CN116807073A - Recyclable electronic atomization device and recycling method - Google Patents

Abstract

The invention relates to a recyclable electronic atomization device and a recycling method thereof, wherein the recyclable electronic atomization device comprises a shell, a suction nozzle and a bottom cover, a liquid storage pipe, an atomization core, a control component and a battery are accommodated in the shell, and the atomization core is at least partially inserted into the liquid storage pipe; the control component is positioned between the liquid storage pipe and the battery and is detachably connected with the liquid storage pipe; the battery is detachably connected with the control assembly; the suction nozzle is detachably connected with the first end of the shell; the bottom cover is detachably arranged in the second end of the shell, so that when the bottom cover receives a thrust force in the direction of the suction nozzle to be larger than a preset value, the bottom cover drives the suction nozzle and the part positioned in the shell to be pushed out from the first end of the shell. The invention has the advantages of convenient disassembly and convenient classification and recovery.

Description

Recyclable electronic atomization device and recycling method

Technical Field

The invention relates to the technical field of electronic atomization, in particular to a recyclable electronic atomization device and a recycling method.

Background

The electronic atomizing device heats the atomized liquid through the atomizing assembly to form aerosol, and a user sucks the aerosol, so that the aerosol is pumped out of the electronic heating device. The atomized liquid can be essence, spice or liquid medicine. The current electron atomizing device generally includes casing, atomizing core, control assembly, battery and bottom, and atomizing core, control assembly and battery all are located the casing, and the wire and the control assembly of atomizing core link to each other through the welding to realize the electricity and be connected, and the battery links to each other with the control assembly welding, in order to supply power for the atomizing assembly, and the bottom lid is established in the bottom outside of casing.

When the user uses the atomized liquid, the whole electronic atomization device is discarded, and the discarded battery can affect the environment. In order to solve the above problems, a person skilled in the art changes the connection mode between the battery and the control assembly into an abutting mode, so that after the atomized liquid in the electronic atomization device is completely consumed, the battery can be taken out from the shell after the bottom cover is scratched out from the shell before the electronic atomization device is discarded, and the battery can be recovered. However, such a structure is inconvenient for taking out the components such as the control assembly for sorting and recycling. Therefore, how to develop an electronic atomization device that facilitates classifying and recycling parts has become a technical problem to be solved in the art.

Disclosure of Invention

The invention aims to provide a recyclable electronic atomization device and a recycling method thereof, wherein the recyclable electronic atomization device is convenient for classifying and recycling parts.

In a first aspect, the present invention provides a solution to the above problem, by constructing a recyclable electronic atomization device, including a housing, a suction nozzle, and a bottom cover, where a liquid storage tube, an atomization core, a control assembly, and a battery are housed in the housing, and the liquid storage tube is used for storing atomized liquid; the atomizing core is at least partially inserted into the liquid storage pipe and is used for atomizing the atomized liquid; the control component is positioned between the liquid storage pipe and the battery and is detachably connected with the liquid storage pipe; the battery is detachably connected with the control assembly; the suction nozzle is detachably connected with the first end of the shell; the bottom cover is detachably arranged in the second end of the shell, so that when the thrust force of the bottom cover in the direction of the suction nozzle is greater than a preset value, the bottom cover drives the suction nozzle and the part positioned in the shell to be pushed out from the first end of the shell.

Preferably, an air inlet hole and a first connecting groove are formed in one end, facing away from the suction nozzle, of the liquid storage pipe, and the notch of the first connecting groove faces the control assembly; the atomization core comprises a porous liquid guide piece, an electric heating piece and a wire, wherein the porous liquid guide piece is positioned in the liquid storage pipe so as to adsorb the atomized liquid; the electric heating element is in contact with the porous liquid guide element and is used for atomizing the atomized liquid; the first end of the wire is connected with the electric heating element, and the second end of the wire passes through the air inlet hole and is inserted into the first connecting groove; the control assembly comprises a circuit board and a conductive column, wherein the conductive column is fixed on the circuit board, and at least part of the conductive column is inserted in the first connecting groove and clamps the lead together with the inner wall of the first connecting groove.

Preferably, the liquid storage tube comprises a sleeve part and an end wall part, the porous liquid guide piece and the electric heating piece are both positioned in the sleeve part, the end wall part is covered and arranged at the end face of one end of the sleeve part facing the battery, the end wall part is provided with the air inlet hole, the end wall part extends towards the direction where the battery is positioned to form a connecting column part, and the end face of the connecting column part is provided with the first connecting groove.

Preferably, the recyclable electronic atomization device further comprises a battery sleeve, wherein the battery sleeve is positioned in the shell and is coaxially arranged with the liquid storage tube, the end wall part extends towards the direction of the battery sleeve to form an extension part, and the extension part is detachably connected with the battery sleeve; the battery is movably inserted in the battery sleeve.

Preferably, the extension part comprises a connecting ring part and a buckling convex part, the connecting ring part is formed by extending the end wall part towards the direction of the battery sleeve, and the buckling convex part is positioned at the outer peripheral surface of the connecting ring part;

the battery sleeve comprises a pipe body and a blocking wall, the blocking wall is positioned in the pipe body and divides the inner space of the pipe body into a containing cavity and a second connecting groove, the battery is positioned in the containing cavity, the groove wall of the second connecting groove is provided with a buckling hole, the connecting ring is inserted into the second connecting groove, and the buckling convex part is connected with the buckling hole in a buckling mode.

Preferably, the control assembly is located in the accommodating cavity, and the conductive column penetrates through the barrier wall and extends into the second connecting groove.

Preferably, the circuit board is connected with a conductive tube, the extending direction of the conductive tube is the same as that of the battery, the electrode of the battery is at least partially inserted into the conductive tube, and the electrode of the battery is detachably connected with the conductive tube.

Preferably, the opening of the conductive tube facing the battery is provided with a notch.

Preferably, the control assembly further comprises an air flow sensor fixed to a side of the circuit board facing the battery;

the recoverable electronic atomization device further comprises a sealing seat, wherein the sealing seat is located between the circuit board and the battery, the sealing seat is provided with a containing groove, and the airflow sensor is located in the containing groove.

In a second aspect, the present invention also discloses a recycling method of the recyclable electronic atomizing device according to any one of the first aspects, comprising the steps of:

firstly, fixing the shell at a preset position; secondly, applying a pushing force towards the suction nozzle on the bottom cover, so that the suction nozzle and the parts in the shell are pushed out from the first end of the shell; thirdly, the liquid storage tube and the battery are pulled out from the control assembly and are respectively arranged on the corresponding target storage devices.

The beneficial effects of the invention are as follows: the control component is positioned between the liquid storage pipe and the battery and is detachably connected with the liquid storage pipe; the battery is detachably connected with the control assembly; the suction nozzle is detachably connected with the first end of the shell; the bottom cover is detachably arranged in the second end of the shell, so that when the thrust force of the bottom cover in the direction of the suction nozzle is greater than a preset value, the bottom cover drives the suction nozzle and the part positioned in the shell to be pushed out from the first end of the shell. Therefore, after the atomized liquid in the electronic atomization device is completely consumed, the bottom cover is applied with a thrust force towards the direction of the suction nozzle, so that the suction nozzle and parts positioned in the shell are pushed out from the first end of the shell, then the liquid storage tube and the battery are pulled out from the control assembly and are respectively placed on the corresponding target storage device, and the classified recovery can be realized.

Drawings

The invention is described below with reference to the accompanying drawings, in which:

FIG. 1 is a perspective view of one embodiment of a recyclable electronic atomizer of the present invention;

FIG. 2 is a cross-sectional view of the recyclable electronic atomizer shown in FIG. 1;

FIG. 3 is an exploded view of the recyclable electronic atomizer of FIG. 1 from a perspective;

FIG. 4 is an exploded view of the recyclable electronic atomizer device of FIG. 1 from another perspective;

fig. 5 is an enlarged view of the area a shown in fig. 2;

fig. 6 is an enlarged view of region B shown in fig. 2;

FIG. 7 is a cross-sectional view of another embodiment of the recyclable electronic atomizer of the present invention;

fig. 8 is an enlarged view of region C shown in fig. 7;

FIG. 9 is a flow chart of an embodiment of a recycling method of a recyclable electronic atomizer according to the present invention.

In the figure, 1, a housing; 11. a body portion; 12. a blocking ring portion; 121. positioning holes; 2. a suction nozzle; 3. a bottom cover; 31. a cover body; 32. a boss; 4. a liquid storage tube; 41. a sleeve portion; 42. an end wall portion; 401. an air inlet hole; 402. a first connection groove; 43. a connecting column part; 44. an extension; 441. a connecting ring portion; 442. a buckling convex part; 45. a protrusion; 5. an atomizing core; 51. a porous liquid guide; 52. an electric heating element; 53. a wire; 6. a control assembly; 61. a circuit board; 62. an air flow sensor; 63. a conductive post; 64. a conductive tube; 7. a battery; 81. a liquid suction cotton pipe; 82. a fixed tube; 821. a liquid guiding hole; 83. a battery sleeve; 831. a tube body portion; 832. a barrier wall portion; 833. a receiving chamber; 834. a second connecting groove; 835. a fastening hole; 836. a support rib; 84. a sealing seat; 841. a receiving groove; 842. an air guide hole; 85. a sealing plug; 86. a condensate adsorption block; 87. an electric heating wire; 88. a liquid baffle.

Detailed Description

The present invention will be described in detail below with reference to the drawings and detailed description.

Referring to fig. 1 to 6, the invention provides a recyclable electronic atomizing device, which comprises a housing 1, a suction nozzle 2 and a bottom cover 3, wherein a liquid storage tube 4, an atomizing core 5, a control assembly 6 and a battery 7 are accommodated in the housing 1, the housing 1 comprises a tubular body 11 and a blocking ring 12 formed by inwards inclining and extending one end face of the body 11, and the blocking ring 12 is formed with a positioning hole 121. The liquid storage pipe 4 is used for storing atomized liquid, and one end of the liquid storage pipe 4, which is away from the suction nozzle 2, is provided with an air inlet hole 401 and a first connecting groove 402, and the notch of the first connecting groove 402 is arranged facing the control component 6. It will be appreciated that the composition of the atomized liquid is not particularly limited herein, as long as it atomizes to form an aerosol upon heating.

In one embodiment of the present invention, the liquid storage tube 4 includes a sleeve portion 41 and an end wall portion 42, and a liquid suction tube 81 is accommodated in the sleeve portion 41, and the liquid suction tube 81 is used for adsorbing the atomized liquid. An end wall portion 42 is provided to cover an end face of the sleeve portion 41 facing the battery 7, and the end wall portion 42 is provided with an air intake hole 401. The end wall portion 42 is formed with a connecting column portion 43 extending in the direction in which the battery 7 is located, and the first connecting groove 402 is provided on an end surface of the connecting column portion 43. The end wall portion 42 is formed with an extension 44 extending in the direction in which the battery 7 is located. Preferably, the extension portion 44 includes a connection ring portion 441 and a fastening protrusion 442, the connection ring portion 441 is formed by extending the end wall portion 42 toward the battery 7, and the fastening protrusion 442 is located at the outer peripheral surface of the connection ring portion 441.

The atomizing core 5 is at least partially inserted into the liquid storage tube 4 and is used for atomizing atomized liquid. In this embodiment, the atomizing core 5 includes a porous liquid guide 51, an electric heating element 52 and a conducting wire 53, and the porous liquid guide 51 is located in the liquid storage tube 4 and contacts with the liquid suction cotton tube 81 to adsorb the atomized liquid. The electric heating element 52 is in contact with the porous liquid guide 51 for atomizing the atomized liquid. The first end of the wire 53 is connected to the electric heating element 52, and the second end of the wire 53 is inserted through the air inlet hole 401 and into the first connection groove 402.

In one embodiment of the present invention, the porous liquid guide 51 and the electric heating element 52 are both disposed in the sleeve portion 41, and the porous liquid guide 51 is substantially tubular and is formed by winding a fiber sheet. The porous liquid guide member 51 is sleeved with a fixed pipe 82, a liquid guide hole 821 is formed in the fixed pipe 82, and atomized liquid on the liquid suction cotton pipe 81 flows into the porous liquid guide member 51 through the liquid guide hole 821. The electric heating element 52 is a tubular electric heating wire wound on the inner wall of the porous liquid guide element 51, the number of the electric heating wires 53 is two, and the end parts of the electric heating wires are connected with one electric wire 53 so as to be electrically connected with the control assembly 6 through the electric wires 53. It is to be understood that the shapes and materials of the porous liquid guiding member 51 and the electrothermal member 52 are not particularly limited herein, for example, the porous liquid guiding member 51 may be made of ceramic material, and the electrothermal member 52 may be an electrothermal sheet or an electrothermal film.

The control assembly 6 is located between the liquid storage tube 4 and the battery 7 and is detachably connected with the liquid storage tube 4. The control assembly 6 includes a circuit board 61, an airflow sensor 62 and a conductive post 63, and a control circuit electrically connected to the conductive post 63 is disposed on the circuit board 61. The air flow sensor 62 is fixed to the side of the circuit board 61 facing the battery 7 and is electrically connected to the control circuit. The conductive post 63 is fixed on the circuit board 61 and electrically connected with the control circuit, and one end of the conductive post 63 is inserted into the first connecting groove 402 and clamps the conductive wire 53 together with the inner wall of the first connecting groove 402. This kind of structure not only is convenient for produce, has avoided among the prior art moreover, when wire 53 and circuit board 61 welding link to each other, not only there is not environmental protection of soldering tin, but also inconvenient dismantlement recycling's problem. Preferably, a conductive tube 64 is connected to a side of the circuit board 61 facing the battery 7, and the extending direction of the conductive tube 64 is the same as the extending direction of the battery 7. More preferably, the orifice of the conductive tube 64 facing the battery 7 is provided with a notch.

The recyclable electronic atomization device further comprises a battery sleeve 83, wherein the battery sleeve 83 is positioned in the shell 1 and is coaxially arranged with the liquid storage tube 4, the battery sleeve 83 and the liquid storage tube 4 are positioned at two ends of the shell 1, and the extension part 44 is detachably connected with the battery sleeve 83, so that the recyclable electronic atomization device is convenient to detach and recycle. The battery 7 is movably inserted in the battery sleeve 83 and is detachably connected with the control assembly 6.

In one embodiment of the present invention, the battery sleeve 83 includes a tube portion 831 and a barrier wall portion 832, the barrier wall portion 832 is disposed in the tube portion 831 and divides the inner space of the tube portion 831 into a receiving cavity 833 and a second connecting slot 834, the control assembly 6 is disposed in the receiving cavity 833, and the conductive post 63 penetrates the barrier wall and extends into the second connecting slot 834. The battery 7 is located in the accommodating cavity 833, the electrode part of the battery 7 is inserted in the conductive tube 64, and the electrode of the battery 7 is detachably connected with the conductive tube 64, so that the electric connection is reliable, and the problem that poor electric connection is easily caused by vibration when the battery 7 is connected in an abutting mode is well avoided. The groove wall of the second connecting groove 834 is provided with a fastening hole 835, the connecting ring portion 441 is inserted into the second connecting groove 834, and the fastening protruding portion 442 is fastened to the fastening hole 835. The connection mode is reliable in connection, the conductive posts 63 are easy to align with the first connection grooves 402, production is facilitated, and production efficiency is improved. In addition, since the opening of the conductive tube 64 facing the battery 7 is provided with a notch, the electrode of the battery 7 is conveniently inserted into the conductive tube 64 and reliably connected, so that the production yield is high, the disassembly is convenient, and the disassembly efficiency is high.

In one embodiment of the present invention, the recyclable electronic atomizer further comprises a sealing seat 84, a sealing plug 85 and a condensate adsorbing block 86, wherein the sealing seat 84 is located between the circuit board 61 and the battery 7, the sealing seat 84 is provided with a containing groove 841 and an air guiding hole 842, the containing groove 841 is communicated with the upper end face and the lower end face of the sealing seat 84, the air flow sensor 62 is located in the containing groove 841, and the air guiding hole 842 is communicated with the air inlet 401 and then the atomizing core 5 so as to be communicated with the suction nozzle 2 through the atomizing core 5. The electrodes of the battery 7 pass through the sealing seat 84 to be connected with the conductive pipe 64. Therefore, the seal seat 84 is mounted more stably and reliably, and the sealing performance is improved.

One end of the sealing plug 85 is inserted into the liquid storage tube 4, and the other end of the sealing plug 85 is inserted into the suction nozzle 2 so as to prevent atomized liquid from leaking towards the suction nozzle 2. The condensate adsorbing block 86 is located in the space formed by the suction nozzle 2 and the sealing plug 85 to adsorb condensate formed by condensation of aerosol at the suction nozzle 2. The sealing seat 84 and the sealing plug 85 may be made of silica gel or rubber, and the condensate adsorbing block 86 may be made of cotton, and the material thereof is not particularly limited herein.

The suction nozzle 2 is detachably connected with the first end of the housing 1, wherein the detachable connection mode can be magnetic attraction connection or interference fit connection. In this embodiment, one end of the suction nozzle 2 is inserted into the housing 1 and is in interference fit with the housing 1, and the other end of the suction nozzle 2 is located outside the housing 1. Of course, in another embodiment, the suction nozzle 2 may also be sleeved outside the housing 1.

The bottom cover 3 is detachably disposed in the second end of the housing 1, so that when the bottom cover 3 receives a pushing force in the direction of the suction nozzle 2 greater than a preset value, the bottom cover 3 drives the suction nozzle 2 and the parts located in the housing 1 to be pushed out from the first end of the housing 1. The bottom cover 3 includes a cover body 31 and a boss 32 formed by extending the end surface of the cover body 31 in the longitudinal direction of the case 1, wherein a first end of the cover body 31 abuts against an end surface of the battery sleeve 83, a second end of the cover body 31 abuts against the stopper ring 12, and the boss 32 is inserted into the positioning hole 121. Therefore, the bottom cover 3 is not only fixed and stable and reliable, but also convenient to push the bottom cover 3 to move towards the suction nozzle 2 during disassembly, and the situation of blocking can not occur, so that the bottom cover is more labor-saving to push and convenient to disassemble.

Referring to fig. 7 and 8, in one embodiment of the present invention, the outer peripheral surface of the connection ring portion 441 is wound with an electric heating wire 87, and the electric heating wire 87 is electrically connected to the control assembly 6, so that before the present invention is disassembled, the control assembly 6 controls the battery 7 to supply power to the electric heating wire 87, so as to soften the connection ring portion 441 and the fastening protrusion 442, thereby facilitating the separation of the liquid storage tube 4 from the battery sleeve 83. Preferably, the connection ring portion 441 and the fastening protrusion 442 are made of a heat-shrinkable material, which may be formed of polyethylene, polyolefin, or the like by radiation of a radiation source, which not only facilitates separation of the liquid storage tube 4 and the battery case 83, but also facilitates disassembly of the heating wire 87, thereby improving the disassembly efficiency. More preferably, the end surface of the connecting post 43 is further provided with a third connecting groove (not shown in the figure), and the ends of the electric heating wires 87 are respectively inserted into the corresponding third connecting grooves in a one-to-one correspondence manner, the control assembly 6 extends into the third connecting groove, and the control assembly 6 and the groove wall of the third connecting groove jointly clamp the electric heating wires 87.

In one embodiment of the present invention, the recyclable electronic atomizer further includes a liquid baffle 88, wherein the liquid baffle 88 is movably inserted into the connection ring portion 441, the liquid baffle 88 is disposed to extend along the lateral direction of the liquid storage tube 4, the end surface of the connection ring portion 441 facing the battery 7 is provided with a protrusion 45, the protrusion 45 is disposed to extend along the lateral direction of the liquid storage tube 4, and the wall of the second connection slot 834 is provided with a support rib 836. When the liquid storage tube 4 is connected with the battery sleeve 83, the supporting rib 836 is abutted against the liquid baffle 88, and the protrusion 45 is spaced from the liquid baffle 88, and at this time, when the user sucks, the air flow flows in the direction indicated by the arrow in fig. 8. When the liquid storage tube 4 is disconnected from the battery sleeve 83, the liquid blocking plate 88 covers the end of the connection ring portion 441 and abuts against the protrusions 45 under the action of gravity, so that the atomized liquid can be prevented from leaking out of the connection ring portion 441 during the detachment, and the user's clothes can be stained.

Referring to fig. 9, the invention also discloses a recycling method of the recyclable electronic atomizing device, which comprises the following steps:

s1, firstly, fixing the shell 1 at a preset position;

when the housing 1 is detached, the housing 1 may be clamped by a clamp or the housing 1 may be held by a user's hand to fix the housing 1.

S2, exerting thrust force towards the suction nozzle 2 on the bottom cover 3, so that the suction nozzle 2 and the parts positioned in the shell 1 are pushed out from the first end of the shell 1;

after the casing 1 is fixed, a pushing force towards the direction of the suction nozzle 2 can be applied to the boss 32 of the bottom cover 3 by hands or other tools, so that the bottom cover 3 pushes the battery sleeve 83, the liquid storage sleeve and the sealing plug 85 to move towards the direction of the suction nozzle 2, the parts such as the battery 7, the control component 6 and the sealing seat 84 in the battery sleeve 83 and the like move towards the direction of the suction nozzle 2 together with the battery sleeve 83, and after the suction nozzle 2 is separated from the casing 1, other parts are separated from the first end of the casing 1 successively under the action of the pushing force.

And S3, pulling the liquid storage tube 4 and the battery 7 out of the control assembly 6, and respectively placing the liquid storage tube and the battery on the corresponding target storage devices.

In one embodiment of the present invention, step S3 specifically includes:

breaking the liquid storage tube 4 to separate the liquid storage tube 4 from the battery sleeve 83, thereby releasing the connection between the liquid storage tube 4 and the control assembly 6 and the battery sleeve 83;

removing the battery 7 with the seal 84 from the battery sleeve 83 together with the control assembly 6;

removing the battery 7 from the control assembly 6, separating the control assembly 6 from the seal 84 and the battery 7;

the battery 7 and the seal holder 84 are separated and then placed on the corresponding target storage devices, respectively.

After the reservoir tube 4 and the battery sleeve 83 are detached from the first end of the housing 1, the battery sleeve 83 is held, and then the reservoir tube 4 and the battery sleeve 83 are separated by forcibly snapping the reservoir tube 4, thereby releasing the connection between the reservoir tube 4 and the control unit 6 and the battery sleeve 83. Then take out battery 7 and control assembly 6 from battery sleeve 83, pull out battery 7 from control assembly 6 again, just make battery 7, control assembly 6 and seal seat 84 all separate each other, can place on corresponding target storage device respectively after the separation to can realize categorised recovery, realize the purpose of environmental protection.

In one embodiment of the present invention, step S1 is preceded by:

acquiring a trigger signal of the airflow sensor 62;

counting the number of the sucking ports of the user in a first preset time according to the trigger signal;

when the number of the sucking openings of the user is greater than the preset number of openings in the first preset time, the control component 6 controls the heating wire 87 to heat for a second preset time so as to soften the connecting ring portion 441 and the fastening protruding portion 442.

When the user sucks, the airflow sensor 62 is triggered, and the airflow sensor 62 sends a trigger signal to the control circuit of the control assembly 6. The first preset time may be 1 second or 2 seconds, and assuming that the first preset time is 1 second and the number of preset openings is 3, the user continuously sucks 3 aerosol openings in 1 second before disassembling the electronic atomization device, and the control circuit controls the heating wire 87 to generate heat for the second preset time, so that the connection ring portion 441 and the fastening protruding portion 442 are softened, and therefore the electronic atomization device is convenient to disassemble. The second preset time may be 3 seconds, 4 seconds, 5 seconds, or the like, and may be selected as needed.

In summary, since the control assembly 6 is located between the liquid storage tube 4 and the battery 7, and is detachably connected to the liquid storage tube 4; the battery 7 is detachably connected with the control assembly 6; the suction nozzle 2 is detachably connected with the first end of the shell 1; the bottom cover 3 is detachably disposed in the second end of the housing 1, so that when the bottom cover 3 receives a pushing force in the direction of the suction nozzle 2 greater than a preset value, the bottom cover 3 drives the suction nozzle 2 and the parts located in the housing 1 to be pushed out from the first end of the housing 1. Therefore, after the atomized liquid in the electronic atomization device is completely consumed, the bottom cover 3 applies a pushing force towards the direction of the suction nozzle 2, so that the suction nozzle 2 and the parts positioned in the shell 1 are pushed out from the first end of the shell 1, then the liquid storage tube 4 and the battery 7 are pulled out from the control assembly 6 and are respectively placed on the corresponding target storage devices, and the classified recovery can be realized.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The recyclable electronic atomization device is characterized by comprising a shell (1), a suction nozzle (2) and a bottom cover (3), wherein a liquid storage tube (4), an atomization core (5), a control assembly (6) and a battery (7) are contained in the shell (1), and the liquid storage tube (4) is used for storing atomized liquid; the atomizing core (5) is at least partially inserted into the liquid storage tube (4) and is used for atomizing the atomized liquid; the control assembly (6) is positioned between the liquid storage pipe (4) and the battery (7) and is detachably connected with the liquid storage pipe (4); the battery (7) is detachably connected with the control assembly (6); the suction nozzle (2) is detachably connected with the first end of the shell (1); the bottom cover (3) is detachably arranged in the second end of the shell (1), so that when the thrust force applied to the bottom cover (3) towards the direction of the suction nozzle (2) is larger than a preset value, the bottom cover (3) drives the suction nozzle (2) and parts positioned in the shell (1) to be pushed out from the first end of the shell (1).

2. The recoverable electronic atomizer according to claim 1, wherein an air inlet hole (401) and a first connecting groove (402) are arranged at one end of the liquid storage tube (4) facing away from the suction nozzle (2), and a notch of the first connecting groove (402) is arranged facing the control component (6); the atomizing core (5) comprises a porous liquid guide piece (51), an electric heating piece (52) and a conducting wire (53), wherein the porous liquid guide piece (51) is positioned in the liquid storage tube (4) so as to adsorb the atomized liquid; the electric heating element (52) is in contact with the porous liquid guide element (51) and is used for atomizing the atomized liquid; the first end of the wire (53) is connected with the electric heating element (52), and the second end of the wire (53) passes through the air inlet hole (401) and is inserted into the first connecting groove (402); the control assembly (6) comprises a circuit board (61) and a conductive column (63), wherein the conductive column (63) is fixed on the circuit board (61), and the conductive column (63) is at least partially inserted into the first connecting groove (402) and clamps the lead (53) together with the inner wall of the first connecting groove (402).

3. The recoverable electronic atomizer according to claim 2, wherein said liquid storage tube (4) comprises a sleeve portion (41) and an end wall portion (42), said porous liquid guiding member (51) and said electric heating member (52) are both located in said sleeve portion (41), said end wall portion (42) is covered at an end face of said sleeve portion (41) facing said battery (7), said end wall portion (42) is provided with said air inlet hole (401), said end wall portion (42) is formed with a connecting post portion (43) extending in a direction in which said battery (7) is located, and an end face of said connecting post portion (43) is provided with said first connecting groove (402).

4. A recyclable electronic atomising device according to claim 3, characterized in that it further comprises a battery sleeve (83), said battery sleeve (83) being located inside the housing (1) and being arranged coaxially to the liquid reservoir (4), said end wall portion (42) being formed with an extension (44) extending towards the direction in which the battery sleeve (83) is located, said extension (44) being detachably connected to the battery sleeve (83); the battery (7) is movably inserted in the battery sleeve (83).

5. The recoverable electronic atomizer according to claim 4, wherein said extension portion (44) comprises a connection ring portion (441) and a fastening protrusion (442), said connection ring portion (441) being formed by said end wall portion (42) extending in a direction in which said battery sleeve (83) is located, said fastening protrusion (442) being located at an outer peripheral surface of said connection ring portion (441);

the battery sleeve (83) comprises a pipe body (831) and a blocking wall (832), the blocking wall (832) is arranged in the pipe body (831) and divides the inner space of the pipe body (831) into a containing cavity (833) and a second connecting groove (834), the battery (7) is arranged in the containing cavity (833), a buckling hole (835) is formed in the groove wall of the second connecting groove (834), the connecting ring (441) is inserted in the second connecting groove (834), and the buckling convex part (442) is connected with the buckling hole (835) in a buckling mode.

6. The recoverable electronic atomizer according to claim 5, wherein said control assembly (6) is located within said receiving cavity (833), said conductive posts (63) extending through said barrier wall and into said second connecting slot (834).

7. The recoverable electronic atomizer according to claim 6, wherein said circuit board (61) is connected with a conductive tube (64), the extending direction of said conductive tube (64) is the same as the extending direction of said battery (7), the electrode of said battery (7) is at least partially inserted into said conductive tube (64), and the electrode of said battery (7) is detachably connected to said conductive tube (64).

8. The recoverable electronic atomizer according to claim 7, wherein the conductive tube (64) is provided with a notch facing the orifice of the battery (7).

9. The recoverable electronic atomizer according to claim 2, wherein said control assembly (6) further comprises an air flow sensor (62), said air flow sensor (62) being fixed to the side of said circuit board (61) facing said battery (7);

the recyclable electronic atomization device further comprises a sealing seat (84), wherein the sealing seat (84) is located between the circuit board (61) and the battery (7), the sealing seat (84) is provided with a containing groove (841), and the airflow sensor (62) is located in the containing groove (841).

10. A recycling method of a recyclable electronic atomizing device according to any one of claims 1 to 9, comprising the steps of:

firstly, fixing the shell (1) at a preset position; secondly, applying a pushing force towards the suction nozzle (2) to the bottom cover (3) so as to push the suction nozzle (2) and the parts positioned in the shell (1) out from the first end of the shell (1); thirdly, the liquid storage pipe (4) and the battery (7) are pulled out from the control assembly (6) and are respectively arranged on the corresponding target storage devices.