CN212212685U - Heating element, atomizer and electronic atomization device - Google Patents

Abstract

The utility model provides a heating element, atomizer and electronic atomization device, wherein heating element includes: a heating line and an electrode connected to the heating line; the electrodes comprise a first electrode used for being connected and conducted with a power supply assembly in a first access mode and a second electrode used for being connected and conducted with the power supply assembly in a second access mode; the connection with the power supply component in different ways is realized through the first electrode and the second electrode of the heating component. Different connected modes between atomizer and the power supply module can be realized to this application, and then different atomization effect can be realized, user experience is improved.

Description

Heating element, atomizer and electronic atomization device

Technical Field

The utility model relates to an electron smoking set field especially relates to a heating element, atomizer and electron atomizing device.

Background

The resistance of the heating wire that the atomizer of the electronic atomization device among the prior art generally provided is certain, and it can't adjust the volume of giving out smoke by oneself according to the demand size. The desired atomization effect is also different for persons with different amounts of smoke involved. Therefore, the existing product can not meet the sampling requirement of users.

SUMMERY OF THE UTILITY MODEL

The utility model provides a heating element, atomizer and electronic atomization device for realize that the atomizer is connected with power supply module with different modes, and then can realize different atomization effect.

For solving the above technical problem, the utility model provides a first technical scheme does: provided is a heat generating component including: a heating line and an electrode connected to the heating line; the electrodes comprise a first electrode used for being connected and conducted with a power supply assembly in a first access mode and a second electrode used for being connected and conducted with the power supply assembly in a second access mode; the connection with the power supply component in different ways is realized through the first electrode and the second electrode of the heating component.

In order to solve the above technical problem, the utility model provides a second technical scheme does: there is provided a nebulizer, comprising: the heating component comprises the heating component, and the shell is used for accommodating the heating component and connecting the heating component with the power supply component.

The shell comprises a first electrode induction point matched with the first electrode and a second electrode induction point matched with the second electrode; the first electrode is connected with the first electrode sensing point so as to connect and conduct the power supply component in a first access mode through the first electrode sensing point; the second electrode is connected with the second electrode sensing point so as to connect and conduct the power supply component in a second access mode through the second electrode sensing point.

Wherein the length of the heating line connected with the first electrode is greater than or equal to the length of the heating line connected with the second electrode.

Wherein the first electrode comprises a first positive electrode and a first negative electrode; the second electrode comprises a second positive electrode and a second negative electrode; the first electrode sensing point comprises a first positive electrode sensing point and a first negative electrode sensing point, and the first positive electrode sensing point and the first negative electrode sensing point correspond to the first positive electrode and the first negative electrode in position; the second electrode sensing point comprises a second positive electrode sensing point and a second negative electrode sensing point, and the second positive electrode sensing point and the second negative electrode sensing point correspond to the second positive electrode and the second negative electrode in position.

The first positive electrode and the second positive electrode are positioned on the same side of the heating circuit and are connected with different ports of the heating circuit; the first negative electrode and the second negative electrode are positioned on the other side far away from the heating circuit and are connected with different ports of the heating circuit.

The first positive electrode, the second negative electrode and the first negative electrode sequentially surround the periphery of the heating circuit and are connected with different ports of the heating circuit.

The first positive electrode and the first negative electrode are connected with the first positive electrode sensing point and the first negative electrode sensing point; or the second positive electrode and the second negative electrode are connected with the second positive electrode sensing point and the second negative electrode sensing point; the first positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly; or the second positive electrode induction point and the second negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly.

Wherein the first positive electrode and the second negative electrode contact the first positive electrode sensing point and the second negative electrode sensing point; or the second positive electrode and the first negative electrode contact the second positive electrode sensing point and the first negative electrode sensing point; the first positive electrode induction point and the second negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly; or the second positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly.

Wherein the first electrode comprises a first positive electrode and a first negative electrode; the second electrode comprises a second positive electrode; the first positive electrode and the second positive electrode are positioned on the same side of the heating circuit and are connected with different ports of the heating circuit; the first negative electrode is positioned on the other side of the heating circuit and is connected with a port of the heating circuit; the first electrode sensing point comprises a first positive electrode sensing point and a first negative electrode sensing point, and the first positive electrode sensing point and the first negative electrode sensing point correspond to the first positive electrode and the first negative electrode in position; the second electrode sensing point comprises a second positive electrode sensing point, and the second positive electrode sensing point corresponds to the second positive electrode in position.

The first positive electrode and the first negative electrode are connected with the first positive electrode sensing point and the first negative electrode sensing point; or the second positive electrode and the first negative electrode are connected with the second positive electrode sensing point and the first negative electrode sensing point; the first positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly; or the second positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly.

In order to solve the above technical problem, the utility model provides a third technical scheme does: provided is an electronic atomization device including: an atomizer according to any one of the above; the power supply component is used for supplying power to the atomizer; the atomizer and the power supply assembly can be in conductive connection in a first access mode, and can be in conductive connection in a second access mode.

The utility model has the advantages that: be different from prior art, the utility model provides a heating element, atomizer and electronic atomization device, include: a heating line and an electrode connected to the heating line; the electrodes comprise a first electrode used for being connected and conducted with a power supply assembly in a first access mode and a second electrode used for being connected and conducted with the power supply assembly in a second access mode; the connection with the power supply component in different ways is realized through the first electrode and the second electrode of the heating component. This application can realize the different connected mode between atomizer and the power supply module, and then the different atomization effect of different heating circuit realization of different calorific capacity of accessible.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the atomizer of the present invention;

fig. 2 is a schematic structural diagram of a first embodiment of a heating assembly in the atomizer according to the present invention;

fig. 3 is a schematic structural diagram of a first embodiment of a housing in the atomizer of the present invention;

fig. 4 is a schematic structural diagram of a second embodiment of a heating element in the atomizer of the present invention;

fig. 5 is a schematic structural view of a second embodiment of a housing in the atomizer of the present invention;

fig. 6 is a schematic structural diagram of a third embodiment of a heating element in the atomizer according to the present invention;

fig. 7 is a schematic structural view of a third embodiment of a housing in the atomizer of the present invention;

fig. 8 is a schematic structural diagram of the electronic atomization device of the present invention.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The present invention will be described in detail with reference to the accompanying drawings and examples.

The heating component provided by the utility model comprises a heating circuit and an electrode connected with the heating circuit; the electrodes comprise a first electrode for being in a first access mode with the power supply component and a second electrode for being in a second access mode with the power supply component. The heating component can be connected with the power supply component in different modes through the first electrode and the second electrode, and different atomization effects can be achieved.

Fig. 1 is a schematic structural diagram of an embodiment of an atomizer according to the present invention. The atomizer comprises a shell 1 and a heating component 2, wherein the shell 1 is used for accommodating the heating component 2 and is connected with a first electrode or a second electrode on the heating component 2. The heating component 2 is then connected to the power supply component in a different way.

Specifically, the heat generating component 2 is connected to the power supply component through the case 1. Thus, in one embodiment, the housing 1 comprises a first electrode sensing point matching with the first electrode and a second electrode sensing point matching with the second electrode. The first electrode is connected with the first electrode sensing point so as to be connected with the power supply assembly through the first electrode sensing point, and the second electrode is connected with the second electrode sensing point so as to be connected with the power supply assembly through the second electrode sensing point.

Further, please refer to fig. 2, which is a schematic structural diagram of a first embodiment of the heating element of the present invention. The first electrode 11 specifically includes a first positive electrode 111 and a first negative electrode 112, and the second electrode 12 includes a second positive electrode 121 and a second negative electrode 122. The first positive electrode 111, the first negative electrode 112, the second positive electrode 121, and the second negative electrode 122 are all connected to the port of the heat generating circuit 13. In the embodiment shown in fig. 2, the first positive electrode 111 and the second positive electrode 121 are both located on the same side of the heat-generating circuit 13 and are connected to different ports of the heat-generating circuit 13. The first negative electrode 112 and the second negative electrode 122 are both located on the other side of the heat generating circuit 13 and are connected to different ports of the heat generating circuit 13. Specifically, the first positive electrode 111 and the second positive electrode 121 are located on the left side of the heat emitting line 13, and the first negative electrode 112 and the second negative electrode 122 are located on the right side of the heat emitting line 13. In another embodiment, the first positive electrode 111 and the first negative electrode 112 may be disposed on the left side of the heat generating circuit 13, and the second positive electrode 121 and the second negative electrode 122 may be disposed on the right side of the heat generating circuit 13.

Please refer to fig. 3, which is a schematic structural diagram of a first embodiment of a housing of an atomizer according to the present invention. The first electrode sensing point 21 includes a first positive electrode sensing point 211 and a first negative electrode sensing point 212. The first positive electrode sensing point 211 corresponds to the first positive electrode 111, and the first negative electrode sensing point 212 corresponds to the first negative electrode 112. The second electrode sensing point 22 includes a second positive electrode sensing point 221 and a second negative electrode sensing point 222. The second positive electrode sensing point 221 corresponds to the second positive electrode 121, and the second negative electrode sensing point 222 corresponds to the second negative electrode 122.

Specifically, the heating element 2 shown in fig. 2 and the housing 1 shown in fig. 3 are both square, and when they are connected to the power supply component, the first positive electrode 111 and the first negative electrode 112 on the heating element 2 can be connected to the first positive electrode sensing point 211 and the first negative electrode sensing point 212 on the housing 1 correspondingly, and the second positive electrode 121 and the second negative electrode 122 are connected to the second positive electrode sensing point 221 and the second negative electrode sensing point 222 on the housing 1 correspondingly.

In the above-described connection mode of connecting the heating element 2 and the housing 1, if the atomizer and the power supply element are connected in the first connection mode, the first positive electrode sensing point 211 and the first negative electrode sensing point 212 on the housing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply element. As a result, the heating line 13 connected between the first positive electrode 111 and the first negative electrode 112 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In order to connect the atomizer and the power supply component in the second connection mode, the second positive electrode sensing point 221 and the second negative electrode sensing point 222 on the casing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply component. As a result, the heating line 13 connected between the second positive electrode 121 and the second negative electrode 122 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In the present embodiment, when the atomizer and the power module are connected by the first connection method and the second connection method, the lengths of the heat generating lines 13 connected to the atomizer and the power module are different. Specifically, the length of the heat generating line 13 connected between the first positive electrode 111 and the first negative electrode 112 when the connection is made in the first connection manner is smaller than the length of the heat generating line 13 connected between the second positive electrode 121 and the second negative electrode 122 when the connection is made in the second connection manner. Therefore, under the condition that the material and the diameter of the heating circuit 13 are the same, the longer the heating circuit 13 is, the larger the resistance is, the different atomization effects are generated, and therefore, the atomizer and the power supply module shown in the embodiment generate different atomization effects when connected in the first connection mode and the second connection mode, and different experiences can be brought to users.

In another embodiment, the first positive electrode 111 and the second negative electrode 122 on the heat generating element 2 can be electrically connected to the first positive electrode sensing point 211 and the second negative electrode sensing point 222 on the housing 1, and the second positive electrode 121 and the first negative electrode 112 can be electrically connected to the second positive electrode sensing point 221 and the first negative electrode sensing point 212 on the housing 1.

In the above-described connection method between the case 1 and the heat generating element 2, in order to connect the atomizer to the power supply element in the first connection method, the first positive electrode sensing point 211 and the second negative electrode sensing point 222 on the case 1 may be connected to the positive electrode terminal and the negative electrode terminal of the power supply element in correspondence. As a result, the heating line 13 connected between the first positive electrode 111 and the second negative electrode 122 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In order to connect the atomizer and the power supply module in the second connection mode, the second positive electrode sensing point 221 and the first negative electrode sensing point 212 on the casing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply module. As a result, the heating line 13 connected between the second positive electrode 121 and the first negative electrode 112 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In the present embodiment, when the atomizer and the power module are connected by the first connection method and the second connection method, the lengths of the heat generating lines 13 connected to the atomizer and the power module are the same. Specifically, the length of the heat generation line 13 connected between the first positive electrode 111 and the second negative electrode 122 when connected in the first connection manner is equal to the length of the heat generation line 13 connected between the second positive electrode 121 and the first negative electrode 112 when connected in the second connection manner. Therefore, under the condition that the material and the diameter of the heating circuit 13 are the same, the heating circuit 13 has the same length and the same resistance, and the generated atomization effect is the same, so that the atomizer and the power supply assembly shown in the embodiment have the same atomization effect when connected in the first access mode and the second access mode, and can bring different experiences for users, for example, the user can connect the atomizer and the power supply assembly randomly when docking the atomizer and the power supply assembly, and the problem that whether the normal insertion and the reverse insertion can cause the inoperability is not considered.

Fig. 4 is a schematic structural diagram of a heating element of an atomizer according to a second embodiment of the present invention. Compared with the first embodiment shown in fig. 2, the difference is that the first positive electrode 111, the second positive electrode 121, the second negative electrode 122 and the first negative electrode 112 of the heat generating component 2 in this embodiment sequentially surround the periphery of the heat generating circuit 13 and are connected to different ports of the heat generating circuit 13.

Fig. 5 is a schematic structural diagram of a housing of an atomizer according to a second embodiment of the present invention. Compared with the first embodiment shown in fig. 3, the difference is that the first positive electrode sensing point 211, the second positive electrode sensing point 221, the second negative electrode sensing point 222 and the first negative electrode sensing point 212 of the case 1 in this embodiment correspond to the positions of the first positive electrode 111, the second positive electrode 121, the second negative electrode 122 and the first negative electrode 112, respectively.

Specifically, the heating element 2 shown in fig. 4 and the housing 1 shown in fig. 5 are both circular, and when the atomizer is electrically connected to the power supply assembly, the first positive electrode 111 and the first negative electrode 112 on the heating element 2 can be electrically connected to the first positive electrode sensing point 211 and the first negative electrode sensing point 212 on the housing 1, and the second positive electrode 121 and the second negative electrode 122 are electrically connected to the second positive electrode sensing point 221 and the second negative electrode sensing point 222 on the housing 1.

In the above-described connection mode of connecting the heating element 2 and the housing 1, if the atomizer and the power supply element are connected in the first connection mode, the first positive electrode sensing point 211 and the first negative electrode sensing point 212 on the housing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply element. As a result, the heating line 13 connected between the first positive electrode 111 and the first negative electrode 112 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In order to connect the atomizer and the power supply component in the second connection mode, the second positive electrode sensing point 221 and the second negative electrode sensing point 222 on the casing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply component. As a result, the heating line 13 connected between the second positive electrode 121 and the second negative electrode 122 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In the present embodiment, when the atomizer and the power module are connected by the first connection method and the second connection method, the lengths of the heat generating lines 13 connected to the atomizer and the power module are the same. Specifically, the length of the heat generating line 13 connected between the first positive electrode 111 and the first negative electrode 112 when connected in the first connection manner is equal to the length of the heat generating line 13 connected between the second positive electrode 121 and the second negative electrode 122 when connected in the second connection manner. Therefore, under the condition that the material and the diameter of the heating circuit 13 are the same, the resistance of the heating circuit 13 is the same, and the atomization effect generated by the same, so that the atomization effect generated by the atomizer and the power supply assembly in the embodiment when the first access mode and the second access mode are connected is the same, and different experiences can be brought to users, for example, the user can connect the atomizer and the power supply assembly randomly when the atomizer and the power supply assembly are connected, without considering the problem that whether the forward insertion and the backward insertion can cause the inoperability or not.

In another embodiment, the first positive electrode 111 and the second negative electrode 122 on the heat generating element 2 can be electrically connected to the first positive electrode sensing point 211 and the second negative electrode sensing point 222 on the housing 1, and the second positive electrode 121 and the first negative electrode 112 can be electrically connected to the second positive electrode sensing point 221 and the first negative electrode sensing point 212 on the housing 1.

In the above-described connection method between the case 1 and the heat generating element 2, in order to connect the atomizer to the power supply element in the first connection method, the first positive electrode sensing point 211 and the second negative electrode sensing point 222 on the case 1 may be connected to the positive electrode terminal and the negative electrode terminal of the power supply element in correspondence. As a result, the heating line 13 connected between the first positive electrode 111 and the second negative electrode 122 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In order to connect the atomizer and the power supply module in the second connection mode, the second positive electrode sensing point 221 and the first negative electrode sensing point 212 on the casing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply module. As a result, the heating line 13 connected between the second positive electrode 121 and the first negative electrode 112 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In the present embodiment, when the atomizer and the power module are connected by the first connection method and the second connection method, the lengths of the heat generating lines 13 connected to the atomizer and the power module are different. Specifically, the length of the heat generating line 13 connected between the first positive electrode 111 and the second negative electrode 122 when connected in the first connection manner is greater than the length of the heat generating line 13 connected between the second positive electrode 121 and the first negative electrode 112 when connected in the second connection manner. Therefore, under the condition that the material and the diameter of the heating circuit 13 are the same, the resistance of the heating circuit 13 is different, and the atomization effect generated by the heating circuit is different, so that the atomization effect generated by the atomizer and the power supply assembly shown in the embodiment when the atomizer and the power supply assembly are connected in the first access mode and the second access mode is different, and different experiences can be brought to users.

Fig. 6 is a schematic structural diagram of a third embodiment of a heating element in an atomizer according to the present invention. In the present embodiment, the first electrode 14 includes a first positive electrode 141 and a first negative electrode 142, and the second electrode 15 includes a second positive electrode 151. The first positive electrode 141 and the second positive electrode 151 are located on the same side of the heat emitting circuit 13 and connected to different ports of the heat emitting circuit 13, and the first negative electrode 142 is located on the other side of the heat emitting circuit 13 and connected to a port of the heat emitting circuit 13.

Fig. 7 is a schematic structural diagram of a housing of an atomizer according to a third embodiment of the present invention. In the present embodiment, the first electrode sensing point 23 includes a first positive electrode sensing point 231 and a first negative electrode sensing point 232, the first positive electrode sensing point 231 and the first negative electrode sensing point 232 correspond to the first positive electrode 141 and the first negative electrode 142, the second electrode sensing point 24 includes a second positive electrode sensing point 241, and the second positive electrode sensing point 241 corresponds to the second positive electrode 151.

Specifically, the heating element 2 shown in fig. 6 and the housing 1 shown in fig. 7 are both square, and when they are connected to the power supply component, the first positive electrode 141 and the first negative electrode 142 on the heating element 2 can be connected to the first positive electrode sensing point 231 and the first negative electrode sensing point 232 on the housing 1 correspondingly, and the second positive electrode 151 and the first negative electrode 142 are connected to the second positive electrode sensing point 241 and the first negative electrode sensing point 232 on the housing 1 correspondingly.

In the above-described connection mode of connecting the heating element 2 and the housing 1, if the atomizer and the power supply element are connected in the first connection mode, the first positive electrode sensing point 231 and the first negative electrode sensing point 232 on the housing 1 are correspondingly connected to the positive electrode end and the negative electrode end of the power supply element. As a result, the heating line 13 connected between the first positive electrode 141 and the first negative electrode 142 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

If the atomizer and the power supply module are connected in the second connection mode, the second positive electrode sensing point 241 and the first negative electrode sensing point 232 on the casing 1 are correspondingly connected with the positive electrode end and the negative electrode end of the power supply module. As a result, the heating line 13 connected between the second positive electrode 151 and the first negative electrode 142 of the heating element 2 is electrically connected, and at this time, the heating line 13 generates heat to atomize the liquid in the case 1.

In the present embodiment, when the atomizer and the power module are connected by the first connection method and the second connection method, the lengths of the heat generating lines 13 connected to the atomizer and the power module are different. Specifically, the length of the heat generating line 13 connected between the first positive electrode 141 and the first negative electrode 142 when connected by the first connection method is smaller than the length of the heat generating line 13 connected between the second positive electrode 151 and the first negative electrode 142 when connected by the second connection method. Therefore, under the condition that the material and the diameter of the heating circuit 13 are the same, the resistance of the heating circuit 13 is different, and the atomization effect generated by the heating circuit is also different, so that the atomization effect generated by the atomizer and the power supply assembly shown in the embodiment when the first access mode and the second access mode are connected is different, and different experiences can be brought to users.

In the above embodiments of the present invention, the first electrode, the second electrode, the first electrode sensing point and the second electrode sensing point can be wires, or can be conductive contacts.

Referring to fig. 8, in order to illustrate the structure of an embodiment of the electronic atomization device of the present invention, the electronic atomization device 5 includes: atomizer 51 and power supply assembly 52. The atomizer 51 includes the heat generating component 2 and the housing 1 according to any of the above embodiments. The power supply assembly 52 is used for accommodating the atomizer 51 and supplying power to the atomizer 51; wherein the nebulizer 51 and the power supply assembly 52 are connectable in a first access way and connectable in a second access way to enable different experiences of the user.

The atomizer and the electronic atomization device described in the present invention only describe a part of the functional structures, and other structures are the same as those in the prior art, and will not be described here.

The above is only the embodiment of the present invention, not the limitation of the patent scope of the present invention, all the equivalent structures or equivalent processes that are used in the specification and the attached drawings or directly or indirectly applied to other related technical fields are included in the patent protection scope of the present invention.

Claims (12)

1. A heat generating component, comprising:

a heating line and an electrode connected to the heating line; the electrodes comprise a first electrode used for being connected and conducted with a power supply assembly in a first access mode and a second electrode used for being connected and conducted with the power supply assembly in a second access mode; the connection with the power supply component in different ways is realized through the first electrode and the second electrode of the heating component.

2. An atomizer, comprising:

a heat generating component as claimed in claim 1;

and the shell is used for accommodating the heating component and connecting the heating component with the power supply component.

3. Nebulizer according to claim 2,

the shell comprises a first electrode induction point matched with the first electrode and a second electrode induction point matched with the second electrode; the first electrode is connected with the first electrode sensing point so as to connect and conduct the power supply component in a first access mode through the first electrode sensing point; the second electrode is connected with the second electrode sensing point so as to connect and conduct the power supply component in a second access mode through the second electrode sensing point.

4. A nebulizer as claimed in claim 2 or 3, wherein the length of the heating line to which the first electrode is connected is greater than or equal to the length of the heating line to which the second electrode is connected.

5. A nebulizer according to claim 3,

the first electrode comprises a first positive electrode and a first negative electrode; the second electrode comprises a second positive electrode and a second negative electrode;

the first electrode sensing point comprises a first positive electrode sensing point and a first negative electrode sensing point, and the first positive electrode sensing point and the first negative electrode sensing point correspond to the first positive electrode and the first negative electrode in position; the second electrode sensing point comprises a second positive electrode sensing point and a second negative electrode sensing point, and the second positive electrode sensing point and the second negative electrode sensing point correspond to the second positive electrode and the second negative electrode in position.

6. Nebulizer according to claim 5,

the first positive electrode and the second positive electrode are positioned on the same side of the heating circuit and are connected with different ports of the heating circuit; the first negative electrode and the second negative electrode are positioned on the other side far away from the heating circuit and are connected with different ports of the heating circuit.

7. Nebulizer according to claim 5,

the first positive electrode, the second negative electrode and the first negative electrode sequentially surround the periphery of the heating circuit and are connected with different ports of the heating circuit.

8. Atomiser according to claim 6 or 7,

the first positive electrode and the first negative electrode are connected with the first positive electrode sensing point and the first negative electrode sensing point; or the second positive electrode and the second negative electrode are connected with the second positive electrode sensing point and the second negative electrode sensing point;

the first positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly; or

The second positive electrode induction point and the second negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly.

9. Atomiser according to claim 6 or 7,

the first positive electrode and the second negative electrode contact the first positive electrode sensing point and the second negative electrode sensing point; or the second positive electrode and the first negative electrode contact the second positive electrode sensing point and the first negative electrode sensing point;

the first positive electrode induction point and the second negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly; or

The second positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly.

10. A nebulizer according to claim 3,

the first electrode comprises a first positive electrode and a first negative electrode;

the second electrode comprises a second positive electrode;

the first positive electrode and the second positive electrode are positioned on the same side of the heating circuit and are connected with different ports of the heating circuit;

the first negative electrode is positioned on the other side of the heating circuit and is connected with a port of the heating circuit;

the first electrode sensing point comprises a first positive electrode sensing point and a first negative electrode sensing point, and the first positive electrode sensing point and the first negative electrode sensing point correspond to the first positive electrode and the first negative electrode in position;

the second electrode sensing point comprises a second positive electrode sensing point, and the second positive electrode sensing point corresponds to the second positive electrode in position.

11. Nebulizer according to claim 10,

the first positive electrode and the first negative electrode are connected with the first positive electrode sensing point and the first negative electrode sensing point; or the second positive electrode and the first negative electrode are connected with the second positive electrode sensing point and the first negative electrode sensing point;

the first positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly; or

The second positive electrode induction point and the first negative electrode induction point are respectively connected with the negative electrode end and the positive electrode end of the power supply assembly.

12. An electronic atomization device, comprising:

an atomizer according to any one of claims 2 to 11;

the power supply component is used for supplying power to the atomizer; the atomizer and the power supply assembly can be in conductive connection in a first access mode, and can be in conductive connection in a second access mode.

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