CN220831960U - Rechargeable anti-reverse electronic atomization system - Google Patents

Abstract

The utility model discloses a chargeable anti-reverse electronic atomization system, which comprises an atomization host and a charging bin; the atomizing host is detachably connected to one side of the charging bin; a plurality of electrodes which are axially arranged in parallel are arranged on the atomizing host; the electrodes are arranged in a non-axisymmetric parallel manner along an axis perpendicular to the axis arranged in parallel in the axial direction; the charging bin is provided with a plurality of charging electrodes which are opposite to the electrodes in the plurality of electrodes respectively; when the atomizing host is connected to the charging bin, each electrode is respectively abutted against each charging electrode. The electrode and the charging electrode can be matched only when the atomizing host is installed in the correct direction, so that charging is performed, the installation in the wrong direction is effectively prevented, and the damage of aerosol substrate leakage to the charging bin is avoided. Meanwhile, when the whole electronic atomizer is in a symmetrical shape, installation guide can be provided, and reverse erroneous installation caused by the symmetrical shape is avoided.

Description

Rechargeable anti-reverse electronic atomization system

Technical Field

The utility model relates to the field of electronic atomizers, in particular to a chargeable anti-reverse electronic atomizing system.

Background

Currently, electronic atomizers are used by numerous users. Some existing electronic atomizers include a charging device for charging an atomizing host, so as to form a chargeable electronic atomizing system. The user can dismantle the atomizing host computer alone from charging device and use, can be with atomizing host computer through charging electrode and charging device reconnection after using to in time charge to can realize anytime and anywhere charging. However, one end of the atomizer host often stores a liquid aerosol matrix, and if the atomizer host is installed into the charging device in the wrong direction or form, when the aerosol matrix leaks from the atomizer host, damage is caused to components on the charging device, resulting in a reduced service life of the machine; meanwhile, for some symmetrically designed atomizing hosts, it is often difficult for a user to determine the installation direction during charging, thereby creating the above risk of aerosol matrix leakage.

Disclosure of Invention

The embodiment of the utility model provides a chargeable anti-reverse electronic atomization system, which aims to solve the problems that in the prior art, when an electronic atomizer with a charging device is installed to the charging device for charging, a user easily causes the situation of wrong installation direction, and the charging device is easily damaged when aerosol matrixes leak.

The embodiment of the utility model provides a chargeable anti-reverse electronic atomization system, which comprises an atomization host and a charging bin; the atomizing host is detachably connected to one side of the charging bin; a plurality of electrodes which are axially arranged in parallel are arranged on the atomizing host; the electrodes are arranged in a non-axisymmetric parallel manner along an axis perpendicular to the axis arranged in parallel in the axial direction; the charging bin is provided with a plurality of charging electrodes which are opposite to the electrodes in the plurality of electrodes respectively; when the atomizing host is connected to the charging bin, each electrode is respectively abutted against each charging electrode.

In some embodiments, the plurality of electrodes includes a first electrode, a second electrode, and a third electrode arranged in sequence; the charging electrode comprises a first charging electrode, a second charging electrode and a third charging electrode which are sequentially arranged; a distance between the first electrode and the second electrode is greater than a distance between the second electrode and the third electrode; when the atomizing host is connected to the charging bin, the first electrode is in butt-joint with the first charging electrode; the second electrode is in butt-joint with the second charging electrode; the third electrode is in positive abutment with the third charging electrode.

In some embodiments, each of the charging electrodes is disposed in the charging bin protruding toward a side of the atomizing host.

In some embodiments, the axis of arrangement of each of the electrodes is parallel to the central axis of the atomizing host.

In some embodiments, each of the electrodes is disposed in the atomizing host at a central location on a contact side with the charging cartridge.

In some embodiments, an electrode platform is arranged in the charging bin in a protruding manner towards one side of the atomizing host; an electrode groove matched with the electrode table is concavely formed in one side, facing the charging bin, of the atomizing host; each charging electrode is arranged at one side of the electrode table, which is close to the atomizing host; each electrode is arranged in the electrode groove.

In some embodiments, each of the electrodes is disposed on the atomizing host in a protruding manner; the atomizing host also comprises an electrode protecting sleeve; the electrode protection sleeves are sleeved on the electrodes at the same time, and the surfaces of the electrode protection sleeves facing the charging bin side are flush with the surfaces of the electrodes facing the charging bin side.

In some embodiments, the charging bin is provided with a charging slot; the inner contour of the charging groove is matched with the outer contour of the atomizing main machine; each charging electrode is arranged in the charging groove.

In some embodiments, the atomizing host includes an atomizing portion and an air outlet portion; the air outlet part is detachably connected to one end of the atomization part; an air outlet part placing groove is also formed in the charging groove; the outer contour of the air outlet part is matched with the inner contour of the air outlet part placing groove.

In some embodiments, the outlet placement groove is disposed on the same axis as each of the charging electrodes arranged in parallel.

Based on the above structure and the connection mode thereof, the rechargeable anti-reverse-loading electronic atomization system provided by the embodiment of the utility model has the advantages that the plurality of electrodes which are axially arranged but asymmetrically arranged are arranged on the atomization host, and the corresponding charging electrodes are arranged on the charging bin, so that the atomization host can be connected with the charging bin only in a specific direction, and further, a user can realize the matching of the electrodes and the charging electrodes only when the atomization host is installed in a correct direction, so that the charging can be smoothly carried out, the installation in an incorrect direction is effectively prevented, and the damage of aerosol substrate leakage to the charging bin is avoided. Meanwhile, the electrode setting mode can provide installation guide for a user when the whole electronic atomizer is in a symmetrical shape, and reverse erroneous installation caused by the symmetrical shape is avoided.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic block diagram of a disassembled rechargeable anti-reverse electronic atomization system according to an embodiment of the present utility model;

fig. 2 is an enlarged schematic diagram of a circled portion a in a schematic block diagram of a disassembled rechargeable anti-reverse electronic atomization system according to an embodiment of the present utility model;

FIG. 3 is a schematic block diagram of a rechargeable anti-reverse electronic atomization system according to another embodiment of the present utility model after disassembly;

FIG. 4 is an enlarged schematic view of a circled portion B in a schematic block diagram of a rechargeable anti-reverse electronic atomization system according to another embodiment of the present utility model after disassembly;

FIG. 5 is a cross-sectional view of a rechargeable anti-reverse electronic atomization system according to an embodiment of the present utility model;

Fig. 6 is an enlarged schematic view of a circled portion C in a cross-sectional view of a rechargeable anti-reverse electronic atomization system according to an embodiment of the present utility model;

Fig. 7 is a schematic diagram of an electronic atomizer according to another embodiment of the present utility model after disassembly.

Wherein, the reference numerals specifically are:

10. a chargeable anti-reverse electronic atomization system;

100. An atomizing host; 110. an electrode; 111. a first electrode; 112. a second electrode; 113. a third electrode; 120. an electrode groove; 130. an electrode protective sleeve; 140. an atomizing unit; 150. an air outlet portion;

200. A charging bin; 210. a charging electrode; 211. a first charging electrode; 212. a second charging electrode; 213. a third charging electrode; 220. an electrode stand; 230. a charging tank; 231. and an air outlet part placing groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be understood that the terms "comprises" and "comprising," when used in this specification and the appended claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

It is also to be understood that the terminology used in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be further understood that the term "and/or" as used in the present specification and the appended claims refers to any and all possible combinations of one or more of the associated listed items, and includes such combinations.

Referring to fig. 1-7, as shown in fig. 1 and 3, an embodiment of the present utility model provides a rechargeable anti-reverse electronic atomization system 10, which includes an atomization host 100 and a charging bin 200; the atomizing host 100 is detachably connected to one side of the charging bin 200; a plurality of electrodes 110 which are axially arranged in parallel are arranged on the atomizing main machine 100; the plurality of electrodes 110 are arranged in a non-axisymmetric parallel manner along an axis perpendicular to the axis arranged in parallel in the axial direction; the charging bin 200 is provided with a plurality of charging electrodes 210 which are respectively opposite to the electrodes 110 in the plurality of electrodes 110; when the atomizing host 100 is connected to the charging cartridge 200, each electrode 110 is respectively abutted against each charging electrode 210.

In this embodiment, the atomizing host 100 is a device that can be used by a user alone, and the atomizing host 100 stores an aerosol matrix and an atomizing core that contacts the aerosol matrix. The atomizing host 100 is internally provided with a rechargeable battery which can independently supply power to the atomizing core, and the atomizing core can heat the liquid aerosol matrix after being electrified so as to generate gaseous aerosol for users to use. The charging bin 200 is also provided with an independent battery, and the charging bin 200 can charge the battery through an external power supply. When the atomizing host 100 is mounted to the charging bin 200, the circuitry inside the atomizing host 100 is connected to the plurality of charging electrodes 210 on the charging bin 200 through the plurality of electrodes 110, and the battery inside the charging bin 200 charges the rechargeable battery inside the atomizing host 100 through the charging electrodes 210.

The plurality of electrodes 110 on the atomizing host 100 are axially arranged in parallel in a uniform direction, but the plurality of electrodes 110 are spaced apart from each other by different distances, and therefore, if the axes perpendicular to the arrangement axes of the plurality of electrodes 110 are taken as symmetry axes, the plurality of electrodes 110 cannot be arranged in a linear arrangement. If necessary, in the specific design process, the plurality of electrodes 110 may be arranged at equal intervals in advance, and then the positions of the odd number of electrodes 110 are displaced along the arrangement axis, so as to change the distance between the odd number of electrodes 110 and the adjacent two electrodes 110, thereby forming an asymmetric arrangement structure. For example, five electrodes 110 may be arranged at equal intervals according to the first distance, and then one or three electrodes 110 are displaced along the axial direction to form an asymmetric arrangement mode. By arranging the plurality of electrodes 110 on the atomizing host 100 in an asymmetric axial arrangement, a user can only install into the charging cartridge 200 in a unique orientation to achieve pairing of the electrodes 110 and the charging electrodes 210 when the user needs to connect the atomizing host 100 to the charging cartridge 200. If the user tries to mount the atomizing host 100 to the charging cartridge 200 in the opposite wrong direction, since the plurality of electrodes 110 are not equally arranged in an axisymmetric form, at least one of the electrodes 110 cannot be abutted against the charging electrode 210, and thus charging cannot be achieved. The user can know that the installation direction is wrong at the moment when the user finds that the charging is impossible, and needs to turn the direction to reinstall the atomizing host 100, so that the damage to the specific part on the atomizing host 100 caused by the leakage of the aerosol matrix is avoided. The specific reason is that the charging bin 200 corresponding to the end of the atomizing host 100 where the aerosol matrix is stored can be enhanced to be sealed, so as to match with the guiding effect of the electrode 110, and the aerosol matrix will not permeate into the important parts of the charging bin 200 even if the aerosol matrix leaks when the user correctly installs the charging direction. Meanwhile, the electrode 110 is guided in an asymmetric arrangement mode, so that the service life of the electrode 110 can be prolonged better, and stable electric connection between the atomizing host 100 and the charging bin 200 is ensured.

In one embodiment, as shown in fig. 2 and 4, the plurality of electrodes 110 includes a first electrode 111, a second electrode 112, and a third electrode 113 sequentially arranged; the charging electrode 210 includes a first charging electrode 211, a second charging electrode 212, and a third charging electrode 213, which are sequentially arranged; the distance between the first electrode 111 and the second electrode 112 is greater than the distance between the second electrode 112 and the third electrode 113; when the atomizing host 100 is connected to the charging bin 200, the first electrode 111 is abutting against the first charging electrode 211; the second electrode 112 is in positive abutment to the second charging electrode 212; the third electrode 113 is in butt-joint to the third charging electrode 213.

In the present embodiment, the number of the electrodes 110 may be three, the three electrodes 110 are the first electrode 111, the second electrode 112, and the third electrode 113, and the first electrode 111, the second electrode 112, and the third electrode 113 are sequentially arranged. The second electrode 112 is disposed between the first electrode 111 and the third electrode 113, and thus, the distance between the first electrode 111 and the second electrode 112 may be set to be greater than the distance between the second electrode 112 and the third electrode 113, thereby achieving non-equidistant asymmetric axial arrangement formed by the three electrodes 110. Correspondingly, three charging electrodes 210, namely a first charging electrode 211, a second charging electrode 212 and a third charging electrode 213, are also simultaneously arranged on the charging bin 200. The arrangement and the mutual spacing of the first charging electrode 211, the second charging electrode 212, and the third charging electrode 213 are also the same as those of the first electrode 111, the second electrode 112, and the third electrode 113. Therefore, as shown in fig. 5 and 6, after the atomizing host 100 is connected to the charging bin 200, the first electrode 111 can be directly abutted to the first charging electrode 211, the second electrode 112 can be directly abutted to the second charging electrode 212, and the third electrode 113 can be directly abutted to the third charging electrode 213. When the user installs the atomizing host 100 in the opposite direction, the first electrode 111 and the third charging electrode 213 can face each other, and the third electrode 113 and the first charging electrode 211 can also face each other, but the second electrode 112 will be located in the space between the first charging electrode 211 and the third charging electrode 213, and the abutting energization cannot be achieved. Thereby, erroneous direction mounting can be avoided.

In one embodiment, as shown in fig. 3, each charging electrode 210 is disposed in the charging bin 200 at a side facing the atomizing host 100.

In this embodiment, the plurality of charging electrodes 210 are all arranged on the side of the charging bin 200 facing the atomizing host 100 in a protruding manner, when a user needs to dock the atomizing host 100 with the charging bin 200 for charging, the protruding plurality of charging electrodes 210 can provide visual guidance for the user, and meanwhile, the protruding arrangement of the plurality of charging electrodes 210 is also convenient for the user to know the arrangement manner of the charging electrodes 210, so that the correct installation direction is determined according to the arrangement manner of the electrodes 110 on the atomizing host 100.

In one embodiment, as shown in fig. 1 and 2, the arrangement axis of each electrode 110 is parallel to the central axis of the atomizing host 100.

In this embodiment, the central axis of the atomizing host 100 is actually the extending direction from the first end to the second end of the atomizing host 100, that is, the axis of the posture of the atomizing host 100 after being mounted to the charging bin 200. If the external shape of the atomizing host 100 is set to be symmetrical, when the arrangement axis of each electrode 110 is parallel to the central axis of the atomizing host 100, the atomizing host 100 actually rotates 180 degrees when the user An Zhuangcuo is wrong, and at this time, the plurality of electrodes 110 cannot be in one-to-one correspondence with the charging electrodes 210 corresponding to each electrode due to the asymmetric arrangement of the plurality of electrodes 110, so that an incorrect connection manner is more effectively avoided.

In one embodiment, as shown in fig. 1 and 2, each electrode 110 is disposed at a central position of the contact side with the charging bin 200 in the atomizing host 100.

In this embodiment, the arrangement axis of each electrode 110 is parallel to the central axis of the atomizing host 100, and each electrode 110 is disposed at the center of the atomizing host 100 on the contact side with the charging bin 200, so that better stability can be provided during charging, and the situation that the distance between the electrode 110 and the charging electrode 210 is too large when the atomizing host 100 shakes is prevented, so as to realize more stable charging. The reason is that if the arrangement axes of the plurality of electrodes 110 are not parallel to the central axis of the atomizing host 100, if the atomizing host 100 rotates around the central axis on one side of the charging bin 200 to shake, the plurality of electrodes 110 are separated from the charging electrode 210 at the same time; if the arrangement axes of the plurality of electrodes 110 are parallel to the central axis of the atomizing host 100, but the plurality of electrodes 110 are disposed at a non-central position on the side of the atomizing host 100 contacting the charging chamber 200, the plurality of electrodes 110 are separated from the charging electrode 210, and at this time, all the electrodes 110 may be separated at the same time. If the arrangement axes of the plurality of electrodes 110 are parallel to the central axis of the atomizing host 100, and each electrode 110 is disposed at the central position of the atomizing host 100 on the contact side with the charging bin 200, it is ensured that each electrode 110 is kept in contact with the respective charging electrode 210, and the shaking amplitude is minimized, because the central position is closest to the rotation axis at this time, and the occurrence of the offset is minimized.

In an embodiment, as shown in fig. 3 and 4, an electrode stand 220 is protruding from a side of the charging bin 200 facing the atomizing host 100; an electrode groove 120 matched with the electrode table 220 is concavely arranged on one side of the atomizing host 100 facing the charging bin 200; each charging electrode 210 is disposed at one side of the electrode stage 220 near the atomizing host 100; each electrode 110 is disposed in an electrode slot 120.

In the present embodiment, the electrode stage 220 is provided protruding on the side of the charging cartridge 200 facing the atomizing host 100; and an electrode groove 120 matched with the electrode table 220 is concavely arranged on one side of the atomizing main machine 100 facing the charging bin 200. Furthermore, when the atomizing host 100 is connected to the charging bin 200, the electrode stand 220 is clamped into the electrode slot 120, so as to achieve more stable connection, and maintain stable connection between the electrode 110 and the charging electrode 210 in a defined area. Meanwhile, the electrode stand 220 is clamped into the electrode slot 120, so that the atomization host 100 can be further prevented from rotating and shaking, and position indication and guidance can be provided when a user needs to install and charge.

In one embodiment, as shown in fig. 6 and 7, each electrode 110 is disposed on the atomizing host 100 in a protruding manner; the atomizing host 100 further includes an electrode protective sheath 130; the electrode protecting sleeves 130 are sleeved on the electrodes 110 at the same time, and the surface of the electrode protecting sleeve 130 facing the charging bin 200 is flush with the surface of the electrode 110 facing the charging bin 200.

In the present embodiment, each electrode 110 is disposed on the atomizing host 100 in a protruding manner, so as to achieve the abutting energization with the charging electrode 210. However, the atomizing host 100 needs to be used alone by a user, and thus, the integrity and flatness of the outer contour of the atomizing host 100 need to be ensured, and the electrode protecting jacket 130 plays a role. The electrode protecting sleeve 130 is provided with a plurality of through holes matched with the outer contour of the electrode 110, and the arrangement mode of the through holes is the same as that of the plurality of electrodes 110. Furthermore, the electrode protecting sleeve 130 can be sleeved on a plurality of electrodes 110 at the same time, and the surface of the electrode protecting sleeve 130 facing the charging bin 200 is kept flat with the end surface of the electrode 110. Furthermore, the electrode protecting sleeve 130 can prevent the plurality of electrodes 110 from independently rising on the outer side wall of the atomizing host 100, so as to ensure the surface flatness of the atomizing host 100. Meanwhile, the electrode protecting sleeve 130 can limit each electrode 110, so that the electrode 110 is prevented from being distorted while collision is prevented.

In one embodiment, as shown in fig. 3, a charging slot 230 is formed on the charging bin 200; the inner contour of the charging slot 230 is adapted to the outer contour of the atomizing host 100; each of the charging electrodes 210 is disposed in the charging slot 230.

In this embodiment, the charging bin 200 is provided with a charging slot 230 adapted to the outer contour of the atomizing host 100, and the atomizing host 100 may be partially or completely accommodated in the charging slot 230 and electrically connected to the charging bin 200. The charging slot 230 can wrap and limit the atomizing host 100, so as to prevent the atomizing host 100 from shaking during charging.

In one embodiment, as shown in fig. 7, the atomizing host 100 includes an atomizing part 140 and an air outlet part 150; the air outlet part 150 is detachably connected to one end of the atomizing part 140; an air outlet part placing groove 231 is also formed in the charging groove 230; the outer contour of the air outlet 150 is adapted to the inner contour of the air outlet pocket 231.

In this embodiment, the atomizing host 100 may be specifically divided into two parts, namely, an atomizing part 140 and an air outlet part 150. Wherein the atomizing part 140 is a main part of the atomizing host 100, in which aerosol can be generated. The detachable air outlet 150 may be connected to one end of the atomizing unit 140, and a user may conveniently and sanitarily obtain aerosol through the air outlet 150 and may individually clean the air outlet 150 after detachment. For convenience in carrying and preventing falling, the charging slot 230 may be further provided with an air outlet portion accommodating slot 231 adapted to the air outlet portion 150. When the user needs to charge, the air outlet 150 can be detached first, then the air outlet 150 is installed into the air outlet placing groove 231, and then the atomizing host 100 is installed into the charging bin 200, so that the air outlet 150 is conveniently carried under the condition of preventing the air outlet 150 from falling.

In one embodiment, as shown in fig. 5 and 7, the air outlet portion placement groove 231 is disposed on the same axis line as the charging electrodes 210 arranged in parallel.

In this embodiment, the air outlet portion placing groove 231 may be placed at a position arranged in parallel with the charging electrodes 210, so that the air outlet portion 150 is arranged on the same line as each charging electrode 210 when stored inside the charging bin 200. Specifically, the air outlet placement groove 231 may be provided to avoid the places where the aerosol substrate is likely to leak, depending on the places where the leakage is likely to occur in the atomizing host 100. Furthermore, if the user uses the atomizing host 100 in a symmetrical form, the aerosol substrate is charged by being connected according to the correct mounting direction of the atomizing host 100, so that the aerosol substrate is prevented from leaking and contaminating the air outlet 150, for example, if the first end of the atomizing host 100 is likely to leak, the air outlet placement groove 231 is provided at a position opposite to the second end of the atomizing host 100, and thus, if the user performs an incorrect operation, the first end is mounted at a position close to the air outlet placement groove 231, and it is found that the aerosol substrate cannot be charged, and the atomizing host 100 is turned to a correct direction.

Therefore, based on the structure and the connection mode thereof, the rechargeable anti-reverse-loading electronic atomization system provided by the embodiment of the utility model has the advantages that the atomizing host is provided with the plurality of electrodes which are axially arranged but asymmetrically arranged, and the charging bin is provided with the corresponding charging electrodes, so that the atomizing host can be connected with the charging bin only in a specific direction, and further, a user can realize the matching of the electrodes and the charging electrodes only when installing the atomizing host in a correct direction, so that the charging can be smoothly carried out, the installation in an incorrect direction is effectively prevented, and the damage of aerosol substrate leakage to the charging bin is avoided. Meanwhile, the electrode setting mode can provide installation guide for a user when the whole electronic atomizer is in a symmetrical shape, and reverse installation caused by the symmetrical shape is avoided.

The present utility model is not limited to the above embodiments, and various equivalent modifications and substitutions can be easily made by those skilled in the art within the technical scope of the present utility model, and these modifications and substitutions are intended to be included in the scope of the present utility model. Therefore, the protection scope of the utility model is subject to the protection scope of the claims.

Claims (10)

1. The rechargeable anti-reverse electronic atomization system is characterized by comprising an atomization host and a charging bin; the atomizing host is detachably connected to one side of the charging bin; a plurality of electrodes which are axially arranged in parallel are arranged on the atomizing host; the electrodes are arranged in a non-axisymmetric parallel manner along an axis perpendicular to the axis arranged in parallel in the axial direction; the charging bin is provided with a plurality of charging electrodes which are opposite to the electrodes in the plurality of electrodes respectively;

When the atomizing host is connected to the charging bin, each electrode is respectively abutted against each charging electrode.

2. The rechargeable anti-reverse electronic atomization system of claim 1 wherein the plurality of electrodes comprises a first electrode, a second electrode, and a third electrode arranged in sequence; the charging electrode comprises a first charging electrode, a second charging electrode and a third charging electrode which are sequentially arranged; a distance between the first electrode and the second electrode is greater than a distance between the second electrode and the third electrode;

When the atomizing host is connected to the charging bin, the first electrode is in butt-joint with the first charging electrode; the second electrode is in butt-joint with the second charging electrode; the third electrode is in positive abutment with the third charging electrode.

3. The rechargeable anti-reverse electronic atomization system of claim 1 in which each of the charging electrodes is disposed in the charging chamber in a protruding manner on a side of the charging chamber facing the atomization host.

4. The rechargeable anti-reverse electronic atomization system of claim 1 in which the axis of arrangement of the electrodes is parallel to the central axis of the atomization host.

5. The rechargeable anti-reverse electronic atomization system of claim 4 in which each electrode is disposed in the central location of the contact side of the atomization host with the charging bin.

6. The rechargeable anti-reverse electronic atomization system according to claim 1, wherein an electrode stand is arranged in the charging bin in a protruding manner towards one side of the atomization host; an electrode groove matched with the electrode table is concavely formed in one side, facing the charging bin, of the atomizing host; each charging electrode is arranged at one side of the electrode table, which is close to the atomizing host; each electrode is arranged in the electrode groove.

7. The rechargeable anti-reverse electronic atomization system according to claim 1, wherein each electrode is disposed on the atomization host in a protruding manner; the atomizing host also comprises an electrode protecting sleeve; the electrode protection sleeves are sleeved on the electrodes at the same time, and the surfaces of the electrode protection sleeves facing the charging bin side are flush with the surfaces of the electrodes facing the charging bin side.

8. The rechargeable anti-reverse-installation electronic atomization system of claim 1, wherein the charging bin is provided with a charging groove; the inner contour of the charging groove is matched with the outer contour of the atomizing main machine; each charging electrode is arranged in the charging groove.

9. The rechargeable anti-reverse electronic atomization system of claim 8 wherein the atomization host comprises an atomization portion and an air outlet portion; the air outlet part is detachably connected to one end of the atomization part; an air outlet part placing groove is also formed in the charging groove; the outer contour of the air outlet part is matched with the inner contour of the air outlet part placing groove.

10. The rechargeable anti-reverse electronic atomization system of claim 9 in which the vent placement slot is disposed on the same axis as each of the charge electrodes in a side-by-side arrangement.