CN220712938U - Electromagnetic induction heating type atomizer and electronic atomizer with same - Google Patents

Abstract

The utility model belongs to the field of electronic atomizers, and particularly discloses an electromagnetic induction heating atomizer and an electronic atomizer with the electromagnetic induction heating atomizer, comprising: the annular supporting piece is provided with a closed installation cavity and an inner cavity positioned at the inner side of the installation cavity, and the inner cavity is communicated with the outside; the coil is arranged in the mounting cavity and used for generating an alternating magnetic field; the liquid guide piece is arranged in the inner cavity; the metal atomization piece is arranged in the inner cavity, the liquid guide piece surrounds the periphery of the metal atomization piece, and the metal atomization piece is used for generating heat with the induction of the coil and atomizing liquid guided by the liquid guide piece to form aerosol; and an airflow channel for guiding out aerosol formed by atomization; the utility model is more energy-saving and safer, and can not burn or insufficient atomization of aerosol matrix.

Description

Electromagnetic induction heating type atomizer and electronic atomizer with same

Technical Field

The utility model belongs to the field of electronic atomizers, and particularly relates to an electromagnetic induction heating atomizer and an electronic atomizer with the electromagnetic induction heating atomizer.

Background

The electronic atomizer is an electronic product which utilizes the atomizing assembly to heat and atomize aerosol matrixes into aerosol for users to use, and meanwhile, the aerosol generated by the electronic atomizer does not contain other harmful components such as tar, suspended particles and the like, so that the electronic atomizer has wide application market; the atomizer is a very important part in the electronic atomizer, the atomizer in the market at present basically adopts the mode of ceramic heating filament heating oil absorption cotton, during the use, the power provides the electric energy for ceramic heating filament, ceramic heating filament generates heat, oil absorption cotton is used for adsorbing aerosol matrix, the aerosol matrix that the ceramic heating filament will absorb oil absorption cotton is atomized, aerosol matrix after the atomizing forms aerosol and supplies the user to inhale, but this kind of atomizer has a problem, when the power of ceramic heating filament is too big, very easily dry-burn oil absorption cotton, the problem of burning can take place, the power of ceramic heating filament is too little, aerosol matrix atomizing is insufficient, and the power of ceramic heating filament depends on the impedance of ceramic heating filament self and the voltage that the power provided, the voltage that the power provided can constant voltage, but the impedance of ceramic heating filament is along with the change of temperature, the power of ceramic heating filament is along with the change of temperature, consequently burnt or aerosol matrix atomizing is not fully be more difficult to control, the taste of aerosol after just can seriously influencing.

Disclosure of Invention

The utility model aims to provide an electromagnetic induction heating type atomizer and an electronic atomizer with the electromagnetic induction heating type atomizer, which are more energy-saving and safer, and do not burn or insufficiently atomize aerosol matrixes.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: provided is an electromagnetic induction heating type atomizer, including:

the annular support piece is provided with a closed installation cavity and an inner cavity positioned at the inner side of the installation cavity, and the inner cavity is communicated with the outside;

a coil installed in the installation cavity and used for generating an alternating magnetic field;

the liquid guide piece is arranged in the inner cavity;

the metal atomization piece is arranged in the inner cavity, the liquid guide piece surrounds the periphery of the metal atomization piece, and the metal atomization piece is used for generating heat with the coil in an induction way and atomizing liquid guided by the liquid guide piece to form aerosol; and

and the airflow channel is used for guiding out aerosol formed by atomization.

Further, the metal atomizing piece includes the annular atomizing portion that has a plurality of meshes and seal in annular atomizing portion both sides open-ended sealing portion, annular atomizing portion with be located both sides sealing portion encloses jointly and establishes and form the atomizing chamber, the liquid guide piece encircle in annular atomizing portion sets up, the air current passageway with the atomizing chamber intercommunication.

Further, the air flow channel penetrates through the annular supporting piece, the liquid guide piece and the annular atomization part.

Further, the air flow channel and the atomizing cavity are arranged in a cross-shaped structure.

Further, the mesh holes are uniformly arranged in the annular atomization part.

Further, the liquid guide member has liquid guide micro-channels irregularly arranged in a crossing manner.

Further, the liquid guide member is a porous fiber.

Still provide an electron atomizer, including casing, base, outlet duct, atomizing support and foretell electromagnetic induction adds hot type atomizer, the base install in the casing, the base with the casing encloses jointly to establish and forms the stock solution chamber, atomizing support install in the base, annular support piece install in atomizing support makes the drain piece with the stock solution chamber intercommunication, the casing has the suction nozzle mouth, the outlet duct intercommunication in the suction nozzle mouth with between the one end of air current passageway, the other end and the external intercommunication of air current passageway.

Further, the electronic atomizer further comprises an electrode assembly, and the electrode assembly is mounted on the base and is electrically connected with the coil.

Further, the electronic atomizer further comprises a power supply assembly for electrically connecting with the electrode assembly and providing alternating current.

The utility model has the following beneficial effects:

the electromagnetic induction heating type atomizer can improve the heat efficiency by utilizing an electromagnetic induction heating mode, is more energy-saving compared with the traditional heating mode of the ceramic atomizing core, is safer, is not easy to generate the problems of scorching or insufficient atomization of aerosol matrixes, and is simple and convenient to maintain in the later period and lower in cost.

The electronic atomizer is designed based on the electromagnetic induction heating atomizer, and the beneficial effects of the electromagnetic induction heating atomizer are referred to and are not described in detail herein.

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 an exploded view of an electromagnetic induction heating atomizer according to an embodiment of the present utility model;

fig. 2 is a cross-sectional view of an electromagnetic induction heating atomizer according to an embodiment of the present utility model;

fig. 3 is a front sectional view of an electronic atomizer according to an embodiment of the present utility model;

fig. 4 is a left side cross-sectional view of an electronic atomizer according to an embodiment of the present utility model.

The figure identifies the description:

1. an annular support; 2. a coil; 3. a liquid guide; 4. a metal atomizing member; 5. an air flow channel; 6. a housing; 7. a base; 8. an air outlet pipe; 9. an atomizing bracket; 10. a first through hole; 11. a mounting cavity; 12. an inner cavity; 30. a second through hole; 40. a third through hole; 41. an annular atomization part; 42. a closing part; 43. an atomizing chamber; 61. a liquid storage cavity; 62. a suction nozzle opening; 63. a battery cell; 64. a control board; 65. a microphone; 66. a socket; 67. a suction nozzle plug; 68. sticking paper; 69. a jack; 60. an air inlet hole; 70. a via hole; 71. an electrode assembly.

Detailed Description

The following description of the embodiments of the present utility model will be made more complete in view of the accompanying drawings, in which it is to be understood 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 herein 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.

Example 1

Referring to fig. 1-2, an electromagnetic induction heating atomizer provided in this embodiment includes: the annular support 1, the annular support 1 has closed installation cavity 11 and inner cavity 12 located inside installation cavity 11, inner cavity 12 communicates with outside; a coil 2 installed in the installation cavity 11 and generating an alternating magnetic field; the liquid guide part 3 is arranged in the inner cavity 12; the metal atomization piece 4 is arranged in the inner cavity 12, the liquid guide piece 3 surrounds the periphery of the metal atomization piece 4, and the metal atomization piece 4 is used for generating heat by induction with the coil 2 and atomizing liquid guided by the liquid guide piece 3 to form aerosol; and an air flow channel 5 for directing out aerosol formed by the atomization.

Through the structure, in practical application, by adopting the electromagnetic induction heating type atomizer of the embodiment of the utility model, the liquid guide piece 3 can adsorb and store aerosol matrixes, the liquid guide piece 3 surrounds the periphery of the metal atomizer 4, when the coil 2 is electrified, a high-frequency magnetic field can be generated in the coil 2 according to the principle of electromagnetic induction, so that the metal atomizer 4 in the coil 2 is heated by induction of the magnetic field, the metal atomizer 4 heats and atomizes the aerosol matrixes adsorbed in the liquid guide piece 3 to form atomized aerosol, and the atomized aerosol can be led out when air flows through the air flow channel 5; the electromagnetic induction heating mode can improve the heat efficiency, and compared with the traditional heating mode of the ceramic atomizing core, the ceramic atomizing core is more energy-saving and safer, and the problems of scorching or insufficient atomization of aerosol matrixes are not easy to occur, and the ceramic atomizing core is simple and convenient to maintain in the later period and lower in cost.

Specifically, the metal atomization piece 4 comprises an annular atomization part 41 with a plurality of meshes and a sealing part 42 sealed at two sides of the annular atomization part 41, the annular atomization part 41 and the sealing parts 42 positioned at two sides of the annular atomization part are jointly surrounded to form an atomization cavity 43, the liquid guide piece 3 is arranged around the annular atomization part 41, and the air flow channel 5 is communicated with the atomization cavity 43; when the coil 2 is electrified, a high-frequency magnetic field is generated in the coil 2, so that the annular atomization part 41 is heated by the induction of the magnetic field, the annular atomization part 41 can heat and atomize aerosol matrixes adsorbed in the liquid guide member 3, aerosol formed by atomization is generated in the atomization cavity 43, and the aerosol formed by atomization can only flow out from the air flow channel 5 communicated with the atomization cavity 43 due to the existence of the sealing part 42.

Specifically, the airflow channel 5 penetrates through the annular supporting member 1, the liquid guiding member 3 and the annular atomization portion 41, so that the atomization cavity 43 can be communicated to the outside through the airflow channel 5, and the airflow channel capable of increasing the aerosol formed by atomization is penetrated, so that the aerosol formed by atomization is guided out from the airflow channel 5.

In this embodiment, referring to fig. 1, a first through hole 10 is formed in the annular support member 1, a second through hole 30 is formed in the liquid guiding member 3, a third through hole 40 is formed in the annular atomization portion 41, and the first through hole 10, the second through hole 30 and the third through hole 40 together form the air flow channel 5.

Specifically, the airflow channel 5 and the atomizing cavity 43 are arranged in a cross-shaped cross structure, so that the airflow channel 5 vertically penetrates through the annular supporting piece 1, the liquid guide piece 3 and the annular atomizing part 41, the flow of aerosol formed by atomization can be more effectively promoted, the aerosol is not gathered at a certain position, the uniformity of the outflow of the aerosol is increased, and the inconsistency of front and rear tastes is avoided.

In particular, the mesh holes are uniformly arranged on the annular atomizing part 41, so that the aerosol generated in the atomizing chamber 43 can be ensured to be more uniform and continuous, and no interruption or excessive aerosol generation occurs.

Specifically, the liquid guiding member 3 has liquid guiding micro-channels (not shown) irregularly and crosswise arranged, and the liquid guiding micro-channels can facilitate the liquid guiding member 3 to adsorb and store the aerosol matrix, and facilitate the flow of the aerosol matrix in the liquid guiding member 3, so that the aerosol matrix can smoothly flow to the annular atomization portion 41.

Specifically, the liquid guide member 3 is porous fiber, and the porous fiber has the advantage of lighter quality, can be favorable to electromagnetic induction heating formula atomizer's lightweight to have better mechanical properties, consequently have fine tensile strength and stability, can increase electromagnetic induction heating formula atomizer's life.

Example 2

Referring to fig. 1-4, the electronic atomizer provided in this embodiment includes a housing 6, a base 7, an air outlet pipe 8, an atomizing support 9, and the electromagnetic induction heating atomizer described above, wherein the base 7 is mounted on the housing 6, the base 7 and the housing 6 are enclosed together to form a liquid storage cavity 61, the atomizing support 9 is mounted on the base 7, the annular support 1 is mounted on the atomizing support 9, so that the liquid guide 3 is communicated with the liquid storage cavity 61, the housing 6 has a suction nozzle opening 62, the air outlet pipe 8 is communicated between the suction nozzle opening 62 and one end of the air flow channel 5, and the other end of the air flow channel 5 is communicated with the outside; the inside of the liquid storage cavity 61 is used for storing aerosol matrixes, the liquid guide piece 3 is communicated with the liquid storage cavity 61, the aerosol matrixes stored in the liquid storage cavity 61 can be adsorbed into the liquid guide piece 3, when the electromagnetic induction heating atomizer is electrified, aerosol can be generated, and when a user sucks at the suction nozzle 62, the aerosol flows out of the air flow channel 5 and flows to the suction nozzle 62 along the air outlet pipe 8 to be sucked by the user.

In this embodiment, the base 7 is provided with the through hole 70, the through hole 70 is communicated with the air flow channel, the housing 6 is provided with the air inlet 60, the air inlet 60 is communicated with the through hole 70, the air inlet 60 is a place where the electronic atomizer and the outside realize air exchange, and the outside air can enter the housing 6 from the air inlet 60 and then flow into the air flow channel 5 after passing through the hole 70.

Specifically, the electronic atomizer further comprises an electrode assembly 71, the electrode assembly 71 is mounted on the base 7 and is electrically connected with the coil 2, and the motor assembly is used for being connected with an external power supply, so that the function of supplying power to the coil 2 is achieved.

Specifically, the electronic atomizer further includes a power supply assembly for electrically connecting with the electrode assembly 71 and supplying an alternating current.

In this embodiment, the power supply assembly includes a battery cell 63 disposed in the housing 6, a control board 64 electrically connected to the battery cell 63, and a microphone 65 and a socket 66 electrically connected to the control board 64, the electrode assembly 71 is electrically connected to the control board 64, the microphone 65 is located inside the air intake hole 60, a jack 69 is disposed at one side of the air intake hole 60, and the socket 66 is located in the jack 69; the electric core 63 provides electric energy for the electronic atomizer, the socket 66 can be used for connecting external charger to realize the function of charging for electric core 63, improved the duration of electronic atomizer, control panel 64 is used for controlling whole electronic atomizer, miaow head 65 can the real-time perception flow in the information of the air current in inlet port 60, turn into the electric signal with the air current signal and transmit to control panel 64, control panel 64 control electric core 63 is for coil 2 power supply, thereby realize utilizing electromagnetic induction principle to make the heating of metal atomizing piece 4.

As a preferred embodiment, a suction nozzle plug 67 is further arranged in the suction nozzle opening 62, a sticker 68 is further arranged at the lower end of the shell 6, and when the electromagnetic induction heating type atomizer is not used any more, the suction nozzle plug 67 is utilized to block the suction nozzle opening 62, so that dust, impurities and the like can be prevented from entering the electromagnetic induction heating type atomizer from the suction nozzle opening 62, a certain protection effect is achieved, and meanwhile, the child can be prevented from being misused, and a child lock effect is achieved; the air inlet hole 60 and the jack 69 can be closed by using the sticker 68 to be stuck to the lower end of the shell 6, so that dust, impurities and the like can be prevented from entering the electromagnetic induction heating atomizer from the air inlet hole 60 and the jack 69, and a certain protection effect is achieved; and when the suction nozzle plug 67 is blocked at the suction nozzle opening 62 and the sticker 68 is stuck at the lower end of the shell 6, the false start caused by the condition that the gas leakage occurs in the process of storing or transporting the electronic atomizer can be avoided, and the safety is improved.

While the utility model has been described with reference to certain preferred embodiments, it will be understood by those skilled in the art that various changes and substitutions of equivalents may be made and equivalents will be apparent to those skilled in the art without departing from the scope of the utility model. Therefore, the protection scope of the utility model is subject to the protection scope of the claims.

Claims (10)

1. An electromagnetic induction heating atomizer, comprising:

the annular support piece is provided with a closed installation cavity and an inner cavity positioned at the inner side of the installation cavity, and the inner cavity is communicated with the outside;

a coil installed in the installation cavity and used for generating an alternating magnetic field;

the liquid guide piece is arranged in the inner cavity;

the metal atomization piece is arranged in the inner cavity, the liquid guide piece surrounds the periphery of the metal atomization piece, and the metal atomization piece is used for generating heat with the coil in an induction way and atomizing liquid guided by the liquid guide piece to form aerosol; and

and the airflow channel is used for guiding out aerosol formed by atomization.

2. The electromagnetic induction heating type atomizer according to claim 1, wherein the metal atomizing piece comprises an annular atomizing part with a plurality of meshes and a sealing part sealed at openings at two sides of the annular atomizing part, the annular atomizing part and the sealing parts at two sides are jointly enclosed to form an atomizing cavity, the liquid guide piece is arranged around the annular atomizing part, and the air flow channel is communicated with the atomizing cavity.

3. The electromagnetic induction heating atomizer of claim 2 wherein said air flow passage is provided through said annular support member, said liquid guide member and said annular atomizing portion.

4. The electromagnetic induction heating atomizer of claim 2 wherein said air flow passages are arranged in a cross-like configuration with said atomizing chamber.

5. The electromagnetic induction heating atomizer according to claim 2, wherein said mesh holes are uniformly arranged in said annular atomizing portion.

6. The electromagnetic induction heating atomizer of claim 1 wherein said liquid guide has irregularly intersecting liquid guide microchannels.

7. The electromagnetic induction heating atomizer of claim 6 wherein said liquid guide is a porous fiber.

8. The utility model provides an electronic atomizer, its characterized in that includes casing, base, outlet duct, atomizing support and the electromagnetic induction adds hot type atomizer of any one of claims 1-7, the base install in the casing, the base with the casing encloses jointly and establishes and form the stock solution chamber, atomizing support install in the base, annular support piece install in atomizing support, so that liquid guide piece with the stock solution chamber intercommunication, the casing has the suction nozzle mouth, the outlet duct intercommunication in between suction nozzle mouth and the one end of air current passageway, the other end of air current passageway communicates with the external world.

9. The electronic atomizer of claim 8 further comprising an electrode assembly mounted to said base and electrically connected to said coil.

10. The electronic nebulizer of claim 9, further comprising a power supply assembly to electrically connect with the electrode assembly and provide an alternating current.