizer - Google Patents

Abstract

An electronic atomization device, comprising: a housing (1), an aerosol raw material reservoir (2), an aerosol generating device (3), and a power assembly (4); An assembly window 112 is installed in the shell 11, and the assembly window 112 is an assembly window of the electronic atomization device through which the aerosol raw material storage container 2, the aerosol generating device 3, and the power assembly 4 are installed. Assembled in the shell 11, the assembly window 112 is also a replacement window for the consumable material, where the consumable material is an aerosol raw material reservoir 2, or an aerosol raw material reservoir 2 and an aerosol generating device ( 3) is the whole formed. The assembly window 112 is installed to serve as the assembly window of the electronic atomization device and the replacement window for consumable materials at the same time, which simplifies the shell structure of the electronic atomization device and allows the electronic atomization device to have better integration, and the cover 13 By moving, the assembly window 112 is exposed to visualize the connection relationship between the consumable material and the power assembly 4, so that the consumable material is not assembled in place, leading to poor contact between the consumable material and the power assembly 4, and the user's normal This can prevent it from affecting use.

Description

electronic atomizer

This application claims priority of the Chinese patent application filed with the Chinese Intellectual Property Office on August 20, 2021, application number 202110959477.2, and entitled “Electronic Atomizing Device,” the entire contents of which are incorporated herein by reference.

Embodiments of the present invention relate to the field of aerosol atomization technology, and particularly to electronic atomization devices.

Electronic atomization devices are designed to heat aerosol raw materials to produce aerosols worth using.

The conventional electronic atomization device includes an aerosol raw material reservoir and stores the aerosol raw material through the aerosol raw material storage bin. However, the aerosol raw material is a consumable item, and the aerosol raw material is continuously consumed as the electronic atomization device is used, so when the aerosol raw material is insufficient, At a minimum, the aerosol raw material reservoir should be replaced.

Conventional electronic atomization devices generally have a cylindrical structure in which the shell has at least two assembly windows, one assembly window is for replacing the carrier of aerosol raw materials such as a cartridge or aerosol raw material reservoir, and one assembly window is for the power assembly. Since it is for assembly, the structure of the electronic atomization device becomes complicated, and for example, the power assembly must be packaged by installing a bottom cover, and the carrier of the aerosol raw material must be packaged by installing a side cover or top cover, etc. Multiple shielding members must be designed to cover different assembly windows, which reduces the integration of the electronic atomization device and complicates assembly.

The embodiment of the present application installs an assembly window and serves as an assembly window for the electronic atomization device and a replacement window for consumable materials, thereby simplifying the structure of the electronic atomization device and improving the integration of the electronic atomization device, thereby enabling assembly of the electronic atomization device. The purpose is to provide an electronic atomization device that is simpler and allows the connection between the consumable material and the power assembly to be exposed by exposing the assembly window through the cover so that the consumable material can be replaced simply and visually.

An embodiment of the present application provides an electronic atomization device,

shell;

An aerosol raw material storage bin for storing aerosol raw materials;

An aerosol generating device for generating an aerosol using the aerosol raw material;

a power assembly electrically connected to the aerosol generating device to provide electrical energy necessary for aerosol generation;

- The shell is provided with an assembly window;

the assembly window is for providing an opening for assembling the aerosol raw material reservoir, the aerosol generating device, and the power assembly into the shell;

The assembly window is also a replacement window for consumable materials, for replacing consumable materials through the assembly window, wherein the consumable material is the aerosol raw material reservoir or the whole formed by the aerosol raw material reservoir and the aerosol generating device;

Includes a cover to movably cover the assembly window.

An embodiment of the present application provides an electronic atomization device,

A shell with a defined receiving cavity;

An aerosol generating device comprising a first electrode;

a power assembly including a second electrode, electrically connected to the aerosol generating device through contact between the second electrode and the first electrode, and providing electrical energy required for aerosol generation;

the shell has an assembly window to provide an opening for mounting the aerosol generating device and power assembly to the receiving cavity; A wall of the receiving cavity contacts a surface of the aerosol generating device and/or power assembly, causing at least one of the first electrode and the second electrode to be compressed to maintain electrical conduction between the two.

The electronic atomizing device is equipped with an assembly window, which serves as an assembly window for the electronic atomizing device and a replacement window for consumable materials, which simplifies the shell structure of the electronic atomizing device and makes the electronic atomizing device have better integration. In addition, the cover movably covers the assembly window, and by moving the cover, the assembly window is exposed to visualize the connection relationship between the consumable material and the power assembly, so that new consumable materials are not assembled in place, causing a gap between the consumable material and the power assembly. This can prevent it from leading to poor contact and affecting the user's normal use.

One or more embodiments are illustratively described through illustrations in the corresponding drawings, but these illustrative descriptions are not intended to limit the embodiments, and components having the same reference numerals in the drawings indicate similar components. And, except as specifically explained, pictures in the drawings are not limited by proportion.
Figure 1 is an exploded view of an electronic atomization device provided by an embodiment of the present application.
Figure 2 is an assembly diagram of an electronic atomization device provided by an embodiment of the present application.
Figure 3 is a cross-sectional view of an electronic atomization device provided by an embodiment of the present application.
Figure 4 is another cross-sectional view of an electronic atomization device provided by an embodiment of the present application.
Figure 5 is a cross-sectional view of one sleeve material provided by one embodiment of the present application.
Figure 6 is a diagram of a power assembly provided by an embodiment of the present application.
Figure 7 is another diagram of a power assembly provided by an embodiment of the present application.
Figure 8 is a three-dimensional view of a shell member provided by an embodiment of the present application.
Figure 9 is a cross-sectional view of Figure 8.
Figure 10 is a cross-sectional view after assembling the power assembly to the shell.

A clear and complete description of the technical solutions in the embodiments of this application will be provided with reference to the drawings in the embodiments of the present application below. The described embodiments are only some embodiments of the present application and are not all embodiments. It is self-evident. All other embodiments that can be obtained by those skilled in the art based on the embodiments of the present application without requiring creative efforts should all fall within the scope of the present application.

The terms “first” and “second” in this application are only for convenience of explanation and do not indicate or imply relative importance or reveal the quantity of the technical feature that is implicitly indicated. All directional indications (e.g., up, down, left, right, front, back...) in the embodiments of the present application only refer to the relative relationship between each part under a certain posture (e.g., as shown in the drawings). It is intended to explain location, movement situation, etc., and if the specific posture changes, the directional indication also changes correspondingly. Additionally, the terms “comprise” and “including” and any variations thereof are intended to indicate non-exclusive inclusion. A process, method, system, product or device comprising a series of steps or units is not limited to the steps or units already listed, but may also optionally include steps or units not listed, or optionally also include such processes, methods, Includes other steps or units unique to the product or device.

“Embodiments” mentioned in the text mean that specified features, structures, or characteristics described with reference to the examples may be included in at least one embodiment of the present application. The sentences appearing at each position in the specification do not all refer to the same embodiment, nor are they independent or preliminary embodiments mutually exclusive of other embodiments. Those skilled in the art will understand, explicitly or implicitly, that the embodiments described herein may be combined with other embodiments.

It should be noted that when an element is said to be "anchored" to another element, it may be directly on or within one of the other elements. When an element is "connected" to another element, it may be connected directly to the other element, or there may be one or more intermediate elements between them at the same time. As used herein, the terms “vertical,” “horizontal,” “left,” “right,” and similar descriptions are for descriptive purposes only and do not represent exclusive embodiments.

One embodiment of the present application provides an electronic atomization device (100) including a housing (1), an aerosol raw material reservoir (2), an aerosol generating device (3), and a power assembly (4).

In some embodiments, the aerosol raw material reservoir 2 includes a raw material reservoir, a first airway 22, and a connecting member 23.

The first airway 22 is for delivering aerosol, and in some embodiments, referring to FIGS. 3 and 5, at least a portion of the first airway 22 is controlled by the inner tube of the aerosol raw material reservoir 2. It is formed in a limited way.

The raw material container is for storing liquid aerosol raw materials, and the aerosol raw materials may be liquid aerosol raw materials, solid aerosol raw materials, or may be a mixed aerosol raw material of liquid and solid. When aerosol raw materials are heated, they produce volatile substances to form an aerosol. In some embodiments, referring to FIGS. 3 and 5, at least a portion of the first airway 22 is located within the raw material container.

The connecting member 23 is for connecting the raw material container to the housing 1. The connecting member 23 can help the aerosol raw material storage container 2 be more easily assembled into the housing 1, and can also help the aerosol material storage container 2 to be more easily assembled. ) can help to be more stably fixed to the housing (1). In some embodiments, referring to FIGS. 3 and 5, one end of the connecting member 23 is fixed to the raw material container and connected to the first airway 22, and the other end is in contact with the housing 1.

In some embodiments, referring to FIGS. 3, 5, and 8, a fixing groove 242 is installed on the fabric of the raw material container, and the connecting member 23 includes a body 233 and an extension portion 232. The extension portion 232 is located at the distal end of the body 233, the body 233 is detachably fixed to the fixing groove 242, and the extension portion 145 is attached to the proximal end of the first airway 22. It is fitted so that the fabric and extension portion 145 of the first airway 22 are fixed to each other. When the body 141 and the raw material container are fixed to each other, the fabric of the first airway 22 is indirectly fixed to the raw material container by the connecting member 23.

The body 233 and the extension portion 234 of the connecting member 23 are penetrated by the third airway 232, so that when the connecting member 23 is fixed to the raw material container, the third airway 232 is connected to the first airway. It is connected to (22).

3 and 4, the connecting member 23 is fixed to the fixing groove 242, its proximal end protrudes from the fixing groove 242 and contacts the housing 1, and the connecting member 23 is elastic. Since it has, the connecting member 23 can be in elastic contact with the housing 1, and after the aerosol raw material storage container 2 is assembled to the housing 1, the connecting member 23 is in an elastically compressed state, so that the housing ( The connection between 1) and the aerosol raw material reservoir (2) can be made more stable and tighter, and the connecting member (23) has elasticity, so that during the process of assembling the aerosol raw material reservoir (2), the connecting member (23) can be elastically contracted, making it easy for the aerosol raw material reservoir 2 to be pressed into the shell 12.

In some embodiments, the housing 1 is equipped with a suction nozzle assembly 12, and the suction nozzle assembly 12 may be molded integrally with the housing 1 and may also be fixed to the housing 1 by assembly. It can be. Referring to Figures 1 to 3, a suction nozzle assembly 12 is installed in the housing 1, one end of the suction nozzle assembly 12 is a part that is bitten by the user's mouth, and the other end is an aerosol discharge passage (e.g. For example, coupled to the first airway 22) to deliver the aerosol to the user's mouth. 3 and 5, the suction nozzle assembly 12 includes a second airway 121 and a suction nozzle 122 installed at the distal end of the second airway 121, and the suction nozzle 122 is located at the mouth. It can be bitten into, and the first airway 22 and the second airway 121 communicate through the third airway 232 of the connecting member 23.

In the process of delivering the aerosol from the second airway 121, for example, due to a decrease in temperature, it may be liquefied or condensed to form a liquid before leaving the suction nozzle, and the liquid may enter the second airway under the action of gravity. After flowing back to the proximal end of 121, it may spread radially to the surroundings along the wall of the suction nozzle assembly 12 and leak.

In some embodiments, referring to FIGS. 3 and 5, the connecting member 23 contacts the suction nozzle assembly 12 within the housing 1 to seal the connection between the first airway 22 and the housing 1. By doing so, in the process of transferring the aerosol from the first airway 22 to the distal end of the second airway 121, the aerosol is prevented from leaking from the connection portion between the connecting member 23 and the housing 1, and also It is possible to prevent outside air from flowing into the suction nozzle assembly (12) through the connection portion between the connection member (23) and the housing (1) to dilute the aerosol and affect the taste, and furthermore, the suction nozzle assembly (12) It prevents the liquid flowing back from leaking out from the connection portion between the connecting member 23 and the housing 1.

Furthermore, referring to Figures 3 and 5, an annular boss 231 is installed at the proximal end of the connecting member 23, the annular boss 231 has elasticity, and the aerosol raw material reservoir 2 is attached to the shell 111. After being mounted inside, the annular boss 231 may surround the outer edge of the second airway 121, and the annular boss 231 is in an elastically compressed state, so that the condensate flowing back from the second airway 121 is sucked. When spreading circumferentially along the nozzle assembly 12 toward the wall of the connecting member 23, it can be blocked by the annular boss 231, thereby condensing the condensate within the range of the annular boss 231, or allowing the condensate to form an annular shape. It is possible to prevent leakage of condensate by allowing it to flow back from the boss 231 to the first airway 22.

In some embodiments, the suction nozzle assembly 12 may be installed with a concave area of one turn at a position directly opposite the annular boss 231, and the annular boss 231 may be inserted into the concave area and be in contact with the concave area. Here, the depression depth or shape of the concave area may be designed according to the specific situation, so that the condensate flowing back from the suction nozzle assembly 12 cannot flow beyond the annular boss 231 to the outer section of the annular boss 231. It is difficult, where the annular boss 231 does not have elasticity and can block the liquid flow only by the height of the annular boss 231; At least the proximal end of the annular boss 231 may also have elasticity, where the annular boss 231 is in contact with the concave area to have better sealing properties and prevent the flow of liquid more effectively.

In some embodiments, at least a portion of the aerosol raw material storage bin 2 is transparent, and the amount of aerosol raw material stored inside the aerosol raw material storage bin 2 is observed from the outside to intuitively determine whether the aerosol raw material storage bin 2 needs to be replaced. can do. In addition, when the aerosol output from the electronic atomization device 100 is insufficient, it is possible to determine whether the insufficient aerosol is due to a lack of aerosol raw material by observing the remaining amount of aerosol raw material inside the aerosol raw material storage container 2, thereby making it possible to determine whether the aerosol is insufficient. By determining whether this insufficiency is due to insufficient power of the power assembly 4 or damage to the aerosol generating device 3, a hint for the next operation can be presented to the user.

In some embodiments, the aerosol raw material storage bin 2 is made of an opaque material to prevent the aerosol raw material stored in the aerosol raw material storage bin 2 from being exposed to light and causing a physical/chemical reaction, thereby affecting its quality. .

In some embodiments, the aerosol generating device 3 is installed in the housing 1, and the aerosol generating device 3 directly or indirectly contacts the aerosol raw material in the aerosol raw material reservoir 2 to generate an aerosol from the aerosol raw material. Contact.

Furthermore, the aerosol generating device 3 is provided with a heat-generating assembly 31, and the heat-generating assembly 31 indirectly or directly contacts the aerosol raw material, emits heat energy, and causes the aerosol raw material to generate volatile substances. This forms an aerosol, which is then delivered out of the aerosol through the exhaust passage (e.g., first airway 22).

In some embodiments, the aerosol raw material reservoir 2 and the aerosol generating device 3 are secured to each other to form a hollow cylinder, or the aerosol raw material reservoir 2 and the aerosol generating device 3 are restrained in the same packing and together with the packing. Forms a hollow barrel.

3 and 5, the aerosol raw material storage container 2 includes an outer tube 24 and an inner tube, and at least a portion of the inner tube is a first airway 22 for delivering aerosol, and the inner tube is Located within the outer tube 24, a material storage area 241 for storing aerosol raw materials is provided in the space between the inner wall of the outer tube 24 and the outer wall of the inner tube, and a connection member is provided at the proximal end of the outer tube 24. A fixing groove 242 is provided for fixing (23), and the fabric area of the exterior (24) is provided with a combination part for assembly with the aerosol generating device (3), and the fabric of the first airway (22) is provided with an aerosol connected to the generating device (3), the proximal end connected to the connecting member (23); Furthermore, an oil sealing plug 25 may be further installed in the outer tube 24, and the material storage area 242 and the aerosol generating device 3 may be connected through the oil sealing plug 25 and/or the first airway 2223. ) and prevents the aerosol raw material from leaking from the fabric of the aerosol raw material reservoir (2) through the oil sealing plug (25).

In some other embodiments, the aerosol generating device 3 may be independent of the aerosol raw material reservoir 2, and the aerosol generating device 3 is connected to the aerosol raw material reservoir 2 by the first airway 22. For example, the distal end of the first airway 22 may be connected to the aerosol generating device 3, and the proximal end of the first airway 22 may be located within the aerosol raw material storage container 2.

In some embodiments, housing 1 may be used to accommodate consumable material and power assembly 4. The consumable material may be a hollow tube formed by fixing the aerosol raw material reservoir (2) and the aerosol generating device (3) to each other, the consumable material may be the aerosol raw material reservoir (2), and the consumable material may also be the aerosol generating device (3). In addition, consumable materials can also be hollowed out.

In some embodiments, the housing 1 includes a shell 11 and the aerosol raw material reservoir 2 and the aerosol generating device 3 are detachably connected to the shell 11 and, in some embodiments, a power source. Assembly 4 may also be detachably connected to shell 11.

In some embodiments, referring to Figure 1, the shell 11 is installed with an operation window 111 and an assembly window 112, an aerosol raw material storage bin 2, an aerosol generating device 3, and a power assembly 4. ), at least one of which may be mounted in the shell 11 through the assembly window 112, the operation window 111 is installed facing the assembly window 112, and the operation window 111 contains the consumable material (A) Corresponding to the position, the consumable material (A) installed in the shell 11 can be directly or indirectly contacted through the operation window 111, and force is applied to the consumable material (A) through the operation window 111. When applied, the consumable material (A) may move in a direction opposite to the assembly direction so that at least a portion of the consumable material (A) exits the assembly window 112 and at least a portion of the consumable material (A) is separated from the shell 11.

Referring to Figure 1, the side wall of the shell 11 connects the rear wall and the assembly window 112, and the shell 11 has an aerosol raw material storage container 2 and an aerosol between the rear wall, the side wall, and the assembly window 112. It has a receiving cavity 116 that houses the generating device 3 and the power assembly 4. In some embodiments, the assembly window 112 is unique, and the aerosol raw material reservoir 2, the aerosol generating device 3, and the power assembly 4 are all mounted to the shell 11 through the assembly window 112. do.

Referring to FIGS. 1, 2, and 3, at least a portion of the side wall of the shell 11 is an arc-shaped structure arched outward, so the maximum cross-sectional area of the receiving cavity 116 is larger than the area of the assembly window 112. , the volume of the receiving cavity 116 can be increased and the consumable material and power assembly 4 can be better secured than a design in which the maximum cross-sectional area of the receiving cavity 116 is equal to the area of the assembly window. The side walls of the arc-shaped structure have a less angular feel, providing a better grip.

In some embodiments, referring to FIGS. 1 and 2, the housing 1 further includes a cover 13, and the cover 13 covers the assembly window 112 to store the aerosol raw material storage bin 2 and the aerosol generating device. It is used to package at least one of (3) and the power assembly (4) within the shell (11).

In some embodiments, the cover 13 is slidably connected to the assembly window, for example, a sliding rail is installed on the shell 11, and the shell 11 is slidably coupled to the sliding rail to form a cover ( 13) forms a sliding cover structure. By sliding the cover 13, the position of the cover 13 can be changed to expose the consumed material.

In some embodiments, the cover 13 is rotatably connected to the assembly window, and rotating the cover 13 changes the position of the cover 13 to expose the spent material within the shell 11.

In some embodiments, referring to FIGS. 1 and 2, the cover 13 is detachably connected to the assembly window 112. For example, the cover 13 and the assembly window 112 may have a clip structure or a magnetic structure. They are detachably connected to each other through the suction structure, and after the cover 13 is removed from the assembly window 112, the consumable material A can be exposed, and then the consumable material A is exposed through the operation window 111. can be directly contacted or indirectly contacted so that the consumable material (A) can be separated from at least some of the shell (11), thereby causing the consumable material (A) to be separated from the shell (11) to remove the consumable material (A) makes it easier.

Optionally, opening the cover 13 simultaneously exposes the consumable material and the power assembly 4, so that when assembling the consumable material or removing the consumable material, the connection relationship between the consumable material and the power assembly 4 is fully visible. It is performed in a certain situation.

In some embodiments, the cover 13 may be absent, and the aerosol raw material reservoir 2, aerosol generator 3, and power assembly 4 may be more stably fixed to the shell 11 after passing through the assembly window. You can.

In some embodiments, referring to Figure 2, the electronic atomizing device 100 is generally shaped like a capiris Masaikai, which is not only aesthetically pleasing but also comfortable to hold.

In addition, the outline of the shell 11 may be pseudo-elliptical or oval-shaped, that is, the two ends of the shell 11 are small and the middle is large, and the outline of the shell 11 is smooth and arc-shaped to match the biological characteristics of the palm, The grip feels good. Specifically, the shell 11 has a long axis, the proximal end and the distal end of the shell 11 are located on the long axis, and among a plurality of cross sections perpendicular to the long axis, the cross section located in the middle of the shell 11 is the proximal end cross section and the distal end. larger than the distal cross-section, where the cross-section in the middle of the shell 11 gradually reduces to the proximal cross-section, and the cross-section in the middle of the shell 11 gradually reduces to the distal cross-section.

Furthermore, the radius of curvature of the proximal end contour of the shell 11 is smaller than the radius of curvature of the distal end contour of the shell 11. In some embodiments, the suction nozzle assembly 1213 is located at the proximal end of the shell 11, and the distal end of the shell 11 has a charging interface connected to a battery in the power assembly 4, and the distal end of the shell 11 The width is larger than the proximal end width, making it easier to bite the suction nozzle 122.

Furthermore, the outline of the assembly window 112 may also be pseudo-elliptical or oval-shaped. Specifically, the assembly window 112 has a long axis, the long axis of the assembly window 112 is parallel to the long axis of the shell 11, and the short axis of the assembly window 112 is parallel to the minor axis of the shell 11, In the chord perpendicular to and intersecting the long axis of the assembly window 112, the chord length located in the center of the assembly window 112 is greater than the proximal chord length and the distal chord length, where the chord length in the middle of the assembly window 112 is It is gradually reduced to the proximal chord length, and the cross section in the middle of the assembly window is gradually reduced to the distal chord length.

The external outline of the consumable material (A), the circular outline of the power assembly 4, etc. match the outline of the assembly window 112 and the outline of the receiving cavity 116, and the consumable material A is accommodated in the shell 11. After being mounted in the cavity 116, the wall of the receiving cavity 116 is brought into contact with the surface of the consumable material A, specifically the aerosol raw material reservoir 2, the aerosol generating device 3, and the power assembly 4. After being mounted in the receiving cavity 116 of the shell 11, the wall of the receiving cavity 116 is in contact with the surfaces of the aerosol raw material storage bin 2, the aerosol generating device 3, and the power assembly 4. Here, there is no clip connection at least between the consumable material A and the wall of the receiving cavity 116.

Furthermore, at least part of the outline of the assembly window 112 and at least part of the outline of the shell 11 are arcs that are parallel to each other, and in the two arc shapes of the arcs that are parallel to each other, each position is the same or has substantially the same distance.

This creates overall harmony. The cover 13 has an outline that matches the assembly window 112 to facilitate assembly.

In some embodiments, referring to FIG. 1, there is at least one operating window 111 and is installed on the back wall of the shell 11, and the operating window 111 includes an aerosol raw material storage container 2 and/or an aerosol generating device ( It is installed in a location corresponding to 3).

In some embodiments, referring to FIG. 1, the operating window 111 includes a through hole penetrating the back wall of the shell 11, so that a finger or tool passes through the operating window 111 and is installed within the shell 11. It can be in direct contact with the consumable material (A). Thereafter, a force opposite to the assembly direction is directly applied to the consumable material (A) in the shell 11, causing at least a portion of the consumable material (A) to move in a direction opposite to the assembly direction, thereby easily disassembling the shell 11. The consumable material (A) can be removed from, or the electrical connection between the consumable material (A) and the power assembly (4) can be disconnected by displacement.

In some embodiments, the operating window 111 includes an aperture and a flexible membrane, the aperture penetrates the back wall of the shell 11, the flexible membrane covers the inside or outside of the aperture, or the flexible membrane is connected to a wall hole of the aperture. and is located in the aperture, so that the flexible membrane can separate the inside and outside of the shell 11, and when a force is applied to the flexible membrane, at least a portion of the flexible membrane is deformed in the direction of the force to form a gap between the flexible membrane and the consumable material. An interaction force can be created, so that the consumable material can be pushed in the direction opposite to its assembly direction by a finger or a tool contacting the flexible membrane, and the flexible membrane can be exposed to an external sharp object through the operating window 111. By preventing direct contact with the consumable material installed in the shell 11, the surface of the consumable material is prevented from being scratched.

Furthermore, the flexible membrane has at least some elasticity, and when a force is applied to the flexible membrane, at least a portion of the flexible membrane is elastically deformed. When no force is applied to the flexible membrane, the flexible membrane may be in a flat state, in a tensioned state, or in a loose state.

In some embodiments, the operating window 111 includes a hole and a push rod installed in the hole, one end of the push rod corresponds to the consumable material, the other end of the push rod is located outside the shell 11, and the push rod is movable in the axial direction of the through hole, and by applying force to the push rod, the push rod is pushed to move in a direction opposite to the assembly direction of the consumable material, and further to move in a direction opposite to the assembly direction of the consumable material. Thus, at least a portion of the consumable material can be separated from the shell 11.

In some embodiments, referring to FIG. 1, the assembly window 112 is unique, and the power assembly 4, the aerosol raw material reservoir 2, the aerosol generating device 3, etc. all have the assembly window 112. It is assembled into the shell (11) through. To facilitate assembly and removal of the hollow barrel or consumable material (A), the assembly window 112 is opened on one side of the shell 11 with the largest upper surface area, resulting in a larger opening area of the assembly window 112. can do.

In some embodiments, referring to FIGS. 3 and 4, the aerosol raw material storage bin 2, the aerosol generating device 3, and the power assembly 4 are arranged in one row, and the aerosol raw material storage bin 2, the aerosol generating device ( The symmetry axis of 3) may overlap with the symmetry axis of the shell 11. In some embodiments, the suction nozzle assembly 12, aerosol raw material reservoir 2, aerosol generating device 3, and power assembly 4 are arranged in a row, and the four axes of symmetry may overlap.

In some embodiments, with reference to FIGS. 1 and 8, the spaces within the shell 11 for assembling the power assembly 4, the aerosol generating device 3, and the aerosol raw material reservoir 2 are interpenetrated, and the spaces There is no baffle plate separating the power assembly (4) and the hollow canister/consumable material (A) into two or more zones, respectively. There may be no gap between the section for assembling the power assembly 4 in the shell 11 and the section for assembling the hollow barrel/consumable material A. In another embodiment, the space within the shell 11 for assembling the power assembly 4, the aerosol generating device 3 and the aerosol raw material reservoir is separated from the power assembly 4 and the hollow barrel/consumable material A, respectively, by a diaphragm or the like. It can be separated into multiple spaces for assembling lights.

In some embodiments, the proximal end of the aerosol raw material reservoir 2 is in contact with the shell 11, and the distal end of the aerosol raw material reservoir 2 is in contact with the power assembly 4 through the aerosol generating device 3. Alternatively, the proximal end of the hollow tube is in contact with the shell (11) and the distal end is in contact with the power assembly (4).

Optionally, the contact force between the proximal end of the aerosol raw material reservoir 2 and the shell 11 may be an elastic contact force. Referring to FIGS. 3 and 4, a connection member 23 is provided at the proximal end of the aerosol raw material reservoir 2. It is fixed, and at least a portion of the connecting member 23 has elasticity so that the proximal end of the aerosol raw material storage container 2 is in elastic contact with the shell 11 through the connecting member 23, and the shell 11 is an aerosol raw material storage container. For (2), at least one elastic force is provided toward the fabric of the aerosol raw material storage container 2, the direction of the elastic force is a third direction, the assembly direction of the consumable material is the second direction, and the third direction is the second direction. perpendicular to the direction The connecting member 23 has elasticity, and at least some hardness is smaller than the hardness of the shell 11 and the raw material container, and by installing the connecting member 23 in the aerosol raw material storage container 2, the aerosol raw material storage container 2 In the process of assembling the shell 11, the connecting member 23 is contracted and yielded when pressed, allowing the aerosol raw material storage container 2 to be conveniently assembled into the shell 11, and the connecting member 23 is introduced. The difficulty of assembling the aerosol raw material storage bin (2) and the shell (11) can be reduced by changing the hard-to-hard assembly between the shell (11) to a soft-to-hard assembly that allows for shrinkage, and in addition, the aerosol raw material storage bin (2) ) and shell (11) from being damaged during assembly.

Optionally, the contact force between the aerosol generating device 3 and the power assembly 4 may be an elastic contact force, and with reference to FIGS. 3 and 4, the power assembly 4 is connected to the battery rod 41 and the elastic pad 44. ), the elastic pad 44 is fixed to the battery rod 41, and the elastic pad 44 is used to elastically contact the aerosol generating device 3. Accordingly, the power assembly 4 can provide for the aerosol generating device 3 at least one elastic force directed toward the proximal end of the aerosol generating device 3, wherein the direction of the elastic force is the fourth direction, and the consumable material A The assembly direction is the second direction, and the fourth direction is perpendicular to the second direction. Likewise, the elastic pad 44 has elasticity, and at least some hardness is smaller than the hardness of the aerosol generating device 3 and the power assembly 4, and the elastic pad 44 is introduced to form the aerosol generating device 3 and the power assembly 4. The difficulty of assembly can be reduced by changing the hard-to-hard assembly between the power assembly (4) into a soft-to-hard assembly that allows shrinkage, and in addition, the aerosol generating device (3) and the power assembly (4) are not damaged during the assembly process. prevent it from happening.

Optionally, referring to Figures 3 and 4, the contact force between the proximal end of the aerosol raw material reservoir 2 and the shell 11 may be elastic contact force, the direction of the elastic contact force is the third direction, and the aerosol generating device ( The contact force between 3) and the power assembly 4 may also be elastic contact force, and the direction of this elastic contact force is the fourth direction, and the third direction and the fourth direction are parallel and opposite directions, wherein the aerosol raw material reservoir 2 ) is fixedly connected to the aerosol generating device 3 to form an integrated structure or to form a hollow cylinder. Thereby, the integral structure or hollow tube can be fixed to the housing 1 by the action of two elastic contact forces, or can be fixed in the section between the proximal end of the shell 11 and the power assembly 4, and thus the integral structure or Implements a detachable connection of the hollow passing shell (11). Furthermore, the third and fourth directions are perpendicular to the assembly direction of the consumable material (A). Likewise, the elastic contact force between the aerosol raw material storage container (2) and the shell (11) and the elastic contact force between the aerosol generating device (3) and the power assembly (4), or the elastic contact force between the proximal end of the hollow container and the shell (11) , the elastic contact force between the fabric of the hollow container and the power assembly (4) is generated by the proximal end of the shell (11) and the power assembly (4) by the soft versus hard assembly method in which the aerosol raw material storage container (2) and the aerosol generating device (3) can yield shrinkage. By fixing it in (4), it lowers assembly difficulty, improves assembly efficiency, and protects assembled parts from damage.

Optionally, the power assembly 4 comprises a second electrode 46 and the aerosol generating device 3 comprises a first electrode 32 and the aerosol generating device comprises a receiving cavity 116 of the shell 11. When positioned within, the first electrode 32 and the second electrode 46 may contact each other such that the power assembly 4 is electrically connected to the aerosol generating device to provide the electrical energy necessary for aerosol generation. Additionally, when the aerosol generating device 3 is positioned within the receiving cavity 116 of the shell 11, the walls of the receiving cavity 116 are in contact with the surface of the consumable material A and/or the power assembly 4. , At least one of the first electrode 32 and the second electrode 46 is compressed to maintain electrical conduction between the two, and by elastic compression between the first electrode 32 and the second electrode 46. At least a portion of the consumable material (A) is brought into contact with the wall of the receiving cavity 116, so that the consumable material (A) is more stably stored in the receiving cavity (116) in a situation where there is no clip structure, self-suction structure, etc. 116), and through fixing in this manner, the consumable material (A) can be brought into closer contact with the inner wall of the receiving cavity 116, thereby reducing the volume of the receiving cavity 116 and reducing the size of the shell 11. It is advantageous for simplifying the structure.

In some embodiments, the power assembly 4 is detachably secured within the shell 11 by a clip structure, and the stability of the power assembly 4 being secured within the shell 11 is greater than the stability of the aerosol raw material reservoir 2. It is larger, or larger than the aerosol generating device 3, or greater than the stability of the hollow container formed by the aerosol raw material storage container 2 and the aerosol generating device 3 being fixed to each other fixed in the shell 11. Accordingly, when at least part of the consumable material moves in the direction in which it is separated from the shell 11 through the operation window 111, the power assembly 4 is also prevented from moving at least in the direction in which it is separated from the shell 11, so that the shell The power assembly (4) can be protected by preventing frequent movement of the power assembly (4) relative to (11).

More specifically, in some embodiments, a locking protrusion 412 is installed on the side of the battery load 41, and the locking protrusion 412 is mutually interfered with (or caught by) at least some areas of the shell 11. The protrusion 412 may be fixed to the shell 11 (by an interaction force between at least a portion of the shell 11). Referring to FIG. 7, the protrusion 412 is caught on the side of the battery load 41. is installed, and during one process of assembling the battery rod 41 to the shell 11, the catching protrusion 412 may be press-fitted with the side wall of the shell 11.

7 to 10, a locking portion 4121 is installed in the direction of the locking protrusion 412 toward the side wall of the shell 11, and is located on the side wall of the shell 11 corresponding to the locking portion 4121. A catching mixing part 113 is installed, and a stopper part 4121a is installed on one side of the catching part 4121 facing away from the back wall of the shell 11, and a stopper part 4121a is installed on one side of the catching mixing part facing the back wall of the shell 11. A stopper 1131 is installed, and when the locking part 4121 is located in the locking mixing part 113, or the locking mixing part 113 is located in the locking part 4121, the stopper 1131 is The battery load 41 can be prevented from retreating within the shell 11 by causing the stopper 1131 to stop the stopper 4121A while facing the stopper 4121A.

In the process of replacing the consumable material, the catching mixing unit 113 can prevent the consumable material A from being separated from the shell 11 by driving the power assembly 4 in the process of being separated from the shell 11. , Under the action of the locking mixing portion 113, in the process of moving the consumable material A away from the assembly direction, the power assembly 4 can be maintained at a predetermined position within the shell 11, so that the power assembly 4 ) can be prevented from moving the position due to movement of the consumable material (A) relative to the shell (11).

Referring to Figure 8, the engaging portion 4121 may be a protrusion, and correspondingly, the engaging portion 113 may be a blind groove that does not penetrate the side wall of the shell 11, or the engaging portion 113 may be a shell ( It may be a passing slot penetrating the side wall of 11). In some embodiments, the engaging portion may be a protrusion and, correspondingly, the engaging portion may be a depression into which the protrusion is inserted.

Referring to FIG. 9, in the process of assembling the battery rod 41 to the shell 11, the locking portion 4121 first contacts the non-locking mixing area on the side wall of the shell 11, and at this time, the locking portion 4121 ) is press-fitted with the side wall of the shell 11, and during the press-fit process, the friction between the battery rod 41 and the shell 11 prevents the battery rod 41 from penetrating deeper into or coming out of the shell 11. A certain stopping action is performed to prevent this. After the latching portion 4121 enters the latching mixing portion 113 and is caught in the latching mixing portion 113, the latching portion 4121 enters a relatively loose area (for example, a protrusion enters the concave portion) and is caught. The interference fit between the portion 4121 and the shell 11 may disappear, or the interference fit may still exist, where the shell 11 is mainly connected to the power assembly through the stop portion 1131 of the engaging portion 113. (4) is restricted within the shell (11). The stop 1131 primarily restrains the power assembly 4 in the longitudinal direction, preventing the power assembly 4 from moving longitudinally within the shell 11 against the assembly direction.

In some embodiments, protecting the battery rod 41 and the shell 11 and preventing the shell 11 or the battery rod 41 from rupturing during the process of assembling the battery rod 41 into the shell 11. To do this, at least a portion of the locking protrusion 412 or at least a portion of the battery rod 41 is installed to have elasticity, so that before the locking portion is stopped by the stopper 4121a, the locking portion and the side wall of the shell 11 During the sliding contact process, the side of the locking protrusion 412 or the battery rod 41 is elastically deformed to a certain extent, and not only protects the shell 11 and the battery through elastic deformation, but also protects the locking combination portion and the shell 11. By having a large frictional force between the side walls of the , the contact between the locking mixing part and the battery rod 41 can be made closer, and the assembly of the battery rod 41 can be effectively ensured.

In order to facilitate the assembly of the battery rod 41 and the shell 11, referring to FIGS. 7 and 9, one side of the engaging portion 4121 facing the rear wall of the shell 11 has a guide inclined surface (b). Provided, the guide inclined surface (b) mainly serves as a transition and guide, and the guide inclined surface (b) enters the engaging mixing portion 113 prior to the stopped portion 4121a on the engaging portion 4121. The locking portion 4121 gradually enters the locking mixing portion 113 according to the transition and guide of the guide inclined surface (b) and is finally caught with the locking blending portion 113.

In some embodiments, referring to FIGS. 8 to 10, a supported portion 4122 is further installed on the battery rod 41, and the supported portion 4122 is installed in a direction toward the rear wall of the shell 11, A support portion 114 is installed within the shell 11, and the support portion 114 is installed toward the supported portion 4122 to support the supported portion 4122, so that the battery load 41 is attached to the shell along its moving direction. (11) Prevents you from continuing to go deeper inside. Here, between the support portion 114 and the supported portion 4122, there may be surface contact, line contact, point contact, etc. to support the supported portion 4122.

In some embodiments, referring to Figures 7 and 9, the back wall of the shell 11 is arc-shaped, and the arc-shaped back wall not only brings the user a softer, more comfortable and new visual perception, but also gives the shell ( When holding 11), the outside of the back wall of the shell 11 is joined to the palm to provide a better grip and make it more comfortable to hold.

If the supported portion 4122 directly contacts the arc-shaped rear wall of the shell 11, the supported portion 4122 continues to move in the assembly direction along the arc-shaped rear wall due to the action of external force, causing the power assembly 4 to adhere to the shell 11. Excessive entry into (11) may cause damage to the shell (11) or power assembly (4). To prevent this problem, referring to FIGS. 7 and 9, the support portion 114 includes a support 1141 and a support surface, and the support 1141 is located on the back wall of the shell 1144 and protrudes with respect to the back wall. The support surface is installed on one side facing away from the rear wall of the shell 11 of the support 1141, and the support surface is configured to statically support the supported part 4122, so that the supported part 4122 is from the supporting surface to the supporting surface. prevent sliding.

Optionally, referring to FIGS. 7 and 9, the support surface of the supported portion 4122 and the support portion 114 may be surface contact, line contact, or point contact, and the support surface of the support portion 114 may be a plane, and the support surface of the support portion 114 may be flat. The plane is perpendicular to the traveling direction in which the power assembly 4 is assembled to the shell 11. Accordingly, when the supported portion 4122 contacts the supporting surface of the supporting portion 114 in the moving direction of the power assembly 4, the supporting force provided by the supporting surface is opposite to the moving direction when the power assembly 4 is assembled. and does not move along the support surface further behind the back wall of the shell 11 or downstream of the mounting position of the support portion 114, thereby protecting the shell 11 and the power assembly 4. The support part 114 can support the supported part 4122 more stably through a flat support surface, and can be applied to a heterogeneous structure in which the back wall of the shell 11 has an arc shape or other shape.

Optionally, the supporting surfaces of the supported portion 4122 and the supporting portion 114 are surface contact, line contact, or point contact, and the supporting surface of the supporting portion 114 is provided with a device to prevent the supported portion 4122 from slipping on the supporting surface. An anti-slip member is installed.

Optionally, the support surface of the support part 114 is in surface contact with the supported part 4122, and the contact surface is a corrugated surface or an installation surface.

In some embodiments, the back wall of the shell 11 is arc-shaped, and the support portion 114 includes a partial arc-shaped back wall of the shell 11 and a baffle plate fixed to the back wall, where the baffle plate is an arc-shaped back wall of the shell 11. Located downstream of the partially arc-shaped rear wall, it prevents the supported portion 4122 from moving downstream or further rearward of the rear wall of the shell 11 under the action of external force.

In some embodiments, the back wall of shell 11 is planar, and support 114 may be located on the back wall of shell 11 and may be planar parallel to the back wall of shell 11.

In some embodiments, referring to FIGS. 7, 9, and 10, the battery rod 41 has a storage cavity 414 that stores a battery 42, and the shell 11 of the storage cavity 414 There is an opening on one side facing the back wall, the battery is assembled into the storage cavity 414 through the opening, a cross section 4123 of the opening faces at least a part of the back wall of the shell 11, and the supported portion 4122 is The support portion 114 includes at least a portion of the cross section 4123 of the opening, i.e., the support portion 114 supports a portion of the cross section 4123 of the opening. If at least part of the cross section 4123 is used as the supported portion 4122, the gap between the battery rod 41 and the side wall of the shell 11 can be reduced, and the support portion 114 is specially manufactured on the battery rod 41. Because the process is omitted, production efficiency can be improved and costs can be reduced.

In some embodiments, when the engaging portion 4121 engages with the engaging combining portion 113, or when the stopping portion 1131 stops the stopped portion 4121a, the supporting portion 114 contacts the supported portion 4122. Furthermore, referring to FIG. 9 , when the support portion 114 contacts the supported portion 4122, the stopper portion 4121a may contact the stopper portion 1131 of the engaging combination portion 113. Furthermore, the support 1141 has elasticity and makes elastic contact with the supported portion 4122, allowing the stopped portion 4121a to contact the stop portion 1131 so that the battery load 41 is stably fixed within the shell 11. This can be guaranteed.

In some embodiments, referring to FIGS. 7 to 9, a guide groove 4124 is installed in the battery rod 41, a guide strip 115 is installed in the shell 11, and the guide strip 115 is slidably connected to the guide groove 4124. The guide strip 115 and guide groove 4124 allow the battery rod 41 to enter the shell 11 according to the sliding direction between the guide groove 4124 and the guide strip 115, and are located during the assembly process. By preventing misalignment, assembly errors can be reduced, thereby preventing the shell 11 and the battery rod 41 from being deformed or damaged during the assembly process. In addition, since the guide strip 115 is installed on the shell 11 and the guide strip 115 is fixed to the shell 11, after the guide strip 115 enters the guide groove 4124, the power assembly ( 4) can move only along the direction of extension of the guide strip 115 and enter the assembly space of the power assembly 4 within the shell 11, and may cross the boundary into the assembly space of the consumable material A or enter the aerosol generating device. It cannot enter the assembly space of (3) or the assembly space of the aerosol raw material storage container (2), etc., and after the consumable material (A) is separated from the shell (11), the power assembly (4) is moved to the proximal end of the shell (11) or the like. Since it cannot be moved to the fabric and only maintains its original position, there is no need to adjust the position within the shell 11 of the power assembly 4 when assembling a new consumable material A, thereby increasing the efficiency of assembling the consumable material A. It is advantageous for heightening.

Also, referring to Figure 9, the starting height of the guide groove 4124 on the battery rod 41 is smaller than the starting height of the catching protrusion 412 on the battery rod 41, so that the guide strip on the battery rod 41 4124 comes into contact with the shell 11 before the catching protrusion 412. Accordingly, before the catching protrusion 412 is press-fitted with the side wall of the shell 11, the power assembly 4 enters the shell 11 in a certain direction under the guidance of the guide groove 4124 and the guide strip 4124. Let's begin.

The power assembly (4) is mainly electrically connected to the heat generating assembly (31) in the aerosol generating device (3) to provide the electrical energy necessary for the heat generating assembly (31) to generate heat; As shown in FIGS. 1 to 4, the power assembly 4 is electrically connected to the aerosol generating device 3 and is electrically connected to the heat generating assembly 31, so that the heat generating device 31 volatilizes the aerosol raw material. It provides the electrical energy needed to generate the heat needed to volatilize water. In some embodiments, the battery in the power assembly 4 may be a disposable power source, a rechargeable battery, or a directly connected power source wired to an external power supply device. In some embodiments, the power assembly 4 further includes an electrical control board and a second electrode, and in some embodiments, the electrical control board is integrated with a control circuit and a sensor, the sensor detecting whether there is a suction action. When the sensor detects that there is a suction motion, the control circuit can control the power source to output current, voltage, or power through the second electrode. The heating assembly 31 is electrically connected to the second electrode, and the second electrode outputs power to the heating assembly 31 to cause the heating assembly 31 to generate heat.

3, 4, 6, and 7, the power assembly 4 includes a battery load 41, a battery 42, a second electrode 46, an airflow sensor 43, and an elastic pad 44. may include.

In some embodiments, battery rod 41 has a storage cavity for housing a battery, an airflow sensor, and some second electrodes. 1 and 4, when the power assembly 4 is mounted within the housing 1, the opening of the storage cavity of the battery rod 41 faces the back wall of the shell 11, and the closed wall of the storage cavity is Since it faces the assembly window 112, when the cover 13 is opened, the items stored in the storage cavity (eg, batteries, airflow sensors, etc.) are not exposed but are hidden.

In some embodiments, referring to FIGS. 1, 4, and 6, a light sheet 47 is installed on the outer surface of the closed wall of the storage cavity, and the light sheet 47 is electrically connected to the battery 42. , the position corresponding to the light sheet 47 of the cover 13 transmits light, and when the light sheet 47 is electrically conductive, at least part of the light is revealed through the cover 13 to provide an indication signal or electronic It can be used as a status display signal of the atomizing device 100. The light sheet 47 is installed on the battery rod 41, and the light sheet 47 and the housing 1 are made independent of each other, so that unnecessary interference with the light sheet 47 does not occur when disassembling the housing 1. .

In some embodiments, a main magnetic sheet is attached to the outer surface of the closed wall of the storage cavity, and an auxiliary magnetic sheet is installed at a position corresponding to the main magnetic sheet of the cover 13, and the cover 13 and the shell 11 ) are combined with each other to cover the assembly window, there is a magnetic attraction force between the main and coja magnetic sheets to prevent the cover 13 from being separated from the shell 11.

In some embodiments, referring to FIGS. 3, 4, 6, and 7, a support member 411 is provided at the proximal end of the battery rod 41, and the support member 411 supports the elastic pad 44. Thus, the elastic pad 44 and the aerosol generating device 3 are elastically connected to prevent the shock applied to the power assembly 4 when the consumable material A is mounted in the shell 11 through the elastic pad 44. It is possible to cushion the vibration of the power assembly (4) and reduce the vibration of the power assembly (4) when installing and removing the consumable material (A).

In some embodiments, referring to FIGS. 3, 4, 6, and 7, the support member 411 is further provided with an inlet hole 45 connected to external air, and the aerosol generating device 32 is provided with an air inlet hole 45. A hole is installed, the air entry hole is connected to the first airway 22, and after the support member 411 is in contact with the aerosol generating device 32, the inlet hole 45 is connected to the air entry hole to externally Air sequentially enters the first airway 22 through the intake hole 45 and the air entry hole.

In some embodiments, referring to FIGS. 4, 6, and 7, the support member 411 includes a groove 4111, the groove 4111 includes a groove bottom and a groove wall surrounding the groove bottom, and the groove wall is installed toward the aerosol generating device 3, and the inlet hole 45 may be located on the groove wall of the groove 4111, or may be located on the groove bottom of the groove 4111. The groove 4111 is installed to correspond to the air entry hole and collects the liquid entering from the air entry hole. The liquid may be condensate flowing back from the air entry hole, or the stored liquid leaking from the aerosol raw material reservoir 2. It may be an aerosol raw material.

In some embodiments, referring to FIGS. 4, 6, and 7, the support member 411 further includes a plurality of pipes (a), where the pipes (a) are connected to the receiving cavity and groove 4111 and the pipe The proximal end of (a) protrudes from the groove bottom of the groove 4111, forming a step between the proximal end of the pipe (a) and the groove bottom of the groove 4111, and protrudes from the groove bottom of the groove 4111. The section between the pipes (a) includes a liquid storage section, and the liquid storage section can be used to store liquid flowing into the groove.

In some embodiments, referring to FIGS. 4, 6, and 7, the pipe a has at least three, where at least two pipes a have a positive second electrode 46 and a negative second electrode 46. Two electrodes 46 are intended to pass through, where one pipe a is for communicating with the airflow sensor 43.

The elastic pad is in a sealed connection with the aerosol generating device 3 so that when the power assembly 4 is joined to the aerosol generating device 3, the liquid entering from the air entry hole leaks between the support member and the aerosol generating device 3. In addition, the elastic pad provides elastic force toward the aerosol material storage bin (2) for the aerosol generating device (3) to ensure that the consumable material is better seated within the housing (1).

In some embodiments, referring to FIGS. 4, 6, and 7, the elastic pad 44 includes an annular body 441, and the annular body 441 is a groove wall of the groove 4111 of the support member 411. It extends and protrudes from and contacts the aerosol generating device 3 instead of the groove wall of the groove 4111, and since the annular body 441 has elasticity, the contact between the annular body 441 and the aerosol generating device 3 is an elastic contact. and is in an elastic compression state after the annular body 441 and the aerosol generating device 3 are in contact, and is compressed when the annular body 441 is in an elastic compression state and when the annular boss 231 is in an elastic compression state. The direction is opposite. The aerosol raw material storage container 2 and the aerosol generating device 3 can be fixed within the housing 1 by the action of these two elastic forces.

In some embodiments, the annular body may be installed surrounding the outer wall of the groove, and may also be installed on the top of the groove wall of the groove, and then the top of the annular body is contacted with the aerosol generating device 3; In some embodiments, a portion of the annulus is wrapped outside a portion of the fabric of the aerosol-generating device 3, and another portion of the annulus extends protruding inward and contacts the aerosol-generating device 3 upwardly.

In some embodiments, referring to FIGS. 4, 6, and 7, the entrance hole 45 is located on the groove wall of the groove 4111, and the annular body 441 is installed surrounding the groove wall, and the annular body 441 A notch 442 is installed at a position corresponding to the entrance hole 45 to prevent outside air from being blocked by the elastic pad 44 in the process of entering the groove 4111 through the entrance hole 45. The hole 45 or the notch 442 is higher than the liquid storage section to prevent the liquid in the liquid storage section from coming out of the inlet hole 45 or the notch 442.

In some embodiments, referring to FIGS. 4, 6, and 7, the elastic pad 44 is located in the groove 4111, and the annular body 441 is installed to be in close contact with the inner surface of the groove wall of the groove 4111. , the elastic pad 44 may further include a liquid storage bottom and a tubular ridge 443, the tubular ridge 443 corresponding one-to-one with the pipe (a) to allow the proximal end of the pipe (a) to pass through. is installed, the proximal end of the tubular ridge 443 is open so that the second electrode 46 and the first electrode 32 of the aerosol generating device 3 can be easily contacted, and the proximal end of the pipe (a) is tubular. It may not protrude from the ridge 443, may be parallel to the proximal end of the tubular ridge 443, or may also protrude from the tubular ridge 443. The liquid storage bottom connects the annular body 441 and the tubular ridge 443 to form a storage space between the annular body 441, the liquid storage bottom, and the tubular ridge 443, and the storage space is connected to the air entry hole. It includes a liquid storage section for storing liquid flowing in from. Therefore, instead of cleaning the liquid directly from the battery rod 41, the liquid can be cleaned by removing the elastic pad 4, making cleaning simpler and operation more convenient.

The air flow sensor 43 is installed on one side of the support frame facing the storage cavity, the air flow sensor 43 is connected to one of the pipes (a), and when a suction action occurs in the suction nozzle 122, the air flow sensor 43 The internal airflow flows into the air entry hole through the corresponding pipe (a), causing negative pressure to be formed on both sides of the airflow sensor 43, and when the negative pressure exceeds a certain threshold, the battery responds to the corresponding detection result. 2 Outputs voltage or current through electrodes. The elastic pad 44 can sealably connect the groove 4111 and the aerosol generating device 3, thereby ensuring high sensitivity of the airflow sensor 43.

An embodiment of the present application provides a method of mounting an electronic atomization device 100. The method is applicable to the electronic atomization device 100, and the method includes the following steps.

Step 1: Directly or indirectly contact the existing consumable material in the housing (1) through the operation window (111) opened in the housing (1).

The method of directly or indirectly contacting existing consumable material within the housing 1 includes the following steps.

S1: Change the shape of the housing (1) to expose the consumable material. The shape of the housing 1 can be changed by disassembling the cover 13 of the housing 1 and removing the cover 13 to expose the assembly window of the housing 1. The shape of the housing (1) can be changed by sliding the cover (13) of the housing (1) so that the cover (13) is separated from the assembly window of the housing (1). The shape of the housing (1) can be changed by rotating the cover (13) of the housing (1) so that the cover (13) is separated from the assembly window of the housing (1).

After the assembly window is exposed, the consumable materials are exposed. After the assembly window is exposed, force is applied to the consumable material through the operation window 111 to move the consumable material in a direction where it is separated from the shell 11.

S2: If the operating window 111 is open and can penetrate the housing 1, use your fingers or a tool to directly penetrate the operating window 111 and directly contact the existing consumable material in the housing 1. Afterwards, the existing consumable material may be pushed out by directly applying force in the first direction to the existing consumable material.

Or, S2: If the operation window 111 is covered and the inside and outside of the housing 1 can be isolated, use your finger or a tool to compress or push at least a part of the operation window 111 to remove the operation window 111. ) causes a compressive force or repulsion force to occur between at least a portion of the area and the existing consumable material, and the compressive force or repulsion force can be used to push the existing consumable material in a direction away from the shell 11.

In some embodiments, step 2 includes applying a force in a first direction to the existing consumable material by penetrating the operating window 111 or compressing at least a portion of the operating window 111, and then compressing the existing consumable material in the first direction. The consumable material is pushed to separate at least a portion of the existing consumable material from the housing (1), wherein the consumable material is an aerosol raw material reservoir (2) detachably connected to the housing (1), or the consumable material is an aerosol raw material reservoir (2) and A hollow cylinder formed by the aerosol generating device (3), which hollow cylinder is removably connected to the housing (1), or the consumable material is an aerosol generating device (3), which is removably connected to the housing (1). . Accordingly, the aerosol raw material storage container (2) or the aerosol generating device (3) can be easily removed.

In some embodiments, step 2 may also include applying a force in a first direction to the consumable material by penetrating the operating window 111 or compressing at least a portion of the operating window 111, and then compressing the existing material in a third direction. The consumable material is pushed so that the first electrode and the second electrode are crossed, where the consumable material is the aerosol generating device (3), or the consumable material is a hollow container formed by the aerosol raw material reservoir (2) and the aerosol generating device (3). , the hollow cylinder is at least partially separate from the power assembly (4), or the consumable material is detachably connected to the housing (1) as an aerosol generating device (3). Accordingly, when the electronic atomization device 100 is in a standby state or is temporarily not used, the electrical connection between the first electrode and the second electrode can be blocked to reduce self-discharge of the battery. In some embodiments, the third step is such that a force passes through the assembly window from a second direction and forces the new consumable material into the housing (1) such that at least a portion of the new consumable material is secured to the housing (1); Here, the second direction and the first direction are parallel and opposite directions, and the new consumable material may have the same shape as the existing consumable material. The cover 13 can then be closed to reliably confine new spent material within the housing 1.

In some embodiments, the third step also causes a force to penetrate the assembly window and push the consumable material from a second direction, bringing the first electrode and the second electrode into contact, wherein the second direction and the first direction are parallel. It's the opposite direction. In some embodiments, the housing 1 is provided with a reverse opening facing the operating window 111, and is capable of directly or indirectly contacting the consumable material through the reverse opening, so that the consumable material is consumed from the second direction through the reverse opening. The material can be pushed to bring the first electrode and the second electrode into contact. Using the reverse opening, it is possible to implement electrical connection between the first electrode and the second electrode while the housing 1 is open.

In some embodiments, the third step also utilizes a reverse opening defined in the housing 1, wherein a force in a second direction is applied to the consumable material by passing through the reverse opening or compressing at least a portion of the reverse opening; After pushing the consumable material, the first electrode and the second electrode are electrically connected. The reverse opening and the operating window 111 are installed on opposite sides of the housing 1, the reverse opening may have the same shape or structure as the operating window 111, and the housing 1 can be disassembled using the reverse opening. The first electrode and the second electrode can be electrically connected without doing so.

Step 4: Operate the electronic atomization device 100 to generate aerosol.

The electronic atomization device 100 of the embodiment of the present application is equipped with an assembly window, which serves as an assembly window and a replacement window for consumable materials of the electronic atomization device 100, thereby simplifying the structure of the electronic atomization device 100 and providing electronic atomization. It allows the device 100 to have better integration, and the consumable material and power assembly 4 can be assembled into the shell 11 through the corresponding assembly window, which simplifies the assembly process of the electronic atomizer. In addition, the cover 13 movably covers the assembly window, and by moving the cover 13, the assembly window is exposed to visualize the connection relationship between the consumable material and the power assembly 4, so that the new consumable material is assembled in place. This may lead to poor contact between the consumable material and the power assembly (4) and prevent it from affecting the user's normal use.

The electronic atomizing device 100 of the embodiment of the present application is provided with an operation window 111 on the shell 11 or a movable frame, so that consumable materials in the shell 11 or the movable frame are disposed of through the operation window 111. After contacting directly or indirectly, a force is applied to the consumable material in a direction opposite to the assembly direction of the consumable material, so that at least a portion of the consumable material can be separated from the housing 1 or the movable frame, thereby conveniently removing the consumable material. removing or, when the electronic atomizing device 100 is temporarily not in use, causing at least a portion of the consumable material to separate from the housing 1 or the movable frame, thereby breaking the electrical connection between the second electrode and the first electrode, The standby time of the electronic atomization device 100 can be extended by reducing self-discharge.

The electronic atomizing device 100 described in the embodiments of the present application has a capiris Masaikai shape, which is not only aesthetic, but also has a structural shape that matches the biological characteristics of the palm, providing a good grip and improving the user's grip. Enhance the experience.

The electronic atomizing device 100 described in the embodiment of the present application has an elastic pad installed on the power assembly 4, and the elastic pad reduces vibration of the power assembly 4 when mounting and removing consumable materials. In addition, it provides an upward elastic contact force to the consumable material, so that the consumable material can be stably mounted on the housing 1 or the movable frame. In addition, the elastic pad ensures soft contact between the power assembly (4) and the aerosol generating device (3), and compared to hard contact, the soft contact reduces wear of the aerosol generating device (3) when removing or installing the aerosol generating device (3). can be reduced.

The mounting method of the electronic atomizing device 100 described in the embodiment of the present application applies force to the consumable material by penetrating the operation window 111 or pushing at least a portion of the operation window 111 with a finger or a tool, By ensuring that at least a portion of the consumable material can be simply and quickly separated from the housing (1) or the movable frame, it facilitates removal of the consumable material, replacement of the consumable material, or disconnection of the electrical connection between the consumable material and the power assembly (4). , prevents self-discharge of the battery in the power assembly (4) and extends the standby time of the battery.

It should be noted that the description of the present application and its drawings illustrate preferred embodiments of the present application, but are not limited to the embodiments described herein, and furthermore, for those skilled in the art, the above description Improvements or conversions may be made, and all such improvements and conversions will fall within the scope of protection of the appended patent claims of this application.

In the drawing,
1. Housing; 11. Shell; 111. Control window; 112. Assembly window; 113. Jamming mixing section; 114. Support part; 1141. Support; 115. Guide strip; 12. Suction nozzle assembly; 121. Second prayer; 122. Suction nozzle; 13. Cover;
2. Aerosol raw material storage bin; 22. First Prayer; 23. No connection; 231. Annular boss; 232. Third prayer; 233. Body; 24. Outer tube; 241. Raw material storage section; 242. Fixed groove; 25. Oil sealing plug;
3. Aerosol generating device; 31. Heat generation assembly; 32. First electrode;
4. Power assembly; 41. Battery load; 411. Absence of support; 4111. Home; a. pipe; 412. Hanging protrusion; 4121. Hang part; b. guide slope; 4122. Sebum support; 4123. Cross section; 4124. Guide Home; 42. Battery; 43. Air flow sensor; 44. Elastic pad; 441. Ring body; 442. Notch; 443. Tubular ridge; 45. Dressing Hall; 46. Second electrode; 47. Light sheet;
A. Consumable materials.

Claims (23)

In the electronic atomization device,
shell;
An aerosol raw material storage bin for storing aerosol raw materials;
An aerosol generating device for generating an aerosol using the aerosol raw material;
a power assembly electrically connected to the aerosol generating device to provide electrical energy necessary for aerosol generation;
- The shell is provided with an assembly window;
the assembly window is for providing an opening for assembling the aerosol raw material reservoir, the aerosol generating device, and the power assembly into the shell;
The assembly window is also a replacement window for consumable materials, for replacing consumable materials through the assembly window, wherein the consumable material is the aerosol raw material reservoir or the whole formed by the aerosol raw material reservoir and the aerosol generating device;
An electronic atomizing device comprising a cover for movably covering the assembly window. According to paragraph 1,
At least one operating window is installed on one side of the shell facing the assembly window, and can directly or indirectly contact the consumable material installed in the housing through the operating window, and contact the consumable material through the operating window. Electronic atomization device, characterized in that when force is applied, the consumable material moves in a direction opposite to the assembly direction. According to paragraph 2,
An electronic atomizing device, wherein at least a portion of the operating window transmits light. According to paragraph 2,
The operating window is an electronic atomizing device characterized in that it includes a hole penetrating the back wall of the shell. According to paragraph 4,
The operating window further includes a flexible membrane, the through hole penetrates the back wall of the shell, and the flexible membrane covers the outside or inside of the through hole to isolate the inside and outside of the shell. . According to paragraph 1,
The side wall of the shell is connected to the rear wall and the assembly window, and the side wall is an arc-shaped structure in which at least a portion of the shell arches outward. According to clause 6,
An electronic atomizing device, characterized in that the outline of at least one of the shell or the assembly window is pseudo-elliptical or oval-shaped. In clause 7,
The shell and the assembly window are both similarly oval or elliptical, and at least a partial outline of the assembly window and at least a partial outline of the shell are arcs parallel to each other. According to paragraph 1,
An electronic atomizing device, wherein at least a portion of the consumable material within the shell is in elastic contact with a side wall of the shell. According to clause 9,
The consumable material includes the aerosol raw material reservoir, a connecting member is fixed to the aerosol raw material reservoir, at least a portion of the connecting member has elasticity, and the aerosol raw material reservoir is in elastic contact with the shell by the connecting member. An electronic atomizing device characterized by being According to clause 10,
A suction nozzle assembly is installed at the proximal end of the shell, an annular boss is installed at the proximal end of the connecting member, at least a portion of the annular boss has elasticity, and the annular boss is located outside the third airway in the suction nozzle assembly. An electronic atomizing device characterized in that it is elastically contacted to the rim to form a sealed connection with the suction nozzle assembly. According to paragraph 1,
The power assembly includes an elastic pad, and the power assembly is in elastic contact with the aerosol generating device by the elastic pad. According to paragraph 1,
The power assembly includes a battery load, a locking portion is installed on the battery rod, a locking mixing portion is installed in the shell corresponding to the locking portion, a stopper is installed on the locking blending portion, and the locking portion is provided with a stopper, and the stopper stops the stopper to prevent the power assembly from moving longitudinally within the shell along the assembly direction of the power assembly. According to clause 13,
At least a portion of at least one of the battery rod side and the locking portion has elasticity, and when the battery rod is assembled and entered into the shell, the battery load side and the locking portion move toward each other in an interference fit. Electronic atomizer. According to clause 13,
The battery rod is further provided with a supported portion, and a support portion is installed within the shell, and the support portion supports the supported portion to prevent the power assembly from continuing to move along the assembly direction. Atomizing device. According to clause 15,
The back wall of the shell is arc-shaped, the support includes a support and a support surface, the support is located on the back wall of the shell, the support surface is installed on a side of the support opposite to the back wall of the shell, and the support An electronic atomizing device, characterized in that the surface is configured to statically support the support. According to clause 16,
The support surface is flat, and the support surface is perpendicular to the direction in which the power assembly is assembled to the shell. According to clause 15,
The stopper is installed above the support part, and when the supported part is supported by the support part, the supported part is stopped by the stopper. According to clause 15,
The battery rod has a storage cavity for storing a battery, the storage cavity has an opening on one side facing the back wall of the shell, the battery is assembled into the storage cavity through the opening, and the supported portion has the An electronic atomizing device comprising at least a portion of the cross section of the opening. According to clause 13,
A guide groove is installed on the battery rod, and a guide strip is installed on the shell, and the guide strip is located in the guide groove so that the power assembly moves in parallel within the shell in an assembly direction perpendicular to the power assembly. An electronic atomization device that prevents According to clause 20,
The guide strip is slidably connected to the guide groove, and the assembly direction of the power assembly is limited by the relative sliding direction of the guide groove and the guide strip. In the electronic atomization device,
A shell with a defined receiving cavity;
An aerosol generating device comprising a first electrode;
a power assembly including a second electrode, electrically connected to the aerosol generating device through contact between the second electrode and the first electrode, and providing electrical energy required for aerosol generation;
the shell has an assembly window to provide an opening for mounting the aerosol generating device and power assembly to the receiving cavity; The wall of the receiving cavity is in contact with a surface of the aerosol generating device and/or the power assembly, causing at least one of the first electrode and the second electrode to be compressed to maintain electrical conduction between the two. Atomizing device. According to clause 22,
The shell has a long axis, the receiving cavity extends along the long axis, and in a plurality of cross sections perpendicular to the long axis, a cross-sectional area located in the middle of the shell of the receiving cavity is larger than a cross-sectional area proximate to the proximal end of the cell. Or, alternatively, an electronic atomization device characterized in that the cross-sectional area located in the middle of the shell of the receiving cavity is larger than the cross-sectional area adjacent to the cell fabric.